CN215272425U - Mite-killing and dust-collecting robot - Google Patents
Mite-killing and dust-collecting robot Download PDFInfo
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- CN215272425U CN215272425U CN202121758408.7U CN202121758408U CN215272425U CN 215272425 U CN215272425 U CN 215272425U CN 202121758408 U CN202121758408 U CN 202121758408U CN 215272425 U CN215272425 U CN 215272425U
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Abstract
The application discloses a mite-killing dust-collecting robot, which comprises a robot main body, a driving mechanism for propelling the robot main body to move, an ultraviolet lamp assembly and a dust-collecting assembly, wherein the ultraviolet lamp assembly and the dust-collecting assembly are arranged on the robot main body; the ultraviolet lamp assembly includes an ultraviolet lamp configured to emit ultraviolet rays and pass through the ultraviolet transmissive portion; the dust collection assembly comprises a suction nozzle arranged on the bottom surface, a dust collection box arranged on the shell and a suction motor, the suction nozzle comprises a dust-containing air inlet facing the surface to be cleaned, a clean air outlet used for discharging clean air generated by the suction motor to the outside of the shell is arranged on the bottom surface, and the clean air outlet is close to the dust-containing air inlet. The dust-collecting cleaning equipment has the advantages that the clean air outlet is arranged near the dust-containing airflow inlet, so that the influence of low power and low suction of the dust-collecting cleaning equipment is reduced; motor-driven wind forms the wind-force circulation, and cleaning efficiency and clean effect obtain promoting.
Description
Technical Field
The application relates to the technical field of surface cleaning equipment, in particular to a mite removing and dust collecting robot.
Background
In order to meet the market requirement of wireless cleaning radius, various wireless cleaning devices appear in the market, and the wireless cleaning devices are more and more popular with people due to small size and wireless work and increased operation comfort; however, most of wireless dust collection cleaning devices are low-power and low-suction devices, and the problems of low dust collection efficiency and poor dust collection effect are often caused in the case of the wireless dust collection cleaning devices.
Disclosure of Invention
The utility model provides a low, the not good problem of dust removal effect of dust collection efficiency among the prior art is solved to the aim at of this application.
In order to achieve the purpose, the technical scheme is as follows: a mite-killing dust-collecting robot, comprising:
the robot comprises a robot main body and a cleaning device, wherein the robot main body comprises a shell, the shell is provided with a bottom surface facing a surface to be cleaned, and at least one ultraviolet transmission part is arranged on the bottom surface;
a drive mechanism for propelling movement of the robot main body;
an ultraviolet lamp assembly comprising at least one ultraviolet lamp disposed within the housing, the at least one ultraviolet lamp configured to emit ultraviolet light and pass through the at least one ultraviolet transmissive portion; and the number of the first and second groups,
the dust collection assembly comprises a suction nozzle, a dust collection box, a suction motor and a clean air outlet which are arranged on the shell and are sequentially communicated with each other in a fluid mode, wherein the suction nozzle comprises a dust-containing air inlet facing to a surface to be cleaned;
wherein the clean air outlet is distributed on the bottom surface and faces the dust-containing air inlet, so that the clean air discharged from the clean air outlet can blow up dust around the dust-containing air inlet.
In the above technical solution, it is further preferable that the clean air outlet is configured to blow out the clean air in a blowing direction forming an angle of 30 to 70 degrees with the bottom surface.
In the above technical solution, it is further preferable that at least a portion of the ground suction nozzle extends downward relative to the bottom surface, and the dust-containing airflow inlet is located at a lower side of the bottom surface.
In the above technical solution, it is further preferable that the suction nozzle includes a first wind blocking wall near one side of the clean air outlet and a second wind blocking wall opposite to the first wind blocking wall in front and rear directions, and a lower end of the first wind blocking wall and a lower end of the second wind blocking wall define the dust-containing airflow inlet.
In the above aspect, it is further preferable that a lower end portion of the first wind blocking wall is located above a lower end portion of the second wind blocking wall.
In the above technical solution, it is further preferable that the first wind shielding wall and the second wind shielding wall are both arc-shaped wall surfaces, and a curvature of the first wind shielding wall is smaller than a curvature of the second wind shielding wall.
In the above technical solution, it is further preferable that the bottom surface is provided with an air outlet grid, and the clean air outlet is formed at the air outlet grid.
In the above technical solution, it is further preferable that the suction motor is located between the clean air outlet and the ground suction nozzle, and the suction inlet of the suction motor is configured to be capable of sucking air flow from top to bottom.
In the above technical solution, it is further preferable that the at least one ultraviolet-transmittable portion is located on a front side of the suction nozzle.
In the above technical solution, it is further preferable that the driving mechanism includes a pair of driving wheels that can be driven to rotate and at least one universal wheel that can rotate with the movement of the robot main body, and the ground suction nozzle is located at a front side of the pair of driving wheels.
Compared with the prior art, the invention has the following beneficial effects:
the dust-collecting cleaning equipment has the advantages that the clean air outlet is arranged near the dust-containing air inlet, so that the dust around the dust-containing air inlet is blown up by the clean air discharged from the clean air outlet, the dust is more easily sucked into the robot body under the action of wind power, and the influence of low power and low suction of the dust-collecting cleaning equipment is reduced; wind driven by the motor surrounds the motor as the center and forms wind power circulation, and the cleaning efficiency and the cleaning effect are improved.
Drawings
FIG. 1 is a front view of the present application;
FIG. 2 is a schematic cross-sectional view A-A of FIG. 1;
FIG. 3 is a left side view of FIG. 1;
fig. 4 is a bottom view of fig. 1.
Detailed Description
To explain the technical content, the structural features, the achieved objects and the functions of the application in detail, the technical solutions in the embodiments of the application will be described below with reference to the drawings in the embodiments of the application, and it is obvious that the described embodiments are only a part of the embodiments of the application, and not all embodiments. In the following description, for purposes of explanation, numerous specific details are set forth in order to provide a detailed description of various exemplary embodiments or implementations of the invention. However, various exemplary embodiments may be practiced without these specific details or with one or more equivalent arrangements. Moreover, the various exemplary embodiments may be different, but are not necessarily exclusive. For example, the particular shapes, configurations and characteristics of exemplary embodiment strips may be used or implemented in another exemplary embodiment without departing from the inventive concept.
In the following, the terms "first", "second", etc. are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first," "second," etc. may explicitly or implicitly include one or more of that feature. In the description of the present application, "a plurality" means two or more unless otherwise specified.
Further, spatially relative terms such as "under … …," "below," "over … …," "up," "upper," "left," "right," "side" (e.g., as in "side wall"), and the like, in this application, thus describe one element's relationship to another (other) element as illustrated in the figures. Spatially relative terms are intended to encompass different orientations of the device in use, operation, and/or manufacture in addition to the orientation depicted in the figures.
In this application, unless expressly stated or limited otherwise, the term "coupled" is to be construed broadly, e.g., "coupled" may be a fixed connection, a removable connection, or an integral part; may be directly connected or indirectly connected through an intermediate.
The application remove mite dust absorption robot for wireless dust absorption cleaning equipment, greatly promoted this application and removed mite dust absorption robot's intelligence and convenience, but because wireless dust absorption cleaning equipment is the equipment of low-power low suction mostly, so have that suction is little, dust collection efficiency is low, the not good influence of dust removal effect. The mite-killing dust-collecting robot has higher dust-collecting efficiency while ensuring that the robot can work wirelessly.
As shown in fig. 1 to 4, the mite removing and dust collecting robot comprises a robot main body 1, a driving mechanism 2, an ultraviolet lamp assembly 4 and a dust collecting assembly 3; the ultraviolet lamp assembly 4 and the dust suction assembly 3 are disposed in the robot main body 1.
As shown in fig. 1, 2 and 4, the robot main body 1 includes a housing 11, the housing 11 has a bottom surface 111 facing a surface to be cleaned, the bottom surface 111 is provided with at least one ultraviolet transmissive portion 112 for transmitting ultraviolet rays by the ultraviolet lamp assembly 4 and an air outlet grid 113 for guiding a discharge direction of clean air; a charging socket 114 for charging is also provided on the outer side wall of the housing 11. The mite-killing dust-collecting robot further comprises a rechargeable battery pack, wherein the battery pack is electrically connected with the charging socket 114 and is connected with a power supply through the charging socket 114 to supplement charging; the rechargeable battery pack supplies power to energy consumption components in the mite removing and dust collecting robot, the purpose of wireless work is achieved, and cleaning efficiency is improved.
The driving mechanism 2 is used for promoting the movement of the robot main body 1, the driving mechanism 2 comprises a pair of driving wheels 21 and at least one universal wheel 22, the pair of driving wheels 21 rotationally advance through the driving of a driving motor and drive the robot main body 1 to advance; the universal wheels 22 are arranged to rotate with the movement of the robot main body 1, and in the present embodiment, the drive mechanism 2 has a pair of universal wheels 22, the track width of the pair of universal wheels 22 is smaller than the track width of the pair of drive wheels 21, and the pair of universal wheels 22 is provided on the front side of the pair of drive wheels 21.
The ultraviolet lamp assembly 4 includes an ultraviolet lamp 41 disposed on the housing 11, the ultraviolet lamp 41 is disposed at the ultraviolet transmissive portion 112, and the ultraviolet lamp 41 emits ultraviolet light to be projected to a surface to be cleaned below the housing 11 through the ultraviolet transmissive portion 112.
As shown in fig. 2, the dust suction assembly 3 includes a suction motor 31 mounted on the housing 11, a dust collection box 32 provided on the housing 11, a suction nozzle 33 provided on the bottom surface 111, and a clean air outlet 34; the suction nozzle 33 communicates with the dust box 32, and the dust-containing air flow is introduced into the dust box 32 through the suction nozzle 33.
The suction motor 31 is disposed between the suction nozzle 33 and the clean air outlet 34, and the suction motor 31 is configured to be capable of sucking an air flow through the upper suction opening 311 and discharging the air flow from the lower portion.
The dust collecting box 32 is a box body with an opening 320, the dust collecting box 32 comprises a filter 321 for covering the opening 320, and the filter 321 is detachably arranged on the dust collecting box 32; the filter 321 blocks dust in the dust-containing air flow in the dust box 32, and clean air overflows from the filter 321 and is sucked from the suction opening 311 by the suction motor 31.
As shown in fig. 1, 2, and 4, the suction nozzle 33 is positioned in front of the pair of driving wheels 21, and a part of the suction nozzle 33 protrudes downward with respect to the bottom surface 111. The suction nozzle 33 includes a dust-laden air inflow port 330 facing the surface to be cleaned, a first wind blocking wall 331 adjacent to the clean air outlet 34, and a second wind blocking wall 332 disposed in front of and behind the first wind blocking wall 331, a lower end portion of the first wind blocking wall 331 and a lower end portion of the second wind blocking wall 332 defining the dust-laden air inflow port 330, the dust-laden air inflow port 330 being inclined toward the clean air outlet 34 due to the lower end portion of the first wind blocking wall 331 being located on an upper side of the lower end portion of the second wind blocking wall 332. The first wind blocking wall 331 and the second wind blocking wall 332 are both arc-shaped wall surfaces, and the curvature of the first wind blocking wall 331 is smaller than that of the second wind blocking wall 332.
The clean air outlet 34 is formed at the air outlet grid 113 of the bottom surface 111 and is close to the dust-containing airflow inlet 330; the clean air outlet 34 is configured to blow out clean air discharged from the suction motor 31 out of the housing 11 in a blowing direction forming an included angle of 30-70 degrees with the bottom surface 111; the clean air outlet 34 guides the clean air discharged from the suction motor 31 to the area to be cleaned, and dust around the suction nozzle 33 is blown by the clean air and moved to the vicinity of the dust-laden air inlet 330, so that the dust is more easily sucked from the suction nozzle 33 into the dust box 32 by the wind even if the power and suction force of the suction motor 31 are low.
The dust-containing airflow inlet 330, the dust box 32, the suction motor 31, and the clean air outlet 34 are sequentially in fluid communication to form an airflow path.
In the present embodiment, the ultraviolet-transmittable part 112 is located at the front side of the suction nozzle 33, so that the mite removing and dust collecting robot can timely suck mites killed by ultraviolet rays into the dust collecting box 32.
When the mite-killing and dust-collecting robot works, the driving motor drives the pair of driving wheels 21 to rotate, and the driving wheels 21 drive the robot body 1 to move; the ultraviolet lamp assembly 4 and the dust collection assembly 3 are started, and the ultraviolet lamp assembly 4 emits sterilization ultraviolet rays to the surface to be cleaned on the lower side of the robot body 1 from the ultraviolet transmission part 112; the suction motor 31 is started, clean air generated by rotation of the suction motor 31 is blown out from the clean air outlet 34 at the air outlet grid 113 to be cleaned, dust on the surface to be cleaned and mite bodies killed after being irradiated by ultraviolet rays are blown to the position near the dust-containing air inlet 330, the dust and the mite bodies are introduced into the dust collection box 32 from the dust-containing air inlet 330 under the suction action of the suction motor 31, the dust and the mite bodies are left in the dust collection box 32 under the filtration of the filter 321, the clean air is sucked in by the suction motor 31 and blown out from the clean air outlet 34 again, and the surface to be cleaned is cleaned through wind circulation of the dust collection assembly 3 until the cleaning is finished.
The dust-collecting cleaning equipment has the advantages that the clean air outlet 34 is arranged near the dust-containing air inlet 330, so that the dust around the dust-containing air inlet 330 is blown up by the clean air discharged from the clean air outlet 34, the dust is more easily sucked into the robot main body 1 under the action of wind power, and the influence of low power and low suction force of the dust-collecting cleaning equipment is reduced; wind driven by the motor surrounds the motor as the center and forms wind power circulation, and the cleaning efficiency and the cleaning effect are improved.
The foregoing shows and describes the general principles, essential features, and advantages of the application. It will be understood by those skilled in the art that the present application is not limited to the embodiments described above, which are merely illustrative of the principles of the application, but that various changes and modifications may be made without departing from the spirit and scope of the application, which is defined by the appended claims, the description, and equivalents thereof.
Claims (10)
1. A mite-killing and dust-collecting robot is characterized by comprising:
the robot comprises a robot main body (1) and a cleaning device, wherein the robot main body comprises a shell (11), the shell (11) is provided with a bottom surface (111) facing a surface to be cleaned, and at least one ultraviolet transmission part (112) is arranged on the bottom surface (111);
a drive mechanism (2) for propelling movement of the robot main body (1);
an ultraviolet lamp assembly (4) comprising at least one ultraviolet lamp (41) disposed within the housing (11), the at least one ultraviolet lamp (41) configured to emit ultraviolet light and pass through the at least one ultraviolet transmissive portion (112); and the number of the first and second groups,
the dust collection assembly (3) comprises a suction nozzle (33), a dust collection box (32), a suction motor (31) and a clean air outlet (34) which are arranged on the shell (11) and are sequentially communicated with each other in a fluid mode, wherein the suction nozzle (33) comprises a dust-containing air inlet (330) facing to a surface to be cleaned;
wherein the clean air outlet (34) is distributed on the bottom surface (111) and faces the dust-containing air inlet (330), so that the clean air discharged from the clean air outlet (34) can blow up dust around the dust-containing air inlet (330).
2. The mite-killing and dust-collecting robot according to claim 1, wherein the clean air outlet (34) is configured to blow out the clean air in a blowing direction at an angle of 30-70 degrees with respect to the bottom surface (111).
3. A mite-killing and dust-collecting robot as claimed in claim 1, wherein said suction nozzle (33) is at least partially extended downward with respect to said bottom surface (111), and said dust-containing air inlet (330) is located at a lower side of said bottom surface (111).
4. A mite-killing dust-collecting robot as claimed in claim 3, wherein said suction nozzle (33) comprises a first wind shielding wall (331) near one side of said clean air outlet (34) and a second wind shielding wall (332) opposite to the front and rear of said first wind shielding wall (331), and the lower end of said first wind shielding wall (331) and the lower end of said second wind shielding wall (332) define said dust-containing air flow inlet (330).
5. The mite removing and dust collecting robot according to claim 4, wherein a lower end portion of the first wind blocking wall (331) is located at an upper side of a lower end portion of the second wind blocking wall (332).
6. The mite-killing and dust-collecting robot as claimed in claim 4, wherein the first wind shielding wall (331) and the second wind shielding wall (332) are arc-shaped wall surfaces, and the curvature of the first wind shielding wall (331) is smaller than that of the second wind shielding wall (332).
7. The mite-killing and dust-collecting robot as claimed in claim 1, wherein an air outlet grill (113) is provided on the bottom surface (111), and the clean air outlet (34) is formed at the air outlet grill (113).
8. A mite-killing and dust-collecting robot as claimed in claim 1, wherein said suction motor (31) is located between said clean air outlet (34) and said suction nozzle (33), and said suction opening (311) of said suction motor (31) is configured to suck an air flow from top to bottom.
9. A mite-killing dust-collecting robot as claimed in claim 1, wherein said at least one ultraviolet-transmissive portion (112) is located at a front side of said suction nozzle (33).
10. A mite-killing and dust-collecting robot as claimed in claim 1, wherein said driving mechanism (2) comprises a pair of driving wheels (21) which can be driven to rotate and at least one universal wheel (22) which can rotate along with the movement of said robot main body (1), and said suction nozzle (33) is positioned in front of said pair of driving wheels (21).
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
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CN202121758408.7U CN215272425U (en) | 2021-07-30 | 2021-07-30 | Mite-killing and dust-collecting robot |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
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CN202121758408.7U CN215272425U (en) | 2021-07-30 | 2021-07-30 | Mite-killing and dust-collecting robot |
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CN215272425U true CN215272425U (en) | 2021-12-24 |
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CN202121758408.7U Active CN215272425U (en) | 2021-07-30 | 2021-07-30 | Mite-killing and dust-collecting robot |
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- 2021-07-30 CN CN202121758408.7U patent/CN215272425U/en active Active
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