Search

CN-224218353-U - Snow removing robot for photovoltaic panel

CN224218353UCN 224218353 UCN224218353 UCN 224218353UCN-224218353-U

Abstract

The utility model relates to a snow removing robot for a photovoltaic panel. The snow removing robot comprises a frame, wherein two sides of the frame are provided with a power device, the power device is provided with travelling wheels, the frame can walk on a photovoltaic frame through the travelling wheels, the left side and the right side of the two power devices are also provided with fixing frames, a bucket is arranged between the two fixing frames on the left side, the front of the bucket is provided with an auger, the auger is not in contact with the ground, a sweeping roller is arranged between the two fixing frames on the right side, the auger is driven to rotate by an auger motor, and the sweeping roller is driven to rotate by a sweeping roller motor. When the photovoltaic device is used, the whole machine is driven to move through the movement of the frame, the auger motor drives the auger to rotate, thick snow is crushed, most of the snow is scooped up by the bucket, and finally the photovoltaic panel is cleaned through the sweeping roller.

Inventors

  • LU JIAN
  • HE DONGTING
  • ZHONG YONG
  • CHEN JUNJIE
  • WU SHENGHUA
  • CHEN QIANQIAN

Assignees

  • 浙江晴天太阳能科技股份有限公司

Dates

Publication Date
20260508
Application Date
20250108

Claims (4)

  1. 1. The snow removing robot for the photovoltaic panel comprises a frame, wherein two power devices are arranged on two sides of the frame, travelling wheels are arranged on the power devices, the frame can walk on the photovoltaic frame through the travelling wheels, and the snow removing robot is characterized in that a fixed frame is further arranged on the left side and the right side of the two power devices, a bucket is arranged between the two fixed frames on the left side, an auger is arranged at the front end of the advancing direction of the bucket, the auger is used for smashing frozen or thick snow on the photovoltaic panel, the auger is not in contact with the surface of the photovoltaic panel, a sweeping roller is arranged between the two fixed frames on the right side, the sweeping roller is arranged at the rear end of the advancing direction of the bucket and is used for sweeping residual snow on the surface of the photovoltaic panel, the auger is driven to rotate by a sweeping roller motor, one fixed frame on the left side is composed of a transverse plate and an arc plate, an opening of the arc plate is downward, one end of the arc plate is fixed with the transverse plate, the fixed point is fixed, and the other end of the arc plate is fixed with the auger.
  2. 2. The snow removing robot for a photovoltaic panel according to claim 1, wherein the lower end of the cross plate is further provided with rollers.
  3. 3. The snow removing robot as set forth in claim 1 or 2, wherein a third mount is further provided on the frame between the left two mounts.
  4. 4. The snow removing robot as set forth in claim 1, wherein the auger motor is engaged with the auger via four gears, the sweeping roller motor is engaged with the sweeping roller via two gears, and the gears connected with the auger motor and the sweeping roller motor are the largest among the groups.

Description

Snow removing robot for photovoltaic panel Technical Field The utility model belongs to the field of photovoltaics, and particularly relates to a snow removing robot for a photovoltaic panel. Background The photovoltaic panel assembly is a power generation device which can generate direct current when being exposed to sunlight, and because the photovoltaic panel assembly is always outdoors, a robot for cleaning and removing snow is arranged in the field so as not to influence the power generation effect of the photovoltaic panel. However, the existing snow removing robot is complicated in overall structure, the design of a snow removing device is not reasonable enough, a fan type rolling brush type snow removing robot is generally adopted, the problem cannot occur when the snow removing robot is used in areas with small snow amount, and if the snow removing robot is used in places with large snow amount and cold weather, the use effect of the snow is limited. Disclosure of utility model In view of the defects of the existing photovoltaic plate snow removing robot, the technical problem to be solved by the utility model is to provide the snow removing robot which is used for removing snow on the photovoltaic plate and has stronger snow removing power and can remove ice and snow. According to the technical measure, the snow removing robot for the photovoltaic panel comprises a frame, wherein two sides of the frame are respectively provided with a power device, travelling wheels are arranged on the power devices, the frame can walk on the photovoltaic frame through the travelling wheels, fixing frames are further arranged on the left side and the right side of the two power devices, a bucket is arranged between the two fixing frames on the left side, the front of the bucket is provided with an auger, the auger is not in contact with the ground, a sweeping roller is arranged between the two fixing frames on the right side, the auger is driven to rotate by an auger motor, and the sweeping roller is driven to rotate by the sweeping roller motor. The snow removing robot of this photovoltaic board carries out the hank snow earlier through the auger, and thick or frozen snow homoenergetic like this is smashed, is shoveling snow through the scraper bowl, sweeps the snow by sweeping the roller at last, and the cold place of weather of design of being convenient for uses like this. Further, one of the fixing frames on the left side consists of a transverse plate and an arc-shaped plate, the opening of the arc-shaped plate faces downwards, one end of the arc-shaped plate is fixed with the transverse plate, the bucket is fixed at a fixed point, and the other end of the arc-shaped plate is fixed with the auger. Further, the lower end of the transverse plate is also provided with a roller. Further, a third fixing frame is arranged on the frame between the two fixing frames at the left side. Further, the auger motor is in meshed connection with the auger through four gears, the sweeping roller motor is in meshed connection with the sweeping roller through two gears, and the gears connected with the auger motor and the sweeping roller motor are the largest among the groups. Compared with the prior art, the snow removing device has the advantages that the snow removing capability is stronger through the cooperation of the auger, the bucket and the sweeping roller, and the snow removing device is suitable for snow removing work of the photovoltaic panel in cold places. Drawings The accompanying drawings, which are included to provide a further understanding of the disclosure and are incorporated in and constitute a part of this specification, illustrate exemplary embodiments of the disclosure and together with the description serve to explain the principles of the disclosure. In the drawings: Fig. 1 is a schematic structural view of a snow removing robot for a photovoltaic panel according to the present utility model. Fig. 2 is a schematic diagram of a transmission structure of the auger motor and the sweeping roller motor. The reference numerals in the drawings specifically are: 1. A frame; 2, a power device, 3, a travelling wheel, 4, a fixing frame, 5, a bucket, 6, an auger, 7, a sweeping roller, 8, an auger motor, 9, a sweeping roller motor, 10, a transverse plate, 11, an arc plate, 12, a roller, 13 and a gear. Detailed Description For the purposes of this description, the present disclosure may use, for example, "under" and "under". "lower", "above", "higher" and "sides (e.g., spatially relative terms, such as" in "sidewalls" and the like, may be used for ease of description to describe one element's relationship to another (other) element(s) as illustrated in the figures. In addition to the orientations depicted in the figures, spatially relative terms are intended to encompass different orientations of the device in use, operation, and/or manufacture, such as a component described as "under" or "under" other components o