Search

CN-224221003-U - Air purification equipment is used in production of perovskite photovoltaic module

CN224221003UCN 224221003 UCN224221003 UCN 224221003UCN-224221003-U

Abstract

The utility model relates to air purification equipment for perovskite photovoltaic module production, which is applied to the technical field of air purification equipment, and is characterized in that waste generated in perovskite photovoltaic module production enters a particle removal bin through an air inlet, particles in air are filtered layer by layer through a plurality of layers of filter screens in the particle removal bin, the filtered air enters an organic matter purification bin through an air pipe, the air is filtered again through active carbon, organic pollutants in the air are purified, the purified air enters a water vapor removal bin through a pipeline again, and because a low-temperature condensate is filled in a condensing pipe, when moist air passes through, the water vapor is condensed into water drops on the surface of the condensing pipe and falls into a water accumulation plate to be collected, a suction pump is started to discharge water in the water accumulation plate, and the effects of dehumidifying the air are realized.

Inventors

  • LI CHANGYU
  • SONG YADING
  • YANG YIZHUANG
  • Weng Zijun
  • Lei Mingkang

Assignees

  • 中科钙钛(苏州)科技有限公司

Dates

Publication Date
20260512
Application Date
20250606

Claims (7)

  1. 1. The air purification equipment for perovskite photovoltaic module production comprises purification equipment (1) with an air inlet and an air outlet, and is characterized in that a particle removal bin (2), an organic matter purification bin (3) and a water vapor removal bin (4) are arranged in the purification equipment (1), the air inlet is communicated with the particle removal bin (2), the air outlet is communicated with the water vapor removal bin (4), the particle removal bin (2), the organic matter purification bin (3) and the water vapor removal bin (4) are communicated through an air pipe, a plurality of filter screens (5) are fixedly connected in the particle removal bin (2) at equal intervals, the mesh density of the filter screens (5) from left to right is sequentially reduced from less to more, a plate frame is arranged on the inner wall of the organic matter purification bin (3), activated carbon (6) is filled in the plate frame, a plurality of snakelike condensation pipes (7) are arranged in the water vapor removal bin (4) at equal intervals, low-temperature condensate is filled in the condensation pipes (7), a clamp (24) is clamped at the top ends of the condensation pipes (7) at equal intervals, a plurality of the clamp (24) are fixedly connected with a water drain outlet (8) through a mounting plate (23) and a water drain port (8) which is arranged on the inner side of the water purification equipment (1), the side of the water outlet (15) is provided with a suction pump (21), the input end of the suction pump (21) is connected with the water outlet (15) through a conveying pipe (22), and the output end of the suction pump is connected with a sewage recovery tank arranged on one side of the purifying equipment (1) through the conveying pipe (22).
  2. 2. The air purification device for producing the perovskite photovoltaic module according to claim 1, wherein the surface of the condensation tube (7) is sleeved with the scraping brush (13), and the scraping brush (13) is made of nylon which is made of non-water-absorbing materials.
  3. 3. The air purification device for perovskite photovoltaic module production according to claim 2, wherein two adjacent scraping brushes (13) are connected through a connecting plate (16), a group of self-rebound scroll (19) and a rotating shaft (14) are respectively and rotatably connected to the upper end and the lower end of a condensing tube (7) on the inner wall of the water vapor removal bin (4), and a second limiting plate (20) and a first limiting plate (17) corresponding to the connecting plate (16) are respectively sleeved on the surfaces of the self-rebound scroll (19) and the rotating shaft (14).
  4. 4. The air purification device for perovskite photovoltaic module production of claim 3, wherein the surface of the self-rebound reel (19) is positioned in the second limiting plate (20) and is wound with a first pull rope (18), one end of the first pull rope (18), which is far away from the self-rebound reel (19), is fixedly connected with the top end of the connecting plate (16) positioned right below, the surface of the rotating shaft (14) is positioned in the first limiting plate (17) and is wound with a second pull rope (25), and one end of the second pull rope (25), which is far away from the rotating shaft (14), is fixedly connected with the bottom end of the connecting plate (16) positioned right above.
  5. 5. The air purification device for perovskite photovoltaic module production according to claim 4, wherein the purification device (1) is fixedly connected with a supporting plate (9) at the side end, a servo motor (10) is fixedly connected to the supporting plate (9), and the output end of the servo motor (10) is connected with one of the rotating shafts (14).
  6. 6. The air purification device for producing perovskite photovoltaic modules according to claim 5, wherein the surfaces of the two rotating shafts (14) positioned outside the purification device (1) are respectively sleeved with a belt pulley (11), and the two belt pulleys (11) are connected through a belt (12).
  7. 7. The air purification device for perovskite photovoltaic module production as claimed in claim 5, wherein the purification device (1) is fixedly connected with a controller for controlling the servo motor (10) and the suction pump (21).

Description

Air purification equipment is used in production of perovskite photovoltaic module Technical Field The utility model relates to air purification equipment, in particular to air purification equipment for perovskite photovoltaic module production, which is applied to the technical field of air purification equipment. Background The perovskite photovoltaic module becomes a research hot spot and development direction in the field of solar photovoltaic by the efficient photoelectric conversion efficiency and the low-cost preparation process. However, perovskite materials have extremely severe requirements on production environment, and impurities such as particulate matters, organic pollutants, water vapor, corrosive gases and the like in the air can pollute the perovskite film in the preparation process of the component, cause film defects, and further influence the photoelectric performance and stability of the component. The specification of Chinese patent CN119836189A discloses a method and a device for treating particulate matters in a perovskite photovoltaic module and the photovoltaic module, and the method and the device can reduce the probability of the particulate matters affecting the encapsulation effect in a semi-finished product of the perovskite photovoltaic module to be detected, thereby improving the encapsulation effect of the perovskite photovoltaic module, and further improving the stability and the service life of the perovskite photovoltaic module. Although the traditional filtering type air purifying equipment can remove part of particles, the purifying effect on particles with small particle size, organic pollutants, water vapor and the like is poor. Disclosure of utility model Aiming at the prior art, the utility model aims to solve the technical problems that the traditional filtering type air purifying equipment can remove partial particulate matters, but has poor purifying effect on the particles with small particle size, organic pollutants, water vapor and the like. In order to solve the problems, the utility model provides air purification equipment for perovskite photovoltaic module production, which comprises purification equipment with an air inlet and an air outlet, wherein a particle removal bin, an organic matter purification bin and a water vapor removal bin are arranged in the purification equipment, the air inlet is communicated with the particle removal bin, the air outlet is communicated with the water vapor removal bin, the particle removal bin, the organic matter purification bin and the water vapor removal bin are communicated through an air pipe, a plurality of filter screens are fixedly connected in the particle removal bin at equal intervals, the mesh density of the filter screens from left to right is sequentially reduced from the bottom to the top, a plate frame is arranged on the inner wall of the organic matter purification bin, activated carbon is filled in the plate frame, a plurality of snake-shaped condensing pipes are equidistantly arranged in the water vapor removal bin, low-temperature condensate is filled in the condensing pipes, a clamp is fixedly connected with the top wall of the water vapor removal bin at equal intervals through a mounting plate, a water accumulation disc is arranged under the condensing pipes in the purification equipment, a water outlet extending to the outside the purification equipment is arranged at the side end of the water accumulation disc, a water outlet is arranged at the side of the water outlet, the water outlet is connected with a water outlet through a conveying pipe, and the input end of the water outlet is connected with the water outlet through the conveying pipe, and the sewage outlet is arranged at one side of the purification equipment. In the air purification equipment, the particle removal bin, the organic matter purification bin and the water vapor removal bin are arranged, so that the purification effect on tiny particle size particles, organic pollutants, water vapor and the like in waste generated in the production of the perovskite photovoltaic module can be achieved. As a further improvement of the application, the surface of the condensing tube is sleeved with a scraping brush, and the scraping brush is made of nylon which is made of non-water-absorbing materials. As a further improvement of the application, two adjacent scraping brushes are connected through the connecting plate, the inner wall of the vapor removal bin is respectively and rotatably connected with a group of self-rebound scroll and a rotating shaft at the upper end and the lower end of the condensing tube, and the surfaces of the self-rebound scroll and the rotating shaft are respectively sleeved with a second limiting plate and a first limiting plate which correspond to the connecting plate. As a further improvement of the application, a first pull rope is wound on the surface of the self-rebound scroll in the second limiting plate, one