CN107854936B - Biological haze control workstation - Google Patents

Abstract

The utility model discloses a biological haze control workstation, which comprises a support body and a haze prevention mechanism, wherein the support body and the haze prevention mechanism are arranged on an area to be treated, the haze prevention mechanism comprises a plurality of transverse plates which are arranged in a staggered manner from top to bottom along the inside of the support body, a first gap is arranged between each transverse plate and the inner side wall of the support body, a bulge is arranged at the edge, close to the first gap, of each transverse plate, and extends to the inner side wall of the support body, a containing cavity for containing algae is formed by the upper surface of each transverse plate, the bulge and the inner side wall of the support body, a plurality of through holes are formed in the side wall of the support body, a feeding pipe is arranged on the inner side wall of the upper part of the support body, a second gap is arranged between the bottom end of the feeding pipe and the transverse plate positioned at the uppermost layer, an opening part is formed at the upper end of the support body, and a collecting pool is arranged at the lower end of the support body. The utility model has simple structure, uses biological algae to treat haze, does not need energy consumption, quickly and efficiently relieves haze weather, and has strong practicability.

Description

Biological haze control workstation

Technical Field

The utility model belongs to the technical field of haze control and setting, and particularly relates to a biological haze control workstation.

Background

The control haze not only needs to reduce the pollution of the tail gas emission of the motor vehicle and encourage green travel, but also needs to increase the strength of monitoring the emission of heavy industrial production, but also has long treatment period, great difficulty and high complexity, and needs to balance factors in various aspects.

At present, application research of garden plants for preventing and treating haze is disclosed, and the research concludes dust stagnation effect of the garden plants, absorption and conversion of toxic substances and photosynthesis for keeping air fresh. The greening rate of cities is enlarged, the ecological corridor function of urban road greenbelts is exerted, related garden plants for reducing PM2.5 pollution are listed, but the greening problem of cities is always a difficult problem to solve. Therefore, a biological haze control workstation with a simple structure and reasonable design is needed at present, and haze treatment is carried out by utilizing biological algae, so that energy consumption is not needed, and haze weather is relieved rapidly and efficiently.

Disclosure of Invention

Aiming at the defects in the prior art, the utility model provides the biological haze control workstation which has the advantages of simple structure, reasonable design, good use effect, no energy consumption, rapid and efficient release of haze weather and strong practicability, and is used for haze control by utilizing biological algae.

In order to solve the technical problems, the utility model adopts the following technical scheme: a biological haze prevention workstation which is characterized in that: including setting up supporter and setting on treating the region and being in prevent haze mechanism in the supporter, prevent that haze mechanism includes a plurality of edges inside diaphragm that staggers from last to down set up of supporter, be provided with first clearance between diaphragm and the supporter inner wall, the diaphragm is close to the edge in first clearance is provided with the arch, just the arch extends to supporter inner wall, diaphragm upper surface, arch and supporter inner wall form the flourishing chamber that holds the alga, be provided with a plurality of through-holes on the supporter lateral wall, supporter upper portion inside wall is provided with the filling tube, be provided with the second clearance between the bottom of filling tube and the diaphragm that is located the upper strata, the upper end of supporter has the opening, the lower extreme of supporter is provided with the collecting vat.

Foretell a biological haze prevention and cure workstation, its characterized in that: the support body includes the multilayer and is used for supporting the supporting layer of a plurality of crossbeams respectively, every layer the supporting layer includes a plurality of vertical stands that set up and sets up two adjacent wallboard between the stand, be provided with toughened glass on the wallboard, a plurality of the through-hole all is located toughened glass.

Foretell a biological haze prevention and cure workstation, its characterized in that: the shape that a plurality of stand encloses is circular or regular polygon, and a plurality of stand, spliced pole and wallboard are reinforced concrete placement body, the quantity of stand is six at least.

Foretell a biological haze prevention and cure workstation, its characterized in that: the thickness of the toughened glass is 0.01 m-0.2 m.

Foretell a biological haze prevention and cure workstation, its characterized in that: the through hole is a conical hole, and the aperture of the conical hole is gradually increased from the inner side wall of the toughened glass to the outer side wall of the toughened glass;

the value range of the small aperture of the conical hole is 0.01 m-0.05 m, the value range of the large aperture of the conical hole is 0.05 m-0.2 m, and the distance between two adjacent conical holes is 0.05 m-0.35 m.

Foretell a biological haze prevention and cure workstation, its characterized in that: the internal center of support is vertical to be provided with the dead lever, the lower extreme of dead lever is installed in waiting to administer regional ground, the dead lever runs through a plurality of the diaphragm.

Foretell a biological haze prevention and cure workstation, its characterized in that: the solar water heater is characterized in that a heating mechanism is arranged in the support body and comprises a water heating pipe and a plurality of solar heat collecting plates arranged along the height direction of the fixing rod, the water heating pipe is arranged on the bottom surface of the transverse plate, the solar heat collecting plates are arranged on the fixing rod, and the solar heat collecting plates are positioned at the bottom of the water heating pipe.

Foretell a biological haze prevention and cure workstation, its characterized in that: and a switch is arranged on the water heating pipe.

Foretell a biological haze prevention and cure workstation, its characterized in that: the bottom of the collecting tank is provided with a supporting rod.

Foretell a biological haze prevention and cure workstation, its characterized in that: the vertical distance between two adjacent transverse plates is 2.0 m-5.0 m.

Compared with the prior art, the utility model has the following advantages:

1. the adopted biological haze control workstation is simple in structure and reasonable in design, and can effectively relieve haze weather, so that the aim of purifying air is fulfilled.

2. The adopted biological haze control workstation does not need to provide energy, so the energy consumption and pollution are avoided, and the economic cost is low.

3. The haze prevention mechanism has good use effect, algae are added in the transverse plate to purify air, and energy consumption is not needed; and a plurality of diaphragm edges the supporter is inside from last to setting down, has reduced the volume that the diaphragm occupy on the one hand, and on the other hand increases the area of alga to improve alga air-purifying's effect, avoided afforestation to prevent haze area big problem.

4. A first gap is arranged between the adopted transverse plate and the inner side wall of the support body, so that algae additionally arranged in the transverse plate on the upper layer can overflow into the transverse plate on the lower layer in sequence, and air purified by the algae can be conveniently discharged into the air again from bottom to top.

5. The edge of the adopted transverse plate, which is close to the first gap, is provided with the bulge, and the bulge extends to the inner side wall of the support body, so that the upper surface of the transverse plate, the bulge and the inner side wall of the support body form a containing cavity capable of containing algae, and the algae can be contained conveniently.

6. The inside wall of the upper portion of the support body is provided with the feeding pipe, algae are sequentially added into the transverse plate through the feeding pipe, so that the quantity of the algae is guaranteed to be maximized, haze is treated to the greatest extent, and air is purified.

7. A second gap is arranged between the bottom end of the feeding pipe and the transverse plate positioned at the uppermost layer, so that algae flowing out of the feeding pipe can enter the transverse plate at the uppermost layer conveniently, and the algae flowing out of the feeding pipe can be in full contact with the atmosphere conveniently.

8. The side wall of the support body is provided with a plurality of through holes, so that the air can enter the support body to provide a growing environment for algae, and the upper end of the support body is provided with an opening part, so that heat is generated by the growth of the algae, the heat in the support body is large, and the purified air purified by the algae can be conveniently discharged into the air again.

9. The lower extreme of the support body that adopts is provided with the collecting vat, and the collecting vat is used for collecting the algae after the PM2.5 granule and photosynthesis in the atmosphere will be absorbed, and the algae after the photosynthesis is rich in certain organic matter, can collect and be used for fertilization, and the value is high.

10. The utility model can be used for purifying air and can be used for scientific research, and stairs can be built in a workstation, so that scientific research is facilitated for scientific researchers.

In conclusion, the haze treatment device is simple in structure, reasonable in design, simple and convenient to operate, good in using effect, simple in structure, reasonable in design, good in using effect, capable of rapidly and efficiently relieving haze weather without energy consumption and high in practicability.

The technical scheme of the utility model is further described in detail through the drawings and the embodiments.

Drawings

Fig. 1 is a schematic view of the structure in embodiment 1 (front side removed) of the present utility model.

Fig. 2 is a schematic structural diagram of a supporting layer in embodiment 1 of the present utility model.

Fig. 3 is a schematic structural diagram of a supporting layer in embodiment 2 of the present utility model.

Reference numerals illustrate:

1-toughened glass; 1-through hole, 2-fixing rod;

3-a transverse plate; 3-1-bulge; 4-a support;

4-1-upright post, 4-2-wallboard, 4-3-connecting post;

5-a feeding pipe; 6, collecting a pool; 7, a water heating pipe;

7-1-switching; 8-supporting rods; 9-a solar heat collecting plate;

10-the area to be treated.

Detailed Description

Example 1

As shown in fig. 1 and 2, the utility model comprises a supporting body 4 arranged on a region 10 to be treated and an anti-haze mechanism arranged in the supporting body 4, wherein the anti-haze mechanism comprises a plurality of transverse plates 3 which are arranged in a staggered manner from top to bottom along the inside of the supporting body 4, a first gap is arranged between each transverse plate 3 and the inner side wall of the supporting body 4, a bulge 3-1 is arranged at the edge of each transverse plate 3, which is close to the first gap, the bulge 3-1 extends to the inner side wall of the supporting body 4, the upper surface of each transverse plate 3, the bulge 3-1 and the inner side wall of the supporting body 4 form a containing cavity for containing algae, a plurality of through holes 1-1 are formed in the side wall of the supporting body 4, a feeding pipe 5 is arranged at the inner side wall of the upper part of the supporting body 4, a second gap is arranged between the bottom end of the feeding pipe 5 and the transverse plate 3 positioned at the uppermost layer, an opening is arranged at the upper end of the supporting body 4, and a collecting pool 6 is arranged at the lower end of the supporting body 4.

In this example, the added algae was living algae containing water.

In this embodiment, the supporting body 4 and the haze preventing mechanism have simple structure, reasonable design, good use effect and low input cost; in addition, the haze prevention mechanism does not need to provide energy, so that the haze prevention mechanism has the advantages of no energy consumption, no pollution and low economic cost.

In the embodiment, the transverse plate 3 is arranged for purifying air by adding algae in the transverse plate 3, so that energy consumption is not required; the plurality of transverse plates 3 are arranged from top to bottom along the inside of the supporting body 4, so that the volume occupied by the transverse plates 3 is reduced, and more transverse plates 3 can be arranged in the supporting body 4 as much as possible; the area of the algae is increased, so that the effect of absorbing PM2.5 particles in the atmosphere by the algae to purify the air is improved, and the problem of large occupation area of greening haze prevention is avoided; and a plurality of transverse plates 3 are arranged in an up-down staggered manner, so that algae in the transverse plates 3 on the upper layer can automatically overflow into the transverse plates 3 on the lower layer after being fully added, and algae can be conveniently added into the transverse plates 3 on the lower layer, and the algae in the transverse plates 3 can be sequentially added.

In this embodiment, a first gap is provided between the transverse plate 3 and the inner side wall of the supporting body 4, so that algae can overflow into the transverse plate 3 at the lower layer in sequence after the algae is filled in the transverse plate 3 at the upper layer, and air purified by the algae can be conveniently discharged into the atmosphere again from bottom to top.

In this embodiment, the edge of the transverse plate 3 near the first gap is provided with the protrusion 3-1, and the protrusion 3-1 extends to the inner side wall of the supporting body 4, so that the upper surface of the transverse plate 3, the protrusion 3-1 and the inner side wall of the supporting body 4 form a containing cavity capable of containing algae, and the algae is contained conveniently.

In this embodiment, the feeding tube 5 is provided to facilitate adding algae into the accommodating cavity on the transverse plate 3, and to facilitate the algae to absorb PM2.5 particles in the atmosphere and to continuously add algae in a state that the algae die after photosynthesis, i.e. the algae quantity is reduced, so that the algae is convenient to add, thereby ensuring that the algae quantity is maximized and the atmosphere is treated to the greatest extent.

In this embodiment, a second gap is provided between the bottom end of the feeding tube 5 and the transverse plate 3 located at the uppermost layer, so that algae flowing out of the feeding tube 5 can enter the transverse plate 3 at the uppermost layer conveniently, and algae flowing out of the feeding tube conveniently can be fully contacted with the atmosphere.

In this embodiment, since the algae grows in the support body 4 to make the heat in the support body 4 large, the pressure in the support body 4 is smaller than the external pressure of the support body 4, and the through holes 1-1 are provided to facilitate the air to enter the support body 4 through the side wall of the support body 4, so as to be absorbed by the algae on the transverse plate 3, provide a growing environment for the algae, and enable the algae to contact with the air to absorb PM2.5 particles in the air.

In this embodiment, the supporting body 4 includes multiple supporting layers for supporting the transverse plates 3, each supporting layer includes multiple vertical columns 4-1, connecting columns 4-3 connected between the bottoms of two vertical columns 4-1, and wall plates 4-2 arranged between two adjacent vertical columns 4-1, toughened glass 1 is arranged on the wall plates 4-2, and multiple through holes 1-1 are all located on the toughened glass 1.

In the actual use process, the upright posts 4-1 at the same position in each supporting layer are of an integrated structure.

In this embodiment, the support layer center pillar 4-1 provided at the lowermost layer extends into the floor of the area to be treated 10.

In this embodiment, the upright posts 4-1 are provided to facilitate the installation of the toughened glass 1 and the transverse plates 3 and the staggered arrangement of the transverse plates 3 along the vertical direction, and the upper ends of the supporting bodies 4 are provided with openings, because the algae grow to generate heat, the heat in the supporting bodies 4 is greater than the heat outside the supporting bodies 4, so that the purified air after being purified by the algae is conveniently discharged into the air again from bottom to top; the collecting tank 8 is arranged at the lower end of the upright post 4-1, so as to collect and absorb PM2.5 particles in the atmosphere and algae after photosynthesis, and the algae after photosynthesis is rich in certain organic matters, can be collected and used for fertilization, and has high utilization value.

In this embodiment, the connection post 4-3 is arranged to be matched with the upright post 4-1 to facilitate the installation of the transverse plate 3, so that the edge of the transverse plate 3 is tightly contacted with the upright post 4-1 and the inner side wall of the connection post 4-4, and the stable installation of the transverse plate 3 is ensured.

In this embodiment, the setting of toughened glass 1 is not only favorable to the photosynthesis of the inside algae of supporter 4, conveniently observes moreover the inside specific condition of supporter 4, the staff of being convenient for research.

As shown in fig. 2, in this embodiment, it is further preferable that the number of the columns 4-1 is six, so as to improve the stability of the support body 4; the six stand columns 4-1 are round in shape, the supporting body 4 is of a cylindrical appearance structure, and the contact area between air and the structure can be increased by arranging the cylindrical appearance structure, so that the entering amount of the air is increased.

In this embodiment, the upright posts 4-1, the connecting posts 4-3 and the wall plates 4-2 are reinforced concrete casting bodies, so that the overall strength of the support body 4 is ensured, and the installation of a plurality of transverse plates 3 is convenient to meet.

In this embodiment, the thickness of the tempered glass 1 is 0.01m to 0.2m, so as to prevent damage to the tempered glass 1 caused by external environments such as strong wind and vibration, and prevent the workstation from haze treatment.

In this embodiment, the through hole 1-1 is a tapered hole 1-1, and the aperture of the tapered hole 1-1 gradually increases from the inner side wall of the tempered glass 1 to the outer side wall of the tempered glass 1;

the value range of the small aperture of the conical hole is 0.01 m-0.05 m, the value range of the large aperture of the conical hole is 0.05 m-0.2 m, and the distance between two adjacent conical holes is 0.05 m-0.35 m.

In this embodiment, the through holes 1-1 are provided as conical holes, which not only increases the air intake, but also reduces the diffusion of air from the support body 4 back into the atmosphere. When air enters the small-aperture end from the large-aperture end, the conical hole is a reducing pipe, the gas flow speed is increased, the pressure is reduced, the streamline is gradually reduced, no vortex is formed in the nozzle, the energy loss is small, and the external air easily flows into the supporting body 4; when the air in the support body 4 enters the end of the large aperture from the end of the small aperture, the taper hole is a gradually-expanding pipe, at the moment, the gas flow speed can be reduced, the pressure is increased, the streamline is gradually expanded, a backflow vortex can be formed in the nozzle, the vortex can increase the flow speed in the nozzle, and the energy loss is large, so that the air in the support body 4 is not easy to flow into the outside, the outside air is prevented from entering the support body 4, energy does not need to be provided, and the air inlet support body 4 is economical and practical.

In this embodiment, the range of the small aperture of the tapered hole is 0.01 m-0.05 m, the range of the large aperture of the tapered hole is 0.05 m-0.2 m, and the distance between two adjacent tapered holes is set to be 0.05 m-0.35 m, so that on one hand, the pressure inside and outside the support body 4 is prevented from being smaller due to the large number of tapered holes, and the atmosphere outside the support body 4 cannot be caused to enter the support body 4; on the other hand, the situation that the support body 4 is not insulated due to the large number of the conical holes, which is unfavorable for the growth of algae, is avoided.

In this embodiment, a fixing rod 2 is vertically disposed in the inner center of the support body 4, the lower end of the fixing rod 2 is installed in the ground of the area to be treated 10, and the fixing rod 2 penetrates through a plurality of transverse plates 3.

In this embodiment, because the edge of the transverse plate 3 near the first gap is suspended, the fixing rod 2 is arranged to effectively fix the edge of the suspended transverse plate 3, so as to ensure the connection strength of the transverse plate 3 and facilitate the installation of the solar heat collecting plate 9.

In this embodiment, a heating mechanism is disposed in the support body 4, the heating mechanism includes a water heating pipe 7 and a plurality of solar heat collecting plates 9 disposed along the height direction of the fixing rod 2, the water heating pipe 7 is mounted on the bottom surface of the transverse plate 3, the solar heat collecting plates 9 are mounted on the fixing rod 2, and the solar heat collecting plates 9 are located at the bottom of the water heating pipe 7.

In this embodiment, the setting of heating mechanism, including water heating pipe 7 and solar heat collecting plate 9, solar heat collecting plate 9 utilizes solar energy to carry out heat accumulation, does not need the external energy that provides, and is with low costs, and is applicable to the open-air environment, and water heating pipe 7 and solar heat collecting plate 9 combined action come control diaphragm 3's temperature to control the optimal temperature of the growth of algae and photosynthesis on the diaphragm 3, thereby improve the efficiency of air purification.

In this embodiment, the switch 7-1 is provided on the water heating pipe 7 to facilitate the control of the water heating pipe 7 as required.

In this embodiment, the bottom of the collecting tank 6 is provided with the supporting rod 8, so that the collecting tank 6 is spaced from one end of the bottom of the supporting body 4, thereby providing air required for growth for organisms in the collecting tank 6, and being capable of converting collected PM2.5 particles in the absorption atmosphere and algae after photosynthesis into fertilizer, thereby improving the utilization rate.

In this embodiment, the vertical distance between two adjacent cross plates 3 is 2.0m to 5.0m.

In the embodiment, the vertical distance between the transverse plates 3 is 2.0 m-5.0 m, on one hand, in order to keep the air circulation in the supporting body 4, ensure the normal growth of algae in the transverse plates 3 and absorb PM2.5 particles in the atmosphere; on the other hand, personnel can enter the support body 4 for maintenance.

When the utility model is specifically used, a certain amount of algae is added through the charging pipe 5, after the algae in the upper transverse plate 3 is filled up, the algae can overflow into the lower transverse plate 3 in sequence until the algae in the lowest transverse plate 3 is filled up, so that the algae is added into each tower plate 3, after the air enters the supporting body 4 through the conical holes, PM2.5 particles or carbon dioxide in the air can fully contact with the algae in the transverse plate 3, the algae can absorb the PM2.5 particles in the air and also can absorb the carbon dioxide in the air for photosynthesis, thereby achieving the aim of purifying air, and when the algae die (namely, the algae is reduced in quantity) after the algae is absorbed in the air, the algae can be continuously added through the charging pipe 5, so that the algae is convenient to add, the maximized quantity of the algae is ensured, and the atmosphere is treated to the greatest extent. In addition, PM2.5 particles in the atmosphere and algae after photosynthesis can be absorbed into the collecting tank 8, and because the algae after photosynthesis is rich in certain organic matters, the collecting tank 8 collects and converts the algae after photosynthesis into fertilizer application, thereby changing waste into valuables, improving the utilization rate of the algae, avoiding environmental pollution caused by dead algae and having high utilization value. In the process of absorbing PM2.5 particles in the atmosphere and photosynthesis by algae, water with a certain temperature is introduced into the water heating pipe 7 to reach the proper temperature for survival of the algae, or the radiant energy of the sun is converted into heat energy by utilizing the solar heat collecting plate 9 to store the heat, the water heating pipe 7 and the solar heat collecting plate 9 jointly act to control the temperature of the transverse plate 3 without providing energy from the outside, so that the optimal temperature for growth and photosynthesis of the algae on the transverse plate 3 is controlled, PM2.5 particles in the atmosphere can be absorbed, photosynthesis can be maximized, and the aim of purifying the air is achieved. Therefore, the haze treatment is carried out by utilizing the biological algae, energy consumption is not needed, the haze weather is quickly and efficiently relieved, and the practicability is strong.

Example 2

This embodiment differs from embodiment 1 only in that: the shape surrounded by the upright posts 4-1 is regular hexagon.

The foregoing description is only a preferred embodiment of the present utility model, and is not intended to limit the present utility model, and any simple modification, variation and equivalent structural changes made to the above embodiment according to the technical substance of the present utility model still fall within the scope of the technical solution of the present utility model.

Claims (8)

1. A biological haze prevention workstation which is characterized in that: the anti-haze device comprises a supporting body (4) arranged on an area (10) to be treated and an anti-haze mechanism arranged in the supporting body (4), wherein the anti-haze mechanism comprises a plurality of transverse plates (3) which are arranged in a staggered manner from top to bottom along the inside of the supporting body (4), a first gap is formed between each transverse plate (3) and the inner side wall of the supporting body (4), a bulge (3-1) is arranged on the edge of each transverse plate (3) close to the first gap, the bulge (3-1) extends to the inner side wall of the supporting body (4), a containing cavity for containing algae is formed in the upper surface of each transverse plate (3), the bulge (3-1) and the inner side wall of the supporting body (4), a plurality of through holes (1-1) are formed in the side wall of the supporting body (4), a feeding pipe (5) is arranged on the inner side wall of the upper portion of the supporting body (4), a second gap is formed between the bottom end of each feeding pipe (5) and the transverse plate (3) located at the uppermost layer, the upper end of the supporting body (4) is provided with an opening, and the lower end (4) of the supporting body (4) is provided with a collecting pool;

the support body (4) comprises a plurality of support layers for supporting a plurality of transverse plates (3) respectively, each support layer comprises a plurality of upright posts (4-1) which are vertically arranged, a connecting post (4-3) connected between the bottoms of the two upright posts (4-1) and a wallboard (4-2) arranged between the two adjacent upright posts (4-1), toughened glass (1) is arranged on the wallboard (4-2), and a plurality of through holes (1-1) are all positioned on the toughened glass (1);

the through hole (1-1) is a conical hole, and the aperture of the conical hole gradually increases from the inner side wall of the toughened glass (1) to the outer side wall of the toughened glass (1);

the solar water heater is characterized in that a heating mechanism is arranged in the supporting body (4) and comprises a water heating pipe (7) and a plurality of solar heat collecting plates (9) arranged along the height direction of the fixing rod (2), the water heating pipe (7) is arranged on the bottom surface of the transverse plate (3), the solar heat collecting plates (9) are arranged on the fixing rod (2), and the solar heat collecting plates (9) are arranged at the bottom of the water heating pipe (7).

2. A biological haze control workstation according to claim 1, wherein: the shape enclosed by the upright posts (4-1) is round or regular polygon, the upright posts (4-1), the connecting posts (4-3) and the wall plates (4-2) are reinforced concrete pouring bodies, and the number of the upright posts (4-1) is at least six.

3. A biological haze control workstation according to claim 1 or 2, characterized in that: the thickness of the toughened glass (1) is 0.01 m-0.2 m.

4. A biological haze control workstation according to claim 1 or 2, characterized in that: the value range of the small aperture of the conical hole is 0.01 m-0.05 m, the value range of the large aperture of the conical hole is 0.05 m-0.2 m, and the distance between two adjacent conical holes is 0.05 m-0.35 m.

5. A biological haze control workstation according to claim 1, wherein: the center is vertically provided with dead lever (2) in support body (4), the lower extreme of dead lever (2) is installed in the ground of waiting to administer regional (10), dead lever (2) run through a plurality of diaphragm (3).

6. A biological haze control workstation according to claim 1, wherein: the water heating pipe (7) is provided with a switch (7-1).

7. A biological haze control workstation according to claim 1, wherein: the bottom of the collecting tank (6) is provided with a supporting rod (8).

8. A biological haze control workstation according to claim 1, wherein: the vertical distance between two adjacent transverse plates (3) is 2.0 m-5.0 m.

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