CN220230723U - Adjustable radiation monitoring instrument support structure - Google Patents

Abstract

The utility model relates to the technical field of building construction and proposes an adjustable radiation monitoring instrument bracket structure. The top of the top cover is fixedly connected with a solar radiation sensor, and the outer wall of the fixed main rod is provided with an adjustment mechanism. The mechanism is used to extend the support rod vertically to adjust the height of the detection chassis. A solar radiation sensor is set up to monitor and measure the value of solar radiation and solar energy in real time, adding the function of the monitoring device, and setting up an adjustment mechanism, turning the hand to make the worm rotate and mesh with the worm gear, so that the rotating shaft and screw rod rotate synchronously, so that the displacement rod moves upward The effect of resisting the extension support and synchronous height adjustment of the detection chassis; by setting the worm rotation and meshing with the worm gear, after the height adjustment of the detection chassis is completed, the worm has self-locking properties. When the helix angle of the worm is very small, the worm can only drive Worm gear transmission, and the principle that the worm gear cannot drive the worm to rotate can achieve high locking of the detection chassis.

Description

An adjustable radiation monitoring instrument bracket structure

Technical field

The utility model relates to the technical field of building construction, specifically to an adjustable radiation monitoring instrument bracket structure.

Background technique

Radiation monitoring refers to radiation measurements or radioactivity measurements for the purpose of evaluating and controlling exposure to radiation or radioactive substances, as well as the analysis and interpretation of measurement results. Solar radiation monitoring and air environment monitoring are usually required during building construction, and solar radiation monitoring is mainly used to measure solar radiation and solar energy. It can be widely used in solar energy utilization, meteorology, agriculture, aging of building materials, air pollution and other departments to measure solar radiation energy. The intensity of solar radiation energy at construction sites can be detected.

After searching, the utility model patent with publication number CN210567192U discloses an environmental monitoring device for building construction, which includes a fixed main pole. The top of the fixed main pole is connected with a vertically arranged extended support pole through bolts. The extended support pole The top of the rod is connected with a vertically arranged detection chassis through bolts. The circumferential inner wall of the detection chassis is fixed with a horizontally arranged installation disk through bolts. The top of the installation disk is connected with a horizontally installed mounting plate through bolts. The top end of the installation plate is connected with a horizontally arranged controller through bolts, the other end of the top of the installation plate is connected with a vertically installed humidity sensor through bolts, and the top of the detection chassis is connected with a horizontally installed top cover through bolts , the circumferential outer wall of the detection chassis is provided with vertical detection holes;

However, during the implementation of related technologies, the following problems were found: the light radiation in the construction site cannot be synchronously monitored, and when the monitoring device is used, the detection chassis needs to be manually rotated to adjust the height of the extension pole, which is not only time-consuming and labor-intensive, but also Moreover, since there are a variety of components installed inside the detection chassis and the weight is relatively large, it is easy for the extension rod and the fixed main rod to slip and suddenly fall.

Therefore, an adjustable radiation monitoring instrument support structure is needed.

Utility model content

The utility model proposes an adjustable radiation monitoring instrument bracket structure, which solves certain limitations of environmental monitoring devices for building construction in related technologies, such that the light radiation in the building construction site cannot be synchronously monitored, and the application of the monitoring device At this time, the detection chassis needs to be manually rotated to adjust the height of the extension pole, which is not only time-consuming and labor-intensive, but also because there are many components installed inside the detection chassis and the weight is relatively large, and the extension pole and the fixed main pole are prone to slipping and sudden The question of whereabouts.

The technical solution of the utility model is as follows: an adjustable radiation monitoring instrument bracket structure, including a fixed main rod, an extended support rod located inside the fixed main rod, and a fixed bolt fixed at the bottom end of the fixed main rod. A fixed frame is fixedly connected to the top of the rod. A detection chassis is fixedly connected to the inside of the fixed frame. A detection hole is provided on the surface of the detection chassis. A mounting disc is fixedly connected to the inside of the detection chassis. The mounting disc is fixedly connected to the top of the rod. A mounting plate is fixedly connected to the top of the mounting plate, a controller is fixedly mounted on the top of the mounting plate, a humidity sensor is fixedly mounted on the top of the mounting plate, a dust sensor is fixedly mounted on the top of the mounting plate, and a dust sensor is fixedly mounted on the top of the mounting plate. A temperature sensor is fixedly installed, a battery is fixedly installed at the bottom of the installation disc, a top cover is fixedly installed at the top of the detection chassis, a solar radiation sensor is fixedly connected to the top of the top cover, and the outer wall of the fixed main rod An adjustment mechanism is provided for vertically extending the support rod to adjust the height of the detection chassis.

Preferably, the solar radiation sensor is electrically connected to the controller.

Preferably, the adjustment mechanism includes a rotating hand, the inner wall of the rotating hand is fixedly connected with a worm, one side of the worm is meshed with a worm gear, the inner wall of the worm gear is fixedly connected with a rotating shaft, and the bottom end of the rotating shaft is connected to the fixed main body. The inner wall of the rod is rotationally connected, the top end of the rotating shaft is fixedly connected to a screw rod, the outer wall of the screw rod is threadedly connected to a displacement rod, and the top end of the displacement rod is fixedly connected to the bottom end of the extended support rod.

Preferably, a vertical rod is fixedly connected to the top of the top cover, a photovoltaic panel is fixedly installed on the top of the vertical rod, and the photovoltaic panel is electrically connected to the battery.

Preferably, the outer wall of the fixed main rod is provided with a chute, the inner wall of the chute is slidingly connected with a slider, the top of the slider is fixedly connected with a long rod, and one end of the long rod is connected to the extension pole. External wall fixed connection.

Preferably, the outer wall of the fixed main rod is fixedly connected with a fixed base, one end of the worm penetrates the inner wall of the fixed base and extends to the inside of the fixed main rod, and the outer wall of the worm is rotationally connected to the inner wall of the fixed base.

Preferably, the displacement rod has a cylindrical shape, and a threaded groove is provided inside the displacement rod.

Preferably, the number of the long rods is one pair, and they are symmetrically arranged on both sides of the outer wall of the fixed main rod.

The working principle and beneficial effects of this utility model are:

1. This utility model is equipped with a solar radiation sensor that can monitor and measure the value of solar radiation and solar energy in real time. It adds the function of the monitoring device and is equipped with an adjustment mechanism. Turn the hand to make the worm rotate and mesh with the worm gear, so that the rotating shaft and screw rod rotate synchronously. The effect of moving the displacement rod upward to resist the extension pole and detecting the synchronous height adjustment of the chassis. Compared with the existing technology, this adjustment mechanism will not cause the problem of sliding or sudden falling when detecting the height adjustment of the chassis;

2. This utility model sets the worm to rotate and mesh with the worm gear. After adjusting the height of the detection cabinet, the worm is self-locking. When the helix angle of the worm is very small, the worm can only drive the worm gear, but the worm gear cannot drive the worm to rotate. Based on the principle, the detection chassis can be highly locked, which can prevent the detection chassis from sliding and is easy and fast to operate.

Description of the drawings

The utility model will be described in further detail below in conjunction with the accompanying drawings and specific implementation modes.

Figure 1 is a schematic diagram of the three-dimensional structure proposed by the present utility model;

Figure 2 is a schematic cross-sectional plan structural diagram of the utility model;

Figure 3 is a partial cross-sectional structural schematic diagram of the utility model proposed;

Figure 4 is an enlarged structural schematic diagram of A in Figure 3 proposed by the present utility model;

Figure 5 is an exploded schematic diagram of the internal structure of the detection chassis proposed by the present utility model.

In the picture: 1 fixed main rod; 11 fixed bolt; 12 extended support rod; 13 fixed frame; 14 detection chassis; 15 detection hole; 16 mounting disc; 17 mounting plate; 18 controller; 19 humidity sensor; 110 dust sensor ; 111 temperature sensor; 112 battery; 113 top cover; 2 solar radiation sensor; 3 fixed base; 4 adjustment mechanism; 41 hand; 42 worm; 43 worm gear; 44 rotating shaft; 45 displacement rod; 46 screw rod; 47 long rod; 48 Slider; 49 chute; 5 vertical rods; 6 photovoltaic panels.

Detailed ways

The technical solutions in the embodiments of the present utility model will be clearly and completely described below with reference to the embodiments of the present utility model. Obviously, the described embodiments are only some of the embodiments of the present utility model, rather than all the embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by those of ordinary skill in the art without creative efforts fall within the scope of protection of the present utility model.

Please refer to Figures 1 to 5. The present utility model provides a technical solution for an adjustable radiation monitoring instrument bracket structure: an adjustable radiation monitoring instrument bracket structure, including a fixed main rod 1 and a fixed main rod 1. The extension pole 12 and the fixing bolt piece 11 fixed at the bottom of the fixed main pole 1 are fixedly connected to the fixed frame 13 at the top of the extension pole 12. The inside of the fixed frame 13 is fixedly connected to the detection chassis 14, and the surface of the detection chassis 14 is provided with The detection hole 15 is fixedly connected with a mounting disc 16 inside the detection chassis 14. The top of the mounting disc 16 is fixedly connected with a mounting plate 17. The top of the mounting plate 17 is fixedly mounted with a controller 18. The top of the mounting plate 17 is fixedly mounted with a Humidity sensor 19, dust sensor 110 is fixedly installed on the top of the installation plate 17, and temperature sensor 111 is fixedly installed on the top of the installation plate 17;

A battery 112 is fixedly installed at the bottom of the installation disc 16, a vertical pole 5 is fixedly connected to the top of the top cover 113, and a photovoltaic panel 6 is fixedly installed at the top of the vertical pole 5. The purpose of the photovoltaic panel 6 is to generate electricity, which uses a semiconductor interface. A technology that directly converts light energy into electrical energy through the photovoltaic effect, which can store electricity in the battery 112. The photovoltaic panel 6 is electrically connected to the battery 112. A top cover 113 is fixedly installed on the top of the detection chassis 14. A solar radiation sensor 2 is fixedly connected to the top of the cover 113. The main function of the solar radiation sensor 2 is to measure solar radiation and solar energy. The solar radiation sensor 2 is electrically connected to the controller 18;

The outer wall of the fixed main rod 1 is provided with an adjustment mechanism 4. The adjustment mechanism 4 is used to vertically extend the support rod 12 to adjust the height of the detection cabinet 14. The outer wall of the fixed main rod 1 is provided with a chute 49, and the inner wall of the chute 49 A slider 48 is slidably connected to limit the extension of the support rod 12. A long rod 47 is fixedly connected to the top of the slider 48. The number of the long rods 47 is a pair and is symmetrically arranged on the outer wall of the fixed main rod 1. On both sides of the two sides, one end of the long rod 47 is fixedly connected to the outer wall of the extended support rod 12. The adjustment mechanism 4 includes a turn handle 41. The inner wall of the turn handle 41 is fixedly connected with a worm 42, and the outer wall of the fixed main rod 1 is fixedly connected with a fixing seat 3. The worm 42 plays a position-defining role. One end of the worm 42 penetrates the inner wall of the fixed base 3 and extends to the inside of the fixed main rod 1. The outer wall of the worm 42 is rotationally connected to the inner wall of the fixed base 3. One side of the worm 42 is engaged and connected. There is a worm gear 43. The inner wall of the worm gear 43 is fixedly connected with a rotating shaft 44. The bottom end of the rotating shaft 44 is rotationally connected with the inner wall of the fixed main rod 1. The top end of the rotating shaft 44 is fixedly connected with a screw rod 46. The outer wall of the screw rod 46 is threadedly connected with a displacement rod. 45. The displacement rod 45 has a cylindrical shape, and a threaded groove is provided inside the displacement rod 45. The top end of the displacement rod 45 is fixedly connected to the bottom end of the extended support rod 12.

The working principle and usage process of the utility model: First, according to the existing technical process (the operator first fixes the fixing bolt of the environmental monitoring device on the top of the building under construction or at a suitable location through bolts and fixing bolt holes, and then fixes the entire The environmental monitoring device is fixed and stable. During the operation of the device, the battery at the bottom provides electric energy. The internal controller can detect the environment in real time. The building environment can be detected through the humidity sensor, dust sensor and temperature sensor. The detected environmental data can be transmitted to the ground machine through the controller). On the basis of the existing technology, a solar radiation sensor 2 is added. The solar radiation sensor 2 can simultaneously monitor the light radiation in the construction site. , which further improves the comprehensiveness of the monitoring device. When it is necessary to adjust the height of the detection chassis 14, turn the handle 41 to drive the worm 42 to rotate. The worm 42 rotates and meshes with the worm gear 43, so that the worm gear 43 rotates and synchronously drives the rotating shaft 44 to rotate, and the rotating shaft 4 rotates. The screw rod 46 is driven to rotate, and the screw rod 46 rotates to move the displacement rod 45 upward and drive the extension support rod 12 to move upward to achieve the effect of adjusting the height of the detection chassis 14. After adjusting to the appropriate position, stop rotating and turn the hand 41 to adjust the height of the detection chassis 14. locking.

The above are only preferred embodiments of the present utility model and are not intended to limit the present utility model. Any modifications, equivalent substitutions, improvements, etc. made within the spirit and principles of the present utility model shall be included in the present utility model. Within the scope of new protection.

Claims (8)

1. The utility model provides an adjustable radiation monitoring instrument support structure, includes dead lever (1), establishes extension branch (12) in dead lever (1) inside, fixes dead bolt piece (11) in dead lever (1) bottom, the top fixedly connected with fixed frame (13) of extension branch (12), the inside fixedly connected with of fixed frame (13) detects quick-witted case (14), detection hole (15) have been seted up on the surface of detecting quick-witted case (14), the inside fixedly connected with of detecting quick-witted case (14) installs disc (16), the top fixedly connected with mounting panel (17) of mounting disc (16), the top fixedly connected with of mounting panel (17) has controller (18), the top fixedly connected with humidity transducer (19) of mounting panel (17), the top fixedly connected with dust sensor (110) of mounting panel (17), the top fixedly connected with temperature sensor (111) of mounting panel (17), the bottom fixedly connected with battery (112) of mounting disc (16), the top fixedly connected with top cap (113), characterized in that sun sensor (113) is fixed in that sun machine case (2) is fixed in the outer wall (1), the adjusting mechanism (4) is used for vertically extending the extension supporting rod (12) to adjust the height of the detection machine case (14).

2. An adjustable radiation monitoring instrument holder structure according to claim 1, characterized in that the solar radiation sensor (2) is electrically connected to a controller (18).

3. The adjustable radiation monitoring instrument support structure according to claim 1, wherein the adjusting mechanism (4) comprises a rotating hand (41), the inner wall of the rotating hand (41) is fixedly connected with a worm (42), one side of the worm (42) is connected with a worm wheel (43) in a meshed mode, the inner wall of the worm wheel (43) is fixedly connected with a rotating shaft (44), the bottom end of the rotating shaft (44) is rotatably connected with the inner wall of the fixed main rod (1), the top end of the rotating shaft (44) is fixedly connected with a screw rod (46), the outer wall of the screw rod (46) is in threaded connection with a displacement rod (45), and the top end of the displacement rod (45) is fixedly connected with the bottom end of the extension supporting rod (12).

4. An adjustable radiation monitoring instrument support structure according to claim 1, characterized in that the top of the top cover (113) is fixedly connected with a vertical rod (5), the top end of the vertical rod (5) is fixedly provided with a photovoltaic panel (6), and the photovoltaic panel (6) is electrically connected with a storage battery (112).

5. An adjustable radiation monitoring instrument support structure according to claim 1, characterized in that a chute (49) is provided on the outer wall of the fixed main rod (1), the inner wall of the chute (49) is slidably connected with a slide block (48), the top of the slide block (48) is fixedly connected with a long rod (47), and one end of the long rod (47) is fixedly connected with the outer wall of the extension strut (12).

6. An adjustable radiation monitoring instrument support structure according to claim 1, characterized in that the outer wall of the fixed main rod (1) is fixedly connected with a fixed seat (3), one end of the worm (42) penetrates through the inner wall of the fixed seat (3) and extends to the inside of the fixed main rod (1), and the outer wall of the worm (42) is rotationally connected with the inner wall of the fixed seat (3).

7. An adjustable radiation monitoring instrument support structure according to claim 3, characterized in that the displacement rod (45) is cylindrical in shape and the interior of the displacement rod (45) is provided with a thread groove.

8. An adjustable radiation monitoring instrument holder structure according to claim 5, characterized in that the number of the long rods (47) is one pair, and symmetrically arranged at both sides of the outer wall of the stationary main rod (1).