CN111474887A - Building engineering environment monitoring device - Google Patents

Abstract

The invention discloses a building engineering environment monitoring device, the structure of which comprises: the invention realizes the matching of the wind vane sacculus groove and the integration plate ball seat by using the wind vane sacculus groove, by receiving high and low wind pressure values detected by the turbulent flow air bag pressing frame and the advection wind guide frame at the top of the infrared monitoring disc, the effect of air bag pressing annular layered wind pressure monitoring is formed, the small-sized modeling framework effect of forming an air flow layer by winding wind in a building engineering environment is ensured, dialysis adaptation sliding and pressing wind direction and motion trail are conveniently carried out on the advection layer and the turbulent flow layer one by one, thereby feeding back to the staff with slider operation mode current potential, forming and carrying the pnematic pressure with the not co-altitude of hoist and mount material adaptation for the workman, forming even balanced effect, promote the security and the roughness of hoist and mount building construction transport material, improve the abominable condition of building engineering environment, control pnematic pressure and form the effect of transporting by oneself.

Description

Building engineering environment monitoring device

Technical Field

The invention relates to a building engineering environment monitoring device, belonging to the field of buildings.

Background

Building engineering environmental monitoring common atmospheric pressure detects and wind pressure detects combination infrared monitoring probe, carries out the height above sea level and synthesizes data and carry out the exploration topography of construction, judges the construction position of construction, and avoids the environmental disturbance factor, promotes the engineering progress, and the public shortcoming of treating the optimization of prior art has:

the wind direction of environment can lead to rocking condition and damping counter weight pressure adjustment inequality of architectural shape hoist and mount among the building engineering, blow the in-process at wind pressure layering and too big wind-force, can cause the upset section bar to lead to the potential safety hazard that high altitude building material falls, and wind power can blow the sand lime that pours, cause the construction environment to produce dust particle, influence staff's respiratory track health, let the engineering progress that the polytropy that cyclone pressure and wind direction detected disturbed construction among the construction, cause the wind pressure clearance between the construction floor and carry material hoist and mount to swing and produce the height difference, cause the construction accident easily.

Disclosure of Invention

Aiming at the defects in the prior art, the invention aims to provide a building engineering environment monitoring device to solve the problems that the wind direction of the environment in the building engineering can cause the shaking condition of hoisting of building sections and the uneven adjustment of the damping counterweight pressure, the potential safety hazard that high-altitude building materials fall due to the fact that the profile is turned over and pressed in the process of wind pressure layering and overlarge wind force blowing can be caused, and the wind force can blow poured sandy soil and ash materials, so that the building construction environment generates dust particles, the respiratory tract health condition of workers is influenced, the variability of the wind pressure and wind direction detection in the building construction can interfere with the engineering progress of the building construction, so that wind pressure gaps between construction floors and the hoisting and swinging of transported materials generate height difference, and construction accidents are easily caused.

In order to achieve the purpose, the invention is realized by the following technical scheme: a building engineering environment monitoring device structurally comprises: the wind vane ball groove is embedded on the top of the hoisting arm rod and is positioned on the same vertical surface, the wall hanging plate is tightly attached to the left side of the hoisting arm rod and is perpendicular to each other, the hoisting arm rod is inserted and embedded on the top of the integration plate ball seat, the integration plate ball seat is mechanically connected with the ball cap shell through the bearing ring seat and is collinear in the axis, the infrared monitoring plate is installed inside the ball cap shell and is electrically connected with the integration plate ball seat, the wind vane ball groove is provided with a damping supporting and pressing frame, a turbulent flow bag pressing frame, an advection wind guiding frame, a ball bag shell block, a valve membrane block, a corridor bent frame rod and a guide plate, the damping supporting and pressing frame and the valve block are respectively inserted and embedded on the left side and the right side of the ball bag shell block and are communicated with each other, the corridor bent frame rod and the guide plate are buckled together and are positioned on the same vertical surface, the channel bent frame rod is inserted into the spherical capsule shell block, the turbulent flow capsule pressing frame and the advection wind guide frame are inserted into the spherical capsule shell block and are parallel to each other, and the spherical capsule shell block is nested on the top of the hoisting arm rod and is located on the same vertical surface.

In order to optimize the technical scheme, the method further comprises the following steps:

as a further improvement of the invention, the damping supporting and pressing frame consists of a bolt frame rail, a cross damping block, an arc cushion frame block and a supporting frame rod, wherein the bolt frame rail and the cross damping block are in interference fit and are positioned on the same inclined plane, the bolt frame rail and the arc cushion frame block are inserted and embedded together, and the arc cushion frame block is mechanically connected with the supporting frame rod and is positioned on the same vertical plane.

As a further improvement of the invention, the cross-shaped damping block consists of three-frame buckling frames, a concave iron rod, a cross-shaped sliding groove and damping shock tubes, wherein the three-frame buckling frames and the concave iron rod are buckled together and are mutually vertical, two concave iron rods are arranged and are respectively welded on the upper side and the lower side of the cross-shaped sliding groove, and the damping shock tubes are inserted and embedded in the cross-shaped sliding groove and are positioned on the same horizontal plane.

As a further improvement of the invention, the turbulent flow air bag pressing frame consists of a flat air bag, a sliding block rod and a short rail frame, wherein the flat air bag is nested on the top of the sliding block rod, and the sliding block rod is movably connected with the short rail frame and is positioned on the same vertical surface.

As a further improvement of the invention, the flat airbag comprises a stitching splint wall, a corrugated cotton block, a through hole and a belt flat balloon, wherein the stitching splint wall and the belt flat balloon are nested into a whole and are positioned on the same cambered surface, the corrugated cotton block and the through hole are integrated into a whole, and the corrugated cotton block is tightly attached to the inside of the belt flat balloon.

As a further improvement of the invention, the advection air guide frame comprises a wing plate balloon, a hanging rod, a torque sliding block and a long rail frame plate, wherein the wing plate balloon is nested below the bottom of the hanging rod, the hanging rod is inserted below the bottom of the torque sliding block and is positioned on the same vertical line, and the torque sliding block and the long rail frame plate are in clearance fit.

As a further improvement of the invention, the wing plate balloon consists of a shifting plate, a wing plate frame, an elliptical balloon and an air inlet ring cap, wherein the shifting plate and the wing plate frame are inserted and embedded into a whole and are positioned on the same vertical surface, the wing plate frame is arranged inside the elliptical balloon, and the elliptical balloon and the air inlet ring cap are of an integrated structure and are communicated with each other.

As a further improvement of the invention, the torque slider consists of two counterweight balls, a slider groove, two rail rings and a support block, wherein the two counterweight balls are respectively nested at the upper side and the lower side of the slider groove, the rail rings are arranged in the slider groove, and the rail rings are mechanically connected with the support block and have collinear axes.

As a further improvement of the invention, the damping shock tube is a shock insulation tube structure with three sections of damping cotton blocks sleeved with a tube shell, so that three-section type pressure-bearing impact cyclone operation is facilitated, and the retraction stability of an air pressure port of air inlet is ensured.

As a further improvement of the invention, the pressing seam clamping plate wall is an arc-shaped thick-wall structure formed by alternately pressing oblique rectangular plates, so that the transverse adjustment of the wind pressure of the upper turbulent flow and the lower turbulent flow can be ensured to be stably operated by pressing the plates conveniently, and the early warning prompt of the turbulent flow layer is formed by the node relay feedback of the plates, so that the construction is facilitated, and the risk is avoided.

As a further improvement of the invention, the shifting plate is of a shifting plate structure with the insection flow guiding stripes at the sides of the upper narrow side and the lower wide side, so that adjustment feedback of rising air pressure and sinking air pressure is conveniently formed by the crossed advection layers, and the safe operation effect of hoisting, rotating and lifting is ensured.

As a further improvement of the invention, the support block is a column frame block structure with short rods at the upper left corner and the lower right corner and a fan plate pressing fit in the middle, so that the matching operation effect of a fine adjustment model during lifting swing and rotation is conveniently formed by twisting counterweight and sliding pressure, and the included angle coefficient of data acquisition and hoisting is conveniently fed back.

Advantageous effects

The invention relates to a building engineering environment monitoring device, wherein a worker inserts a hoisting arm rod and a wall hanging plate at a plurality of azimuth angles of a building construction environment, a wind vane balloon groove forms data feedback on an integrated plate ball seat, a bearing ring seat and a spherical cap shell are matched to drive an infrared monitoring disc to rotate and monitor, simultaneously, Bluetooth integrates and compiles wind direction data and wind pressure data, mixed wind power of the building engineering environment enters a balloon shell block through a retracting port of a damping supporting and pressing frame, then forms a layered detection effect for a turbulent flow balloon pressing frame and a horizontal flow wind guiding frame through a channel bent frame rod and a guide plate, finally forms unidirectional conduction ventilation operation at the end of a valve block, during monitoring and detection, a corrugated cotton block is pressed on the wall of a flat air bag through a pressing seam clamping plate wall of the flat air bag to drive a through hole to monitor the turbulent flow air pressure in the flat air bag of a belt, so that a pushing sliding block rod is adaptive to high and low positions in a short track frame to achieve balance value feedback, then the plectrum board through the pterygoid lamina sacculus and pterygoid lamina frame grafting ellipsoid vesicle bear the advection layer crosswind that the ring cap of admitting air pours into, form the floating effect that adapts to the wind pressure of raising upward and sinking wind pressure angle, thereby pull the counter weight ball and the take-up housing of jib propelling movement moment of torsion slider and go up and down at long distance in long rail frame inboard, also take the adaptation balance to the strut piece and form the angle fine setting in moving rail ring, thereby the feedback of combined data base, guarantee the stability of signal of telecommunication cooperation physical framework observation, promote building engineering environment monitoring device's pneumatic system scheme adjustment engineering operation effect.

The invention has the following advantages after operation:

application wind vane sacculus groove cooperatees with the integrated board ball seat, receive the high low level wind pressure value that indiscriminate stream bag pressure frame and advection wind guide frame detected at infrared monitoring dish top through the integrated board ball seat, form the effect of bag pressure annular layering wind pressure control, ensure the building engineering environment and revolve the small-size modeling framework effect that forms the air current layer through winding into, conveniently dialyse adaptation smooth pressure wind direction and movement track with the indiscriminate stream layer one by one, thereby with slider operation mode potential feedback to the staff, form and carry and hoist the not pneumatic pressure of the co-altitude of material adaptation for the workman, form even balanced effect, promote the security and the peaceful degree of hoist and mount construction transport material, improve the adverse circumstances of building engineering environment, control pneumatic pressure and form the power of borrowing transportation operation effect.

Drawings

Other features, objects, and advantages of the present invention will become more apparent from the following detailed description of the embodiments of the invention when taken in conjunction with the accompanying drawings, in which:

fig. 1 is a schematic structural diagram of an environmental monitoring apparatus for construction engineering according to the present invention.

FIG. 2 is a detailed cross-sectional structure diagram of the wind vane balloon groove, the damping supporting and pressing frame, the turbulent flow balloon pressing frame and the advection wind guide frame.

FIG. 3 is an enlarged cross-sectional structural view of the cross damping block of the present invention in an operating state.

Fig. 4 is a cross-sectional enlarged structural schematic diagram of the flat air bag in the working state.

Fig. 5 is a cross-sectional internal view structural diagram of the wing balloon in the working state of the invention.

FIG. 6 is a schematic cross-sectional internal view of the torque slider of the present invention in an operational state.

Description of reference numerals: wind vane sacculus groove-1, hoisting arm rod-2, hanging plate-3, integrated plate ball seat-4, bearing ring seat-5, infrared monitoring disc-6, spherical cap shell-7, damping support and compression frame-1A, turbulent flow sacculus compression frame-1B, advection wind guide frame-1C, sacculus shell block-1D, valve block-1E, channel bent frame rod-1F, guide plate-1G, bolt frame rail-1A 1, cross damping block-1A 2, arc cushion frame block-1A 3, support frame rod-1A 4, three-frame buckle frame-1A 21, concave iron rod-1A 22, cross sliding groove-1A 23, damping vibration tube-1A 24, flat gasbag-1B 1, slide block rod-1B 2, short rail frame-1B 3, crack clamping plate wall-1B 11, The device comprises a corrugated cotton block-1B 12, a through hole-1B 13, a banding flat balloon-1B 14, a wing balloon-1C 1, a suspender-1C 2, a torque slider-1C 3, a long rail frame plate-1C 4, a shifting sheet plate-1C 11, a wing frame-1C 12, an ellipsoid balloon-1C 13, an air inlet ring cap-1C 14, a counterweight ball-1C 31, a slider groove-1C 32, a rail ring-1C 33 and a counter-bracing block-1C 34.

Detailed Description

In order to make the technical means, the creation characteristics, the achievement purposes and the effects of the invention easy to understand, the invention is further described with the specific embodiments.

The first embodiment is as follows:

referring to fig. 1 to 6, the present invention provides an environmental monitoring apparatus for construction engineering, which comprises: wind vane sacculus groove 1, hoist and mount armed lever 2, hanging plate 3, integrated board ball seat 4, bearing ring seat 5, infrared monitoring dish 6, ball cap casing 7, wind vane sacculus groove 1 nestification is on hoist and mount armed lever 2's top and be in on same vertical face, hanging plate 3 hugs closely in hoist and mount armed lever 2's left side and mutually perpendicular, hoist and mount armed lever 2 inserts and inlays on integrated board ball seat 4's top, integrated board ball seat 4 passes through bearing ring seat 5 and ball cap casing 7 mechanical connection and axle center collineation, infrared monitoring dish 6 is installed in the inside of ball cap casing 7, infrared monitoring dish 6 is connected with integrated board ball seat 4 electricity, wind vane sacculus groove 1 is equipped with damping bracing frame 1A, indiscriminate flow bag pressure frame 1B, advection wind guide frame 1C, sacculus casing piece 1D, valve piece 1E, corridor curved hack lever 1F, guide plate 1G, the bracing frame 1A is inserted respectively with damping valve piece 1E and is inlayed in the left and right sides of sacculus casing piece 1D and looks both sides and looks The air duct bending frame rods 1F and the air guide plate 1G are buckled together and located on the same vertical surface, the duct bending frame rods 1F are inserted and embedded in the spherical capsule shell block 1D, the turbulent flow capsule pressing frame 1B and the advective air guide frame 1C are inserted and embedded in the spherical capsule shell block 1D and are parallel to each other, and the spherical capsule shell block 1D is embedded on the top of the hoisting arm rod 2 and located on the same vertical surface.

Referring to fig. 2, the turbulent flow air bag pressing frame 1B is composed of a flat air bag 1B1, a slider rod 1B2, and a short rail frame 1B3, the flat air bag 1B1 is nested on the top of the slider rod 1B2, the slider rod 1B2 is movably connected with the short rail frame 1B3 and is located on the same vertical plane, the flat flow air guiding frame 1C is composed of a wing plate air bag 1C1, a suspension rod 1C2, a torque slider 1C3, and a long rail frame plate 1C4, the wing plate air bag 1C1 is nested under the bottom of the suspension rod 1C2, the suspension rod 1C2 is inserted under the bottom of the torque slider 1C3 and is located on the same vertical line, the torque slider 1C3 and the long rail frame plate 1C4 are in clearance fit, and the flat air bag 1B1 and the wing plate air bag 1C1 form a low-level and high-level air duct collection debugging, so that the wind pressure of the layered detection data feedback environment of the whole construction engineering construction is realized.

Referring to fig. 4, the flat airbag 1B1 is composed of a stitching splint wall 1B11, a corrugated cotton block 1B12, a through hole 1B13 and a band flat balloon 1B14, the stitching splint wall 1B11 and the band flat balloon 1B14 are nested into a whole and are located on the same arc surface, the corrugated cotton block 1B12 and the through hole 1B13 are integrated, the corrugated cotton block 1B12 is tightly attached to the inside of the band flat balloon 1B14, the stitching splint wall 1B11 is an arc-shaped thick-wall structure formed by cross-attaching inclined rectangular plates, so that transverse adjustment and stable operation of up-down turbulent wind pressure is ensured by the splint plate, and node relay feedback of the splint plate forms an early warning prompt of a turbulent layer, so that construction risk is avoided, the corrugated cotton block 1B12 is extruded by the stitching splint wall 1B11 to form a corrugated surface triggering feedback effect of the turbulent layer, thereby ensuring a wind-break detection operation effect of the turbulent gas path and improving the turbulent flow-stopping effect of the construction environment, and (4) potential safety hazard of scale.

Referring to fig. 5, the wing panel balloon 1C1 is composed of a blade shifting plate 1C11, a wing panel frame 1C12, an ellipsoid balloon 1C13 and an air inlet ring cap 1C14, the blade shifting plate 1C11 and the wing panel frame 1C12 are inserted and embedded into a whole and are located on the same vertical plane, the wing panel frame 1C12 is installed inside the oval balloon 1C13, the oval balloon 1C13 and the air inlet ring cap 1C14 are of an integrated structure and are mutually communicated, the blade shifting plate 1C11 is of a blade shifting structure with a flow guiding stripe on a narrow upper side and a wide lower side, adjustment feedback of an upward wind pressure and a downward wind pressure is facilitated when the cross advection layer forms an upward wind pressure and a downward wind pressure, a safety operation effect of hoisting and a rotation lifting effect is ensured, the blade shifting plate 1C11 is inserted into the wing panel frame 1C12 to form adaptive sensing of an upward wind pressure and a downward wind pressure when the advection layer forms an angle adjustment effect when the building material is hoisted.

Referring to fig. 6, the torque slider 1C3 is composed of a counterweight ball 1C31, a slider groove 1C32, a track ring 1C33, and a counter-support block 1C34, the counterweight ball 1C31 is provided with two and is respectively nested on the upper and lower sides of the slider groove 1C32, the track ring 1C33 is installed inside the slider groove 1C32, the track ring 1C33 is mechanically connected with the counter-support block 1C34 and has a collinear axis, the counter-support block 1C34 is a column frame block structure with short rods in the middle of the upper left corner and the lower right corner, and is a fan plate pressing fit, so that the fine-tuning model adaptation operation effect during lifting and swinging is formed by twisting counterweight sliding pressure, thereby facilitating feedback of data collection and hoisting included angle coefficient, and the counter-support block 1C34 is pulled and rotated around the pressure by the counterweight ball 1C31, thereby improving the hoisting model adjustment effect under the whole load force, and ensuring real-time data feedback adaptation construction operation.

The working process is as follows: a worker inserts the hoisting arm rod 2 and the wall hanging plate 3 at a plurality of azimuth angles of a building construction environment, so that the wind vane balloon groove 1 forms data feedback on the integrated plate ball seat 4 to match with the bearing ring seat 5 and the ball cap shell 7 to drive the infrared monitoring disc 6 to rotate and monitor, simultaneously, Bluetooth integrates wind direction data and wind pressure data, mixed wind power of the building construction environment enters the balloon shell block 1D through a retracting port of the damping supporting and pressing frame 1A, then forms a layered detection effect by forming and shunting the mixed wind power to the turbulent flow balloon pressing frame 1B and the advection wind guiding frame 1C through the channel bent frame rod 1F and the guide plate 1G, finally forms unidirectional conduction ventilation operation at the end of the valve block 1E, and presses and covers the corrugated cotton block 1B12 through the pressing seam clamping plate wall 1B11 of the flat balloon 1B1 to drive the through hole 1B13 to carry out wind direction monitoring on convective air pressure in the flat balloon 1B14, therefore, the pushing sliding block rod 1B2 is pushed to slide in a high-low adaptive manner in the short rail frame 1B3 to achieve balance value feedback, then the shifting sheet plate 1C11 of the wing panel saccule 1C1 and the wing panel frame 1C12 are inserted with the elliptical saccule 1C13 to bear horizontal wind of a stratosphere poured by the air inlet ring cap 1C14, a floating effect suitable for an upward wind pressure and a downward wind pressure angle is formed, the dragging suspension rod 1C2 pushes the counterweight ball 1C31 of the torque sliding block 1C3 and the sliding block groove 1C32 to lift in a long distance in the long rail frame plate 1C4, and the opposite-support frame block 1C34 is also provided with adaptive balance of fine adjustment in an angle in the moving rail ring 1C33, so that database feedback is combined, an electric signal guarantees stability of physical architecture observation, and the scheme adjustment engineering operation effect of the pneumatic system of the building engineering environment monitoring device is improved.

Example two:

referring to fig. 1 to 6, the present invention provides an architectural engineering environment monitoring apparatus, which is otherwise the same as embodiment 1, except that:

referring to fig. 2, the damping supporting and pressing frame 1A is composed of a pin frame rail 1A1, a cross damping block 1A2, an arc cushion frame block 1A3, and a supporting frame rod 1A4, the pin frame rail 1A1 and the cross damping block 1A2 are in interference fit and are located on the same inclined plane, the pin frame rail 1A1 and the arc cushion frame block 1A3 are inserted and embedded together, the arc cushion frame block 1A3 is mechanically connected with the supporting frame rod 1A4 and is located on the same vertical plane, a vent edge formed by the cross damping block 1A2 and the supporting frame rod 1A4 is overlapped to support a protection effect, and swing monitoring operation of pneumatic pressure resistance is improved.

Referring to fig. 3, the cross damping block 1a2 is composed of a three-frame buckle frame 1a21, a concave iron rod 1a22, a cross sliding groove 1a23, and a damping vibration tube 1a24, the three-frame buckle frame 1a21 and the concave iron rod 1a22 are buckled together and are perpendicular to each other, the concave iron rod 1a22 is provided with two parts and is respectively welded on the upper side and the lower side of the cross sliding groove 1a23, the damping vibration tube 1a24 is inserted and embedded in the cross sliding groove 1a23 and is located on the same horizontal plane, the damping vibration tube 1a24 is a shock insulation tube structure in which three sections of damping cotton blocks are sleeved and connected, so that three-section pressure-bearing impact wind-rotation operation is facilitated, the stability of the air pressure port retraction of the intake air is ensured, the sliding pressure springing effect of the wind pressure is formed by pulling the damping vibration tube 1a24 through the three-frame buckle frame 1a21, the unloading operation of the.

The cross sliding groove 1A23 of the cross damping block 1A2 slides and presses the arc cushion frame block 1A3 and the support rod 1A4 in the bolt frame rail 1A1 to form an impact effect in front of the absorption and detection of the wind pressure layered air bag, so that the three-frame buckling frame 1A21 is pulled and buckled with the concave iron rod 1A22 and the damping shock tube 1A24 to form damping unloading to improve the wind pressure brought into detection, and the stability of the whole air pressure difference and the accuracy of monitoring data are improved.

The invention achieves the effects of utilizing the cooperation of the wind vane saccule groove 1 and the integration plate ball seat 4, receiving high and low wind pressure values detected by the turbulent flow saccule pressing frame 1B and the advection wind guiding frame 1C at the top of the infrared monitoring disc 6 through the integration plate ball seat 4, forming saccule pressing annular layered wind pressure monitoring, ensuring the small-sized modeling framework effect of forming an air flow layer through winding in a cyclone in the building engineering environment, conveniently carrying out dialysis adaptation on the advection layer and the turbulent flow layer one by one to smoothly press the wind direction and the motion track, thereby feeding the potential to the working personnel in a sliding block operation mode, forming pneumatic pressure adapting different heights for the workers and the hoisting materials, forming uniform balance effect, improving the safety and the stability of the hoisting construction materials, improving the severe condition of the building engineering environment, and controlling the pneumatic pressure to form the borrowing transportation operation effect, the wind direction of environment can lead to what building section hoisted in the building engineering rocks the condition and damping counter weight pressure adjustment inequality with this, blow the in-process at wind pressure layering and too big wind-force, can cause to turn over the potential safety hazard that the pressure section bar leads to high altitude building material to fall, and wind power can blow the sand and dust material of pouring, cause the construction environment to produce dust particle, influence staff's respiratory track health, let the polytropy that wind pressure and wind direction detected disturb the engineering progress of construction among the construction, cause the wind pressure clearance between the construction floor and carry material hoist and mount to swing and produce the height head, cause the problem of construction accident easily.

The specific embodiments described herein are merely illustrative of the invention. Various modifications or additions may be made to the described embodiments or alternatives may be employed by those skilled in the art without departing from the scope of the invention or exceeding the scope of the claims appended hereto.

Claims (8)

1. A building engineering environment monitoring device structurally comprises: wind vane sacculus groove (1), hoist and mount armed lever (2), hanging plate (3), integrated board ball seat (4), bearing ring seat (5), infrared monitoring dish (6), ball cap casing (7), its characterized in that:

the wind vane balloon groove (1) is nested on the top of the hoisting arm rod (2), the wall hanging plate (3) is tightly attached to the left side of the hoisting arm rod (2), the hoisting arm rod (2) is inserted and embedded on the top of the integration plate ball seat (4), the integration plate ball seat (4) is mechanically connected with the ball cap shell (7) through a bearing ring seat (5), the infrared monitoring disc (6) is installed inside the ball cap shell (7), and the infrared monitoring disc (6) is electrically connected with the integration plate ball seat (4);

the wind vane balloon groove (1) is provided with a damping supporting and pressing frame (1A), a turbulent flow balloon pressing frame (1B), an advection wind guide frame (1C), a balloon shell block (1D), a valve block (1E), a channel bending frame rod (1F) and a guide plate (1G);

damping props and presses frame (1A) and lamella piece (1E) to insert respectively and inlays in the left and right sides of sacculus shell piece (1D), curved hack lever of corridor (1F) is in the same place with guide plate (1G) lock, curved hack lever of corridor (1F) is inserted and is inlayed in the inside of sacculus shell piece (1D), indiscriminate flow bag presses frame (1B) and advection wind-guiding frame (1C) and all inserts the inside of inlaying in sacculus shell piece (1D), sacculus shell piece (1D) nestification is on the top of hoist and mount armed lever (2).

2. A construction work environment monitoring apparatus according to claim 1, wherein: damping props and presses frame (1A) to constitute by bolt frame rail (1A 1), cross damping piece (1A 2), arc pad frame piece (1A 3), vaulting pole (1A 4), bolt frame rail (1A 1) cooperatees with cross damping piece (1A 2), bolt frame rail (1A 1) and arc pad frame piece (1A 3) are inserted and are inlayed together, arc pad frame piece (1A 3) and vaulting pole (1A 4) mechanical connection.

3. A construction work environment monitoring apparatus according to claim 2, wherein: cross damping piece (1A 2) is buckled frame (1A 21), concave type iron pole (1A 22), cross spout (1A 23), damping and shakes and manage (1A 24) by three frames and constitute, three frames are buckled frame (1A 21) and concave type iron pole (1A 22) and are buckled together, concave type iron pole (1A 22) are equipped with two and weld respectively in the upper and lower both sides of cross spout (1A 23), damping shakes pipe (1A 24) and inserts the inside of inlaying in cross spout (1A 23).

4. A construction work environment monitoring apparatus according to claim 1, wherein: the turbulent flow air bag pressing frame (1B) is composed of a flat air bag (1B 1), a sliding block rod (1B 2) and a short rail frame (1B 3), the flat air bag (1B 1) is nested on the top of the sliding block rod (1B 2), and the sliding block rod (1B 2) is movably connected with the short rail frame (1B 3).

5. The construction engineering environment monitoring device according to claim 4, wherein: flat gasbag (1B 1) comprises seam clamp plate wall (1B 11), corrugated cotton piece (1B 12), through-hole (1B 13), flat sacculus of band (1B 14), seam clamp plate wall (1B 11) and flat sacculus of band (1B 14) nestification are integrative, corrugated cotton piece (1B 12) and through-hole (1B 13) structure as an organic whole, corrugated cotton piece (1B 12) hug closely in the inside of flat sacculus of band (1B 14).

6. A construction work environment monitoring apparatus according to claim 1, wherein: advection air guide frame (1C) comprises pterygoid lamina sacculus (1C 1), jib (1C 2), moment of torsion slider (1C 3), long rail frame board (1C 4), pterygoid lamina sacculus (1C 1) are nested under the bottom of jib (1C 2), jib (1C 2) are inserted and are inlayed under the bottom of moment of torsion slider (1C 3), moment of torsion slider (1C 3) cooperate with long rail frame board (1C 4).

7. The construction engineering environment monitoring device according to claim 6, wherein: wing board sacculus (1C 1) comprises plectrum board (1C 11), pterygoid lamina frame (1C 12), oval sacculus (1C 13), ring cap (1C 14) admits air, plectrum board (1C 11) and pterygoid lamina frame (1C 12) are inserted and are inlayed integratively, pterygoid lamina frame (1C 12) are installed in the inside of oval sacculus (1C 13), oval sacculus (1C 13) and ring cap (1C 14) structure as an organic whole admits air.

8. The construction engineering environment monitoring device according to claim 6, wherein: the torque slider (1C 3) is composed of two counterweight balls (1C 31), slider grooves (1C 32), track rings (1C 33) and a pair support frame block (1C 34), the counterweight balls (1C 31) are respectively nested on the upper side and the lower side of the slider grooves (1C 32), the track rings (1C 33) are installed inside the slider grooves (1C 32), and the track rings (1C 33) are mechanically connected with the pair support frame block (1C 34).

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