CN219120289U - Adjusting equipment for unorganized emission monitoring points - Google Patents

Abstract

The utility model discloses an adjusting device for an unorganized emission monitoring point, which relates to the technical field of air environment monitoring and comprises the following components: the installation base piece is of an I-shaped structure; the supporting mechanism is positioned in the bottom of the mounting substrate; the rotating mechanism is positioned in the upper part of the bottom of the mounting base member; and the isolation assembly is positioned at the top of the mounting base member. After the adjusting device moves to a designated position, the two-way adjusting screw rod is driven to rotate through the first gear and the second gear, the position of the moving block is relatively moved through the two-way adjusting screw rod, and then the positions of the connecting plate and the supporting cone are driven to penetrate deep into the place, so that the fixing of the position of the device is completed.

Description

Adjusting equipment for unorganized emission monitoring points

Technical Field

The utility model relates to the technical field of air environment monitoring, in particular to an unorganized emission monitoring point adjusting device.

Background

The application number is found by the search of the inventor: the utility model patent of CN201921678664.8 discloses a gas sampling device for environment detection, which drives a threaded sleeve to move through a threaded rod, the threaded sleeve drives a first fixed block to move, the first fixed block drives a connecting rod to move, the connecting rod drives a second fixed block to move, the second fixed block drives a fixed plate to move, and the fixed plate drives an atmosphere sampler body to move, so that the aim of height adjustment of the existing gas sampling device for environment detection in the use process can be achieved, and the problem that the existing air sampling device cannot accurately detect dust, particles, harmful gas and other contents in the atmosphere due to the limitation of sampling height in the use process is solved.

The sampling device can be suitable for detecting the contents of dust, particles, harmful gases and the like at different heights in the atmosphere, but the structure is relatively fixed, and the position and the angle of the device are difficult to adjust according to external environmental factors such as wind direction and the like when the sampling device is used, so that the applicability of the device is lower.

Disclosure of Invention

The utility model aims to solve the technical problems that the detection process in the prior art is long in time consumption, large in difficulty, more in variable and difficult to control, the structure tends to be complex, and certain inconvenience exists in use, and provides an unorganized emission monitoring point adjusting device.

In order to achieve the above purpose, the present utility model provides the following technical solutions:

an unstructured emissions monitoring point adjustment device comprising:

the installation base piece is of an I-shaped structure;

the supporting mechanism is positioned in the bottom of the mounting base member;

the rotating mechanism is positioned in the upper part of the bottom of the mounting base member;

and the isolation assembly is positioned at the top of the mounting base member.

Preferably, the mounting base member includes:

the four corners of the bottom of the mounting plate are respectively and rotatably connected with a movable wheel;

the telescopic sleeve is positioned at the upper part of the top of the mounting plate;

the extension rod is positioned at the top of the inside of the telescopic sleeve, and positioning holes are distributed in the center of the front end of the extension rod from top to bottom at equal intervals;

the positioning buckle is rotationally connected to the lower inner part of the top of the front end of the telescopic sleeve;

the display screen is fixedly arranged at the front end of the extension rod, which is lower than the top of the extension rod, and the top of the extension rod is fixedly connected with the monitor body.

Preferably, the support mechanism includes:

the adjusting groove is formed in the center of the bottom of the mounting plate;

the two-way adjusting screw rod is rotatably arranged at the front end and the rear end of the lower top of the inside of the adjusting groove, and the right end of the two-way adjusting screw rod is fixedly connected with an adjusting rod;

the first gear is positioned on the right side of the adjusting rod, and a second gear is meshed with the center of the opposite side of the first gear;

a rocker is fixedly connected to the center of the right side of the second gear;

the movable block is positioned on the outer surfaces of the left end and the right end of the bidirectional adjusting screw rod, and the bottom of the movable block is hinged with a lifting frame;

the connecting plate, the connecting plate is located the bottom of crane, and four equal fixedly connected with support awls in connecting plate bottom angle.

Preferably, the rotation mechanism includes:

the positioning plate is positioned at the top center of the mounting plate;

the mounting grooves are annularly and equidistantly distributed in the top of the positioning plate, the bottom of the inside of the mounting grooves is fixedly connected with a spring, and the top of the spring is fixedly connected with a positioning pin;

the rotation shaft is positioned in the center of the top of the positioning plate, the top of the rotation shaft is fixedly connected with an adjusting plate, and handles are distributed on one side, far away from the center, of the adjusting plate at equal intervals.

Preferably, the inner surface of the bottom center of the adjusting plate is attached to the outer surface of the top of the positioning plate, and positioning holes are formed in the top of the inner part of the bottom center of the adjusting plate at equal intervals.

Preferably, the isolation assembly includes:

the protection plate is positioned at the top of the monitor body;

the adjusting sleeve is positioned at the front end of the left side of the top of the protection plate, and the outer surface of the upper part of the bottom of the adjusting sleeve is fixedly connected with an adjusting ring

The lifting screw rod is positioned at the top of the adjusting sleeve;

the telescopic sleeves are positioned on the right side of the front end and the left side and the right side of the rear end of the top of the protection plate, and the center of the top of the protection plate is fixedly connected with a warning lamp;

the heat insulating plate is positioned at the top of the telescopic sleeve.

Preferably, the bidirectional adjusting screw rod penetrates through the inside of the moving block and extends to the inside of the moving block, and the supporting cone forms a lifting structure through the bidirectional adjusting screw rod and the moving block.

Compared with the prior art, the utility model has the beneficial effects that:

1. after the adjusting device moves to a designated position, the bidirectional adjusting screw rod is driven to rotate through the first gear and the second gear, the position of the moving block is relatively moved through the bidirectional adjusting screw rod, and then the positions of the connecting plate and the supporting cone are driven to go deep into the depth of the place, so that the fixing of the position of the device is completed, the device can be ensured to be firmly positioned at the monitoring point to be stable, and the smooth detection of the content of dust, particles, harmful gases and the like in the atmosphere of the monitoring point is ensured;

2. according to the adjusting device, the handle drives the adjusting plate to rotate by taking the center of the rotating shaft as the center of the circle, and then the rotating angle of the spring, the locating pin and the limiting Kong Duidiao section plate is limited, so that the angles of the telescopic sleeve, the telescopic rod and the display screen can be adjusted, and under the conditions of different wind directions and different heights, the device can detect dust, particles, harmful gas and other contents in the atmosphere of the monitoring point under the accurate conditions of the angles and the heights;

3. this conditioning equipment, in the use, receive under the condition of strong illumination, the temperature of the inside part of monitor body can rise, and the normal use of part can be influenced to the high temperature to lead to the life of equipment to shorten, through the high regulation to the heat insulating board, can play thermal-insulated effect, when rainy day, the high reduction of heat insulating board, then can avoid the rainwater to enter into the inside of monitor body.

Drawings

FIG. 1 is a schematic diagram of the overall structure of an unstructured emissions monitoring point adjustment device in accordance with one embodiment of the present utility model;

FIG. 2 is a schematic view of a supporting mechanism of an apparatus for adjusting an emissions control point in an embodiment of the present utility model;

FIG. 3 is an enlarged schematic view of the structure of FIG. 2A of an unstructured emissions monitoring point adjustment device in accordance with one embodiment of the present utility model;

FIG. 4 is a schematic diagram of a rotating mechanism of an unstructured emissions monitoring point adjustment device according to an embodiment of the present utility model;

FIG. 5 is a schematic diagram of an isolation assembly of an unstructured emissions monitoring point adjustment device according to an embodiment of the present utility model.

1. Mounting a base member; 101. a mounting plate; 102. a moving wheel; 103. a telescopic sleeve; 104. an extension rod; 105. positioning holes; 106. a positioning buckle; 107. a display screen; 108. a monitor body; 2. a support mechanism; 201. an adjustment tank; 202. a support cone; 203. a two-way adjusting screw rod; 204. an adjusting rod; 205. a first gear; 206. a second gear; 207. a rocker; 208. a moving block; 209. a lifting frame; 210. a connecting plate; 3. a rotating mechanism; 301. a positioning plate; 302. a handle; 303. a mounting groove; 304. a spring; 305. a positioning pin; 306. a rotating shaft; 307. an adjusting plate; 4. an isolation assembly; 401. a protection plate; 402. an adjusting sleeve; 403. an adjusting ring; 404. lifting the screw rod; 405. a telescoping tube; 406. a warning light; 407. and the heat insulation plate.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

FIG. 1 is a schematic diagram of the overall structure of an unstructured emissions monitoring point adjustment device in accordance with one embodiment of the present utility model; FIG. 2 is a schematic view of a supporting mechanism of an apparatus for adjusting an emissions control point in an embodiment of the present utility model; FIG. 3 is an enlarged schematic view of the structure of FIG. 2A of an unstructured emissions monitoring point adjustment device in accordance with one embodiment of the present utility model; FIG. 4 is a schematic diagram of a rotating mechanism of an unstructured emissions monitoring point adjustment device according to an embodiment of the present utility model; FIG. 5 is a schematic diagram of an isolation assembly of an unstructured emissions monitoring point adjustment device according to an embodiment of the present utility model.

In this embodiment, with reference to the accompanying drawings, an unstructured emission monitoring point adjustment device includes: the installation base piece 1 is in an I-shaped structure, and the installation base piece 1 is provided with a plurality of mounting holes; the supporting mechanism 2 is positioned in the bottom of the mounting base member 1; the rotating mechanism 3 is positioned in the upper part of the bottom of the mounting base member 1; isolation assembly 4 the isolation assembly 4 is located on top of the mounting base 1.

Specifically, the installation base member 1 is used as the installation benchmark of this detection device, bears the effect of structural connection and integration for whole detection device compact structure, the in-service use of being convenient for, supporting mechanism 2 is used for fixing the position of device, and slewing mechanism 3 is used for adjusting the angle of display screen 107, and isolation component 4 can protect the internals of monitor body 108 when using, thereby avoids appearing the damage because external environment leads to.

The mounting base 1 is further described in order to facilitate a thorough understanding of the specific structure and principles of the mounting base 1 by those skilled in the art. In the present embodiment, the mounting base 1 includes: the mounting plate 101, four corners of the bottom of the mounting plate 101 are respectively and rotatably connected with a movable wheel 102; the telescopic sleeve 103, the telescopic sleeve 103 is positioned at the upper part of the top of the mounting plate 101; the extension rod 104, the extension rod 104 is positioned at the top of the inside of the telescopic sleeve 103, and positioning holes 105 are distributed in the inside of the center of the front end of the extension rod 104 from top to bottom at equal intervals; the positioning buckle 106 is rotatably connected to the lower inner part of the top of the front end of the telescopic sleeve 103; the display screen 107, the front end that display screen 107 fixed mounting was in extension rod 104 top partial down, and the top fixedly connected with monitor body 108 of extension rod 104.

In the installation base 1, the installation plate 101 is used for installing, the telescopic bush 103 is used for installing the supporting mechanism 2, the extension rod 104 is used for installing the supporting mechanism 2, the telescopic bush 103 and the extension rod 104 are used for adjusting the height of the monitor body 108, and the monitor body 108 is used for installing the isolation assembly 4.

The support mechanism 2 is further described in order to facilitate a thorough understanding of the specific structure and principles of the support mechanism 2 by those skilled in the art. In the present embodiment, the support mechanism 2 includes: the adjusting groove 201 is formed in the center of the bottom of the mounting plate 101, and the adjusting groove 201 is formed in the center of the bottom of the mounting plate 101; the two-way adjusting screw rod 203 is rotatably arranged at the front end and the rear end of the lower top of the inside of the adjusting groove 201, and the right end of the two-way adjusting screw rod 203 is fixedly connected with an adjusting rod 204; a first gear 205, the first gear 205 being located at the right side of the adjustment lever 204, and a second gear 206 being engaged at the center of the opposite side of the first gear 205; a rocker 207 is fixedly connected to the right center of the second gear 206; the moving block 208, the outer surfaces of the left and right ends of the two-way adjusting screw 203 are positioned by the moving block 208, and the bottom of the moving block 208 is hinged with a lifting frame 209; the connecting plate 210, the connecting plate 210 is positioned at the bottom of the lifting frame 209, and four corners of the bottom of the connecting plate 210 are fixedly connected with the supporting cone 202; the bidirectional adjusting screw 203 penetrates through the inside of the moving block 208 and extends to the inside of the moving block 208, and the supporting cone 202 forms a lifting structure through the bidirectional adjusting screw 203 and the moving block 208.

In the supporting mechanism 2, after moving to a designated position, the bidirectional adjusting screw 203 is driven to rotate by the first gear 205 and the second gear 206, and the position of the moving block 208 is relatively moved by the bidirectional adjusting screw 203, so that the positions of the connecting plate 210 and the supporting cone 202 are driven to go deep into the place, and the fixing of the position of the device is completed.

The turning mechanism 3 is further described in order to facilitate a thorough understanding of the specific structure and principles of the turning mechanism 3 by those skilled in the art. In the present embodiment, the rotation mechanism 3 includes: a positioning plate 301, the positioning plate 301 being located at the top center of the mounting plate 101; the mounting grooves 303 are annularly and equidistantly distributed in the top of the positioning plate 301, the bottom of the inside of the mounting groove 303 is fixedly connected with a spring 304, and the top of the spring 304 is fixedly connected with a positioning pin 305; the axis of rotation 306, axis of rotation 306 are located the inside at locating plate 301 top center, and the top fixedly connected with regulating plate 307 of axis of rotation 306, and regulating plate 307 is kept away from the equidistant handle 302 that distributes in one side at center. The inner surface of the bottom center of the adjusting plate 307 is attached to the outer surface of the top of the positioning plate 301, and the positioning holes 105 are formed in the top of the inside of the bottom center of the adjusting plate 307 at equal intervals.

In the rotating mechanism 3, the handle 302 drives the adjusting plate 307 to rotate around the center of the rotating shaft 306, and then the rotation angle of the spring 304, the positioning pin 305 and the limiting Kong Duidiao segment 307 is limited, so that the angles of the telescopic sleeve 103, the extension rod 104 and the display screen 107 are adjusted.

The isolation assembly 4 is further described in order to facilitate a thorough understanding of the specific structure and principles of the isolation assembly 4 by those skilled in the art. In the present embodiment, the isolation assembly 4 includes: the isolation assembly 4 includes: a protection plate 401, the protection plate 401 being located on top of the monitor body 108; the adjusting sleeve 402 is positioned at the front end of the left side of the top of the protection plate 401, and the outer surface of the upper part of the bottom of the adjusting sleeve 402 is fixedly connected with an adjusting ring 403; a lifting screw 404, the lifting screw 404 being located at the top of the adjustment sleeve 402; the telescopic tube 405, the telescopic tube 405 locates at right side and left and right sides of rear end of front end of top of guard plate 401, and the top center department of the guard plate 401 fixedly connects with the warning light 406; heat shield 407, heat shield 407 is located on top of telescoping tube 405.

In the isolation component 4, under the condition of strong illumination in the use process, the temperature of the parts inside the monitor body 108 can rise, and the normal use of the parts can be influenced by the high temperature, so that the service life of the equipment is shortened, the heat insulation effect can be achieved through the adjustment of the height of the heat insulation plate 407, and in rainy days, the height of the heat insulation plate 407 is reduced, so that rainwater can be prevented from entering the inside of the monitor body 108.

Working principle: firstly, the whole position of the device is moved through the moving wheel 102, after the device is moved to a designated position, the rocker 207 is rotated, the second gear 206 is driven to rotate through the rocker 207, then the first gear 205 is driven to rotate through the meshing structure, when the first gear 205 rotates, the adjusting rod 204 and the bidirectional adjusting screw 203 are driven to synchronously rotate because the right side of the adjusting rod 204 is fixedly connected with the first gear 205, and when the bidirectional adjusting screw 203 penetrates through the inside of the moving block 208 and extends to the inside of the moving block 208, the position of the moving block 208 is driven to relatively move when the bidirectional adjusting screw 203 rotates, the lifting frame 209 is driven to extend through the moving block 208, then the height of the connecting plate 210 and the supporting cone 202 is driven to descend through the lifting frame 209, and the supporting cone 202 penetrates deep into the place, so that the whole position of the device is fixed;

according to actual monitoring requirements, the height of the monitor body 108 is adjusted, the height of the monitor body 108 can be adjusted through the adjustment of the length of the telescopic sleeve 103 and the extension rod 104 after combination, and after the adjustment is completed, the adjusted state is fixed through the positioning hole 105 and the positioning buckle 106;

according to the angle of the display screen 107, the handle 302 is pulled, the handle 302 drives the adjusting plate 307 to rotate by taking the center of the rotating shaft 306 as the center of a circle, and the rotating angle of the adjusting plate 307 is limited under the cooperation of the spring 304, the positioning pin 305 and the limiting hole, so that the angles of the telescopic sleeve 103, the extension rod 104 and the display screen 107 are adjusted;

during sunny days, the adjusting ring 403 is rotated, the adjusting sleeve 402 is driven to rotate through the adjusting ring 403, then the height of the lifting screw rod 404 is driven through the threaded structure to be adjusted, and the lifting screw rod 404 is used for driving the height of the heat insulation plate 407 to rise, so that the protection plate 401 plays a role in heat insulation, and during rainy days, the operation is reversed, and a rainproof effect is achieved.

Although the present utility model has been described with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments described, or equivalents may be substituted for elements thereof, and any modifications, equivalents, improvements and changes may be made without departing from the spirit and principles of the present utility model.

Claims (7)

1. An unstructured emissions monitoring point adjustment device, comprising:

the installation base piece (1), wherein the installation base piece (1) is of an I-shaped structure;

the supporting mechanism (2) is positioned in the bottom of the installation base piece (1);

the rotating mechanism (3) is positioned in the upper part of the bottom of the mounting base member (1);

and the isolation assembly (4) is positioned on the top of the mounting base (1).

2. An unstructured emissions monitoring point adjustment device according to claim 1, wherein:

the mounting base (1) comprises:

the device comprises a mounting plate (101), wherein the four corners of the bottom of the mounting plate (101) are respectively connected with a movable wheel (102) in a rotating way;

the telescopic sleeve (103) is positioned at the upper part of the top of the mounting plate (101);

the extension rod (104), the extension rod (104) is positioned at the top of the inside of the telescopic sleeve (103), and positioning holes (105) are distributed in the inside of the front end center of the extension rod (104) from top to bottom at equal intervals;

the positioning buckle (106) is rotationally connected to the lower inner part of the top of the front end of the telescopic sleeve (103);

the display screen (107), display screen (107) fixed mounting is in the front end that extension rod (104) top is partial down, and the top fixedly connected with monitor body (108) of extension rod (104).

3. An unstructured emissions monitoring point adjustment device according to claim 2, wherein:

the support mechanism (2) includes:

the adjusting groove (201) is formed in the center of the bottom of the mounting plate (101);

the bidirectional adjusting screw rod (203) is rotatably arranged at the front end and the rear end of the lower top of the inside of the adjusting groove (201), and the right end of the bidirectional adjusting screw rod (203) is fixedly connected with an adjusting rod (204);

the first gear (205), the said first gear (205) locates at the right side of the regulating lever (204), and the centre of the opposite side of the first gear (205) engages with the second gear (206);

a rocker (207) is fixedly connected to the right center of the second gear (206);

the movable block (208), the movable block (208) is positioned on the outer surfaces of the left end and the right end of the bidirectional adjusting screw rod (203), and the bottom of the movable block (208) is hinged with a lifting frame (209);

the connecting plate (210), connecting plate (210) are located the bottom of crane (209), and four angles in connecting plate (210) bottom are all fixedly connected with support awl (202).

4. An unstructured emissions monitoring point adjustment device according to claim 2, wherein:

the rotation mechanism (3) includes:

a positioning plate (301), the positioning plate (301) being located at the top center of the mounting plate (101);

the mounting grooves (303) are annularly and equidistantly distributed in the top of the positioning plate (301), springs (304) are fixedly connected to the bottoms of the inside of the mounting grooves (303), and positioning pins (305) are fixedly connected to the tops of the springs (304);

the rotating shaft (306), the rotating shaft (306) is located the inside at locating plate (301) top center, and the top fixedly connected with regulating plate (307) of rotating shaft (306), one side that regulating plate (307) kept away from the center equidistance distributes has handle (308).

5. An unstructured emissions monitoring point adjustment device according to claim 4, wherein: the inner surface of the bottom center of the adjusting plate (307) is attached to the outer surface of the top of the positioning plate (301), and limiting holes are formed in the top of the inside of the bottom center of the adjusting plate (307) at equal intervals.

6. An unstructured emissions monitoring point adjustment device according to claim 2, wherein:

the isolation assembly (4) comprises:

the protection plate (401), the protection plate (401) is positioned at the top of the monitor body (108);

the adjusting sleeve (402), the adjusting sleeve (402) is positioned at the front end of the left side of the top of the protection plate (401), and the outer surface of the upper part of the bottom of the adjusting sleeve (402) is fixedly connected with an adjusting ring (403)

The lifting screw rod (404), wherein the lifting screw rod (404) is positioned at the top of the adjusting sleeve (402);

the telescopic sleeve (405), the telescopic sleeve (405) is positioned on the right side of the front end and the left and right sides of the rear end of the top of the protection plate (401), and a warning lamp (406) is fixedly connected to the center of the top of the protection plate (401);

and the heat insulation plate (407), wherein the heat insulation plate (407) is positioned at the top of the telescopic sleeve (405).

7. An unstructured emissions monitoring point adjustment device according to claim 3, wherein: the bidirectional adjusting screw rod (203) penetrates through the moving block (208) and extends to the inside of the moving block (208), and the supporting cone (202) forms a lifting structure through the bidirectional adjusting screw rod (203) and the moving block (208).

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