CN211375427U - Floor sweeping robot - Google Patents

Abstract

The utility model provides a robot of sweeping floor, the robot of sweeping floor includes detection module and motion module, and detection module movable mounting is in the body of the robot of sweeping floor, and the motion module is used for controlling detection module and outwards stretches out for the body for detection module movably sets up in the body, acquires information in order to sweep floor the work planning of robot. The utility model discloses well detection module can outwards stretch out for the body, reduces and detects the blind area to detect the bigger whole environmental information of scope, plan the complete route that cleans, improve and clean efficiency.

Description

Floor sweeping robot

Technical Field

The utility model relates to a robot field of sweeping the floor especially relates to a robot of sweeping the floor.

Background

A floor sweeping robot is an intelligent household appliance, and automatically finishes the floor cleaning work indoors by means of certain artificial intelligence. With the progress of the times, the sweeping robot appears in families and households successively, plays an important role in daily life of people, and greatly improves the life quality of people.

Generally, the floor cleaning machine adopts a brushing and vacuum mode, and firstly absorbs the impurities on the floor into the garbage storage box, so that the function of cleaning the floor is achieved. Generally, a robot that performs cleaning, dust collection and floor wiping is also collectively called a floor sweeping robot.

The detection module of the existing sweeping robot is basically fixedly arranged on the side wall of the sweeping robot, and the detection visual field is changed by the rotation of the sweeping robot; has the following disadvantages: firstly, it is fixed to detect the field of vision, and it is big to detect the blind area, is difficult to acquire indoor whole environmental information, cleans route planning incompletely, secondly is difficult to acquire the peripheral local environmental information of robot of sweeping the floor in real time, bumps easily.

SUMMERY OF THE UTILITY MODEL

To the above defect, the utility model aims to provide a robot of sweeping floor makes detection module can enlarge the detection field of vision, reduces the detection blind area, improves and cleans efficiency to, can real-time detection robot's all ring edge borders of sweeping floor, it is especially right the peripheral barrier of robot of sweeping floor accomplishes accurate real-time detection.

To achieve the purpose, the utility model adopts the following technical proposal: the utility model provides a robot of sweeping floor, includes detection module and motion module, detection module movable mounting in robot of sweeping floor's body, the motion module is used for control detection module for the body is outwards stretched out, makes detection module telescopically activity set up in the body.

Further, the detection module is extended outwards or retracted back relative to the top of the body through the movement module.

Further, the motion module is located the inside of robot of sweeping the floor, the motion module include for the flexible subassembly of body activity, detection module install in flexible subassembly, flexible subassembly's flexible direction with the contained angle of the perpendicular axis of robot of sweeping the floor is phi, and wherein 0 is not less than phi and is not more than 60.

Further, the motion module still includes the swing subassembly, the swing subassembly includes base and swing driver, flexible subassembly is installed the base, the swing driver sets up the below of base, the swing driver with be equipped with the driving medium between the base, the swing driver passes through the driving medium swing the base, and then change flexible subassembly's flexible direction makes detection module's flexible direction with the robot of sweeping the floor the contained angle phi of perpendicular axis is changeable.

Further, flexible subassembly includes movable part and drive division, the movable part includes flexible post, the drive division includes electric power drive ware, detection module sets up flexible post, be equipped with the transmission fitting piece between flexible post and the electric power drive ware, electric power drive ware passes through the drive fitting piece drive flexible post is stretched out or is rolled back.

Further, the transmission fitting piece comprises a driving gear and a rack which are matched with each other, the rack is vertically and fixedly arranged on the bottom end face of the telescopic column, and the driving gear is arranged on a driving shaft of the electric power driver.

Furthermore, the detection module is provided with a rotation driver, and the rotation shaft of the rotation driver is arranged on the axis of the detection module in the telescopic movement direction, so that the detection module rotates by taking the axis of the telescopic movement direction as a central line to detect the conditions in all directions.

The utility model provides a robot of sweeping floor and method that detection control cleaned thereof according to above-mentioned content, detection module passes through motion module install in the robot of sweeping floor's body, motion module is used for control detection module for the body is outwards stretched out, makes detection module telescopically activity set up in the body.

Therefore, the detection module can extend out relative to the body, the detection visual field is enlarged, and the detection blind area is reduced, so that the overall environmental information with a larger detection range is detected, a complete cleaning route is planned, and the cleaning efficiency is improved.

The robot of sweeping the floor is in the detection that cleans in-process continuously on a large scale, real-time detection the robot's of sweeping the floor all ring edge borders, especially right the peripheral barrier of robot of sweeping the floor accomplishes accurate real-time detection, thereby makes the robot of sweeping the floor avoids meaningless collision, avoids stretching out detection module's damage.

When detecting module detects out certain high obstacle that exists in the traffic direction, motion module control detecting module past the robot indentation of sweeping the floor corresponds the height, reduces detecting module's height is convenient for the robot of sweeping the floor passes through the obstacle to the messenger robot of sweeping the floor gets into low space, cleans.

Drawings

FIG. 1 is a schematic structural diagram of one embodiment of the present invention;

fig. 2 is a schematic structural diagram of the telescopic assembly and the detection module according to an embodiment of the present invention, wherein β is an up-down direction detection angle that the detection module can detect in front of the detection end;

fig. 3 is a schematic structural diagram of the telescopic assembly and the detection module according to an embodiment of the present invention, wherein β is an up-down direction detection angle that the detection module can detect in front of the detection end;

fig. 4 is a schematic diagram of a combination of a detection module and a motion module according to an embodiment of the present invention;

fig. 5 is a schematic view of a combination of the detection module and the motion module according to one embodiment of the present invention, where phi is an included angle between a telescopic motion direction of the detection module and a vertical central axis of the sweeping robot.

Wherein: 1. a sweeping robot; 11. a detection module; 12. a motion module; 121. a telescoping assembly; 122. a swing assembly; 31. a telescopic column; 32. a power driver; 33. a lifting platform; 34. an oblique cross section; 35. a connecting rod; 36. a pulley; 41. a base; 42. a swing driver; 43. a transmission member; 431. a driving gear; 432. A driven gear; 44. a transmission fitting member; 441. a drive gear; 442. a rack; 3. perpendicular to the central axis.

Detailed Description

The technical solution of the present invention is further explained by the following embodiments with reference to the accompanying drawings.

As shown in fig. 1 to 5, a sweeping robot includes a detection module 11 and a motion module 12, wherein the detection module 11 is movably installed on a body of the sweeping robot 1, and the motion module 12 is configured to control the detection module 11 to extend outward relative to the body, so that the detection module 11 is telescopically and movably disposed on the body.

Specifically, the detection module 11 may be an infrared detection module, an ultrasonic detection module, a laser detection module, a visual detection module, and the like.

The detection module 11 is used for acquiring external environment information, constructing a map, positioning and detecting obstacles, and in this embodiment, the detection module 11 is movably installed in the body of the floor sweeping robot 1, and the movement module 12 is used for controlling the detection module 11 to extend outwards or return back and reset relative to the body, so that the detection module 11 is movably arranged in the body.

Therefore, the detection module 11 can extend out relative to the body, so that the detection visual field is enlarged, and the detection blind area is reduced, thereby detecting the overall environmental information with a larger detection range, planning a complete cleaning route and improving the cleaning efficiency.

Through the robot 1 of sweeping floor of this embodiment, at the in-process of sweeping detection on a large scale continuously, real-time detection the all ring edge borders of robot 1 of sweeping floor, it is especially right 1 peripheral barrier of robot of sweeping floor accomplishes accurate real-time detection, thereby makes robot 1 of sweeping floor avoids meaningless collision, avoids stretching out detection module 11's damage.

Further, the detection module 11 protrudes outwards relative to the top of the sweeping robot 1 through the motion module 12.

Detection module 11 can for the top, bottom or the lateral wall of robot 1 of sweeping the floor are outwards stretched out, and more preferably, detection module 11 passes through motion module 12 for robot 1's of sweeping the floor top is outwards stretched out, because robot 1's of sweeping the floor top space is big, consequently detection module 11's the space of stretching out is big, and the collision probability is low, and detection module 11's activity need not to consider whether the required uneven factor in ground that cleans exists, and is convenient detection module 11 stretches out, thereby enlarges detection module 11's the detection field of vision, consequently will detection module 11 set up for robot 1's of sweeping the floor top is outwards stretched out.

Further, the motion module 12 is located inside the sweeping robot 1, the motion module 12 includes a telescopic assembly 121 movable relative to the body, and the detection module 11 is installed in the telescopic assembly 121, for example, in a telescopic end face of the telescopic assembly 121, so that the detection module 11 is partially or completely installed inside the sweeping robot 1. Specifically, an included angle between the telescopic direction of the telescopic assembly 121 and the vertical central axis 3 of the sweeping robot 1 is phi, wherein phi is greater than or equal to 0 degree and less than or equal to 60 degrees, as shown in fig. 5, the vertical central axis 3 is a central axis of the sweeping robot 1 in the vertical direction.

The telescopic assembly 121 can be a cylinder telescopic assembly, a hydraulic telescopic assembly or a motor-driven telescopic assembly 121, preferably, the electric-driven telescopic assembly 121 is selected, and the electric-driven telescopic assembly 121 is low in structural cost, high in reliability and relatively simple in fault maintenance. As shown in fig. 2, the electrically driven telescopic assembly 121 includes a movable portion including the telescopic column 31 and a driving portion including an electric driver 32, and the electric driver 32 may be a motor such as a dc motor, an ac motor, a servo motor, or the like. The detection module 11 is arranged on the telescopic column 31, a transmission mating piece 44 is arranged between the telescopic column 31 and the electric driver 32, and the electric driver 32 drives the telescopic column 31 to extend out or retract through the transmission mating piece 44. Wherein, the transmission matching element 44 comprises a driving gear 441 and a rack 442 which are matched with each other, the rack 442 is vertically and fixedly arranged on the bottom end surface of the telescopic column 31, and the driving gear 441 is arranged on the driving shaft of the electric driver 32. The driving gear 441 is driven by the electric driver 32 to rotate, and the driving gear 441 drives the rack 442 to move up and down, so as to drive the telescopic column 31 to extend and retract.

In addition, as shown in fig. 3, the electrically driven telescopic assembly 121 may further include a guide cavity and a telescopic column 31, the detection module 11 is mounted on an upper end surface of the telescopic column 31, the driving portion includes an electrical driver 32 and a lifting table 33, the electrical driver 32 drives the lifting table 33 to rotate circumferentially, an oblique section 34 is disposed at a top of the lifting table 33, a connection rod 35 is disposed between the moving portion and the driving portion, one end of the connection rod 35 is fixedly disposed on a lower end surface of the telescopic column 31, the other end of the connection rod 35 is movably disposed on the oblique section 34, the connection rod 35 is supported by the oblique section 34, and a pulley 36 is disposed between the connection rod 35 and the oblique section 34. The electric driver 32 drives the lifting table 33 to rotate, the pulley 36 slides along the oblique section 34, and the connecting rod 35 drives the telescopic column 31 to move due to the height change of the oblique section 34, so that the telescopic of the detection module 11 is realized.

Further, motion module 12 still includes swing subassembly 122, swing subassembly 122 includes base 41 and swing driver 42, flexible subassembly 121 is installed the up end of base 41, swing driver 42 sets up the below of base 41, swing driver 42 with be equipped with driving medium 43 between the base 41, swing driver 42 passes through driving medium 43 swings base 41, and then changes the flexible direction of flexible subassembly 121 makes the flexible direction of detection module 11 and the perpendicular contained angle phi of axis 3 are changeable.

The swing driver 42 may be a motor such as a dc motor, an ac motor, a servo motor, etc., and the transmission member 43 may be a transmission member such as a gear, a connecting rod, etc., preferably, a gear transmission is used. The transmission member 43 includes a driving gear 431 and a driven gear 432, the driven gear 432 is disposed on the lower end face of the base 41, the driving gear 431 is driven by the swing driver 42 to rotate, the driving gear 431 drives the driven gear 432 to rotate, the base 41 swings up and down, and the telescopic direction of the telescopic assembly 121 is changed, so that the telescopic direction of the detection module 11 and the included angle phi of the vertical central axis 3 are variable. In addition, the gear and the rack can be matched, and the rack can be driven to move by a motor, an air cylinder or a hydraulic cylinder, so that the rotation of the gear is realized, and the change of the included angle phi is realized. Through changing detection module 11's flexible direction with perpendicular well axis 3's contained angle phi realizes detection module 11's detection field of vision luffing motion enlarges detection range, reduces the detection blind area, does benefit to detection module 11 accurately detects in real time the peripheral barrier of robot 1 sweeps floor reduces meaningless collision, avoids stretching out detection module 11's damage.

Further, the detection module 11 is provided with a rotation driver, and a rotation shaft of the rotation driver is disposed on an axis of the detection module 11 in the telescopic movement direction, so that the detection module 11 rotates by taking the axis of the telescopic movement direction as a central line to detect the conditions in all directions.

Rotate the driver like motor etc. and rotate the driver, detection module 11 passes through rotate the driver and rotate for the central line rotation around the axis of concertina movement direction, realize detection module 11 all-round detection the whole environment around robot 1 of sweeping the floor does benefit to the complete route that cleans of planning.

A method of detecting a controlled sweep, comprising the steps of:

extending the detection module 11 outwards to obtain the overall environmental information around the sweeping robot 1;

determining the running direction of the cleaning work according to the overall environment information;

the sweeping robot 1 performs sweeping work, and meanwhile, the detection module 11 continuously detects to acquire local environment information around the sweeping robot 1;

when the sweeping robot 1 detects that an obstacle exists at a certain height in the running direction, the detection module 11 retracts to the sweeping robot 1 by a corresponding height, so that the sweeping robot 1 passes through the obstacle;

after the sweeping robot 1 passes over the obstacle, the detection module 11 stretches out again to continue the detection work.

Since the detecting module 11 of this embodiment is installed in the body of the sweeping robot 1 through the moving module 12, the moving module 12 is used for controlling the detecting module 11 to extend outwards relative to the body, so that the detecting module 11 can be movably disposed in the body.

Therefore, the detection module 11 can extend out relative to the body, and detection blind areas are reduced, so that the overall environmental information with a larger detection range is detected, a complete cleaning route is planned, and the cleaning efficiency is improved.

The robot 1 of sweeping the floor is in the process of sweeping and continuously detects on a large scale, and detects in real time the peripheral environment of the robot 1 of sweeping the floor, especially right the peripheral barrier of the robot 1 of sweeping the floor accomplishes accurate real-time detection, thereby makes the robot 1 of sweeping the floor avoids meaningless collision.

When detection module 11 detects out certain height on the traffic direction and has the barrier, motion module 12 control detection module 11 toward 1 indentation of robot that sweeps floor corresponds the height, the calculation that corresponds the height can subtract the distance on current detection module 11 to ground for the distance on the minimum of barrier to ground, reduces detection module 11's height is convenient for robot 1 that sweeps floor passes through the barrier, thereby makes robot 1 that sweeps floor gets into low space, cleans.

Further, the process of acquiring the overall environmental information around the cleaning robot 1 is as follows:

the robot 1 of sweeping floor stretches out detection module 11, detection module 11 passes through the rotation of rotation driver obtains the current whole environmental information around of robot 1 of sweeping floor.

Through motion module 12 control detection module 11 for the body is outwards stretched out, and rethread rotates the driver and realizes detection module 11 all-round detection whole environment around robot 1 of sweeping the floor acquires holistic environmental information in order to carry out robot 1 work planning of sweeping the floor does benefit to the complete route that cleans of planning.

Further, the process of acquiring the local environment information around the cleaning robot 1 is as follows:

the robot 1 of sweeping floor passes through motion module 12 changes detection module 11's flexible stroke or/and flexible direction of motion make detection module 11's detection field of vision reciprocates, adjusts detection module 11's detection range acquires in real time the peripheral local environment of robot 1 of sweeping floor.

The telescopic stroke of the detection module 11 is changed through the motion module 12, so that the detection visual field of the detection module 11 moves up and down, the detection range of the detection module 11 is adjusted, and the detection module 11 can conveniently detect the local environment around the sweeping robot 1 in real time; through motion module 12 changes detection module 11's flexible direction makes detection module 11 luffing motion provides wider detection field of vision, is convenient for detection module 11 makes more accurate detection.

Further, the sweeping robot 1 establishes a map and performs positioning through the detection module 11 and a sensor built in the sweeping robot 1.

The built-in sensor of the sweeping robot 1 may be an inertial measurement unit such as a gyroscope or an acceleration sensor. In the cleaning process, the detection module 11 and the sensor acquire the surrounding environment information of the cleaning robot 1, a more accurate three-dimensional map is established, the planning and cleaning path determination is facilitated, and the collision is reduced.

Further, when robot 1 that sweeps floor detects out certain height in the traffic direction and has the barrier, detection module 11 acquires terrain clearance, direction and the distance information of barrier, when detection module 11 avoids the barrier, motion module 12 control detection module 11 toward robot 1 indentation of sweeping floor corresponds the height, and the record calculates the operation route record, and after passing through the barrier, detection module 11 stretches out again, continues real-time detection robot 1's the surrounding environment.

In this embodiment, the detection module 11 extends outward relative to the top of the sweeping robot 1, and the overall thickness of the sweeping robot is increased in the sweeping process, when the detection module 11 detects that an obstacle exists at a certain height in the running direction, if the sweeping robot 1 needs to enter a low space such as a table bottom or a cabinet bottom, information such as the ground clearance, the direction, the distance, and the like of the obstacle is acquired through the detection module 11, and when the detection module 11 avoids the obstacle, the movement module 12 controls the detection module 11 to retract to the sweeping robot 1 by the corresponding height, so that the height of the detection module 11 is reduced, and the sweeping robot 1 can conveniently pass through the obstacle; and recording and calculating a running path record, and after passing through the barrier, the detection module 11 stretches out again to continuously detect the surrounding environment of the sweeping robot 1 in real time. The detection module 11 only retracts a certain distance, and can still perform detection within a certain height range, and can identify whether the current state passes through the obstacle.

Furthermore, the included angle between the telescopic motion direction of the detection module 11 and the vertical central axis 3 is phi, wherein phi is more than or equal to 0 degrees and less than or equal to 60 degrees.

Further, the vertical direction stroke of the detection module 11 relative to the sweeping robot 1 is H, wherein H is greater than or equal to 0mm and less than or equal to 70 mm.

Further, the detection module 11 detects an angle β in the vertical direction right in front of the detection end, wherein β is greater than or equal to-30 ° and less than or equal to 50 °, wherein the detection angle below the horizontal line is negative, and the detection angle above the horizontal line is positive.

Further, after the cleaning task of the cleaning robot 1 is finished, the detection module 11 retracts into the cleaning robot 1 to be stored.

When robot 1 finishes clean task, motion module 12 control detection module 11 retracts into accomodate in the robot 1 of sweeping the floor, avoid detection module 11 exposes, improves detection module 11's working life.

Further, after the cleaning of the whole area is completed, the sweeping robot 1 finds the charging pile for recharging according to the detection module 11 and a map established by a built-in sensor of the sweeping robot 1.

After receiving the locating signal that fills electric pile and send in certain extent, combine locating signal to fix a position, improve and return and fill position control accuracy, the robot of sweeping the floor 1 returns the stake and charges the back, ensures next the robot of sweeping the floor 1 cleans the work occasionally sufficient electric quantity.

The technical principle of the present invention is described above with reference to specific embodiments. The description is made for the purpose of illustrating the principles of the invention and should not be construed in any way as limiting the scope of the invention. Based on the explanations herein, those skilled in the art will be able to conceive of other embodiments of the present invention without any inventive effort, which would fall within the scope of the present invention.

Claims (7)

1. The utility model provides a robot of sweeping floor which characterized in that: including detection module (11) and motion module (12), detection module (11) movable mounting in the body of robot (1) sweeps floor, motion module (12) are used for controlling detection module (11) for the body is outwards stretched out, makes detection module (11) telescopically activity set up in the body.

2. The sweeping robot of claim 1, wherein: the detection module (11) is extended outwards or retracted back relative to the top of the body through the movement module (12).

3. The sweeping robot of claim 1, wherein: motion module (12) are located the inside of robot (1) of sweeping the floor, motion module (12) include for telescopic component (121) of body activity, detection module (11) install in telescopic component (121), telescopic component's (121) flexible direction with the contained angle of the perpendicular axis (3) of robot (1) of sweeping the floor is phi, and wherein 0 is less than or equal to phi and is less than or equal to 60 deg.

4. The sweeping robot of claim 3, wherein: motion module (12) still includes swing subassembly (122), swing subassembly (122) include base (41) and swing driver (42), flexible subassembly (121) are installed base (41), swing driver (42) set up the below of base (41), swing driver (42) with be equipped with driving medium (43) between base (41), swing driver (42) are passed through driving medium (43) swing base (41), and then change the flexible direction of flexible subassembly (121), make the flexible direction of detection module (11) with the contained angle phi of perpendicular axis (3) is changeable.

5. The sweeping robot of claim 3, wherein: flexible subassembly (121) are including movable part and drive division, the movable part is including flexible post (31), the drive division includes electric drive (32), detection module (11) set up flexible post (31), be equipped with transmission fitting piece (44) between flexible post (31) and electric drive (32), electric drive (32) pass through transmission fitting piece (44) drive flexible post (31) are stretched out or are rolled back.

6. The sweeping robot of claim 5, wherein: the transmission fitting piece (44) comprises a driving gear (441) and a rack (442) which are matched with each other, the rack (442) is vertically and fixedly arranged at the bottom end face of the telescopic column (31), and the driving gear (441) is arranged at the driving shaft of the electric driver (32).

7. The sweeping robot of claim 1, wherein: the detection module (11) is provided with a rotary driver, and a rotary shaft of the rotary driver is arranged on the axis of the detection module (11) in the telescopic motion direction, so that the detection module (11) rotates by taking the axis of the telescopic motion direction as a central line.

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