JP2015231574A - Autonomous floor cleaning robot - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an autonomous floor cleaning robot capable of autonomously dealing with a detected situation by detecting the situation in which the robot is placed.SOLUTION: The autonomous floor cleaning robot includes a housing and a chassis, a plurality of wheels configured so as to move the robot on a floor surface and connected to the chassis through respectively corresponding arms and a motor for driving the plurality of wheels, a control part for controlling the movement of the robot on the floor surface, a sensor for detecting an obstacle to transmit obstacle information to the control part, a waste container, and a first rotary member configured so as to direct particles toward the waste container. The plurality of wheels are respectively connected rotatably to the tips of respectively corresponding arms, the proximal end of an arm is connected rotatably to the chassis, the plurality of wheels are respectively energized to an extended position away from the chassis by a spring extending between an arm and the chassis, and the weight of the robot overcomes the force of the spring which respectively energizes the plurality of wheels to the extended positions.

Description

  The present invention relates to a cleaning device, and more particularly to an autonomous floor cleaning robot.

  Autonomous robot cleaning devices are known in the art. For example, US Pat. Nos. 5,940,927 and 5,781,960 disclose “Autonomous Surface Cleaning Apparatus and No Nozzle Arrangement for a Self-Guiding Vacuum Cleaner”. Yes. One of the main requirements for an autonomous cleaning device is a self-contained power source, and if such an autonomous cleaning device utilizes a power cord to an outlet to an external power source, it must be eliminated immediately. The usefulness of the device is significantly reduced.

  In addition, although the driving capability of a self-contained power source such as a battery is clearly improved, today's self-contained power source still has a time limit for providing power. Cleaning mechanisms for cleaning devices such as brush assemblies and vacuum assemblies typically require large power loads to provide efficient cleaning capabilities. This is especially true when the brush assembly and vacuum assembly are configured as a combination, since the brush assembly and / or vacuum assembly of such a combination is typically designed for co-operation. Or it is not configured.

  Thus, an autonomous design and configuration designed to optimize the cleaning capability and efficiency of the cleaning mechanism of the autonomous cleaning device for co-operation while concomitantly minimizing or reducing the power requirements for such cleaning mechanism. There is a need to provide a mechanical cleaning device.

  One object of the present invention is to provide a cleaning device operable to clean a specified area without human intervention.

  Another object of the present invention is designed and configured to optimize the cleaning capability and efficiency of the cleaning mechanism of the autonomous cleaning device for cooperative action while concomitantly minimizing the power requirements for such mechanism. To provide an autonomous cleaning device.

  These and other objects of the present invention are autonomous floor cleaning robots, each of which is disposed at least partially within the housing and chassis and is configured to move the robot over the floor surface. A plurality of wheels connected to the chassis via corresponding arms having a tip and a proximal end, and at least one motor for driving the wheels, and disposed in the housing to control movement of the robot on the floor surface A controller that controls the robot so that the robot reacts to the obstacle, at least one sensor that detects the obstacle and transmits obstacle information to the controller, and at least partially within the housing A detachable garbage container arranged to receive particles and a first rotating member configured to direct particles to the garbage container; Each of the plurality of wheels is rotatably coupled to the tip of the corresponding arm, the proximal end of the arm is rotatably coupled to the chassis, and the plurality of wheels are each provided by a spring extending between the arm and the chassis. According to one embodiment of the present invention, wherein the weight of the robot is biased to the extended position away from the chassis, and the weight of the robot overcomes the force of the spring that biases each of the plurality of wheels to the extended position during cleaning. Achieved by autonomous floor cleaning robot.

It is the schematic of the autonomous floor cleaning robot which concerns on this invention. It is a perspective view of one Example of the autonomous floor cleaning robot which concerns on this invention. FIG. 3 is a bottom plan view of the autonomous floor cleaning robot of FIG. 2. It is the partially broken top plan view which removed the cover of another example of the autonomous floor cleaning robot concerning the present invention. FIG. 5 is a partially broken bottom plan view of the embodiment of the autonomous floor cleaning robot of FIG. 4. FIG. 5 is a partially broken side view of the embodiment of the autonomous floor cleaning robot of FIG. 4. FIG. 5 is a plan view of the deck and chassis of the embodiment of the autonomous floor cleaning robot of FIG. 4. It is sectional drawing of FIG. 7 along the BB line. FIG. 5 is a perspective view of a deck adjustment subassembly of the embodiment of the autonomous floor cleaning robot of FIG. 4. FIG. 5 is a first exploded perspective view of a dust cartridge for the embodiment of the autonomous floor cleaning robot of FIG. 4. FIG. 11 is a second exploded perspective view of the dust cartridge of FIG. 10. FIG. 5 is a perspective view of a two-stage brush assembly including a flapper brush and a main brush for the embodiment of the autonomous floor cleaning robot of FIG. 4. FIG. 5 is a perspective view showing blades and vacuum compartments for the embodiment of the autonomous floor cleaning robot of FIG. 4. FIG. 14 is a partially exploded perspective view of the embodiment of the autonomous floor cleaning robot of FIG. 13.

  The invention and its attendant features and advantages will be more fully understood with reference to the detailed description of the invention when taken in conjunction with the accompanying drawings.

  Referring to the drawings wherein like reference numerals represent corresponding or like elements throughout the several views, FIG. 1 is a schematic diagram of an autonomous floor cleaning robot 10 according to the present invention. The robot 10 includes a housing substructure 20, a power subsystem 30, a drive subsystem 40, a sensor subsystem 50, a control module 60, a side brush assembly 70 and a self-adjusting cleaning head subsystem 80. The power subsystem 30, drive subsystem 40, sensor subsystem 50, control module 60, side brush assembly 70, and self-adjusting cleaning head subsystem 80 are combined as described in more detail in the following paragraphs. And integrated into the housing basic structure 20 of the robot 10.

  In the following description of the autonomous floor cleaning robot 10, the term “forward / fore” refers to the main direction of operation of the autonomous floor cleaning robot 10, and the fore-aft axis ( The term “reference” “FA” in FIGS. 4 and 5) defines a forward direction of motion that matches the front-rear diameter of the robot 10.

  2, 3, and 4 to 6, the housing base structure 20 of the robot 10 includes a chassis 21, a cover 22, a displaceable bumper 23, a tip wheel subassembly 24, and a transport handle 25. The chassis 21 preferably mounts or otherwise incorporates elements of the power subsystem 30, drive subsystem 40, sensor subsystem 50, side brush assembly 70 and self-adjusting cleaning head subsystem 80 to be combined with the chassis 21. Molded from a material such as plastic as a unitary element including a plurality of depressions, recesses and structural members preformed to be integrated. The cover 22 is preferably a unitary element that is complementary to the chassis 21 in construction and protects the elements / components attached to the chassis 21 and / or the elements / components that make up the self-adjusting cleaning head subsystem 80. And molded from a material such as plastic as a single element that provides access to it. The chassis 21 and the cover 22 cooperate to be detachably integrated by any suitable means such as screws, and the chassis 21 and the cover 22 cooperate to be roughly symmetrical along the longitudinal axis FA. Forming a minimum height structural envelope having a generally cylindrical configuration.

  A displaceable bumper 23 having a generally arcuate configuration is mounted in a movable connection at the front of the chassis 21 so as to extend outwardly, ie to a normal operating position. The displaceable bumper mounting configuration is such that whenever the bumper 23 encounters a stationary object or obstacle with a predetermined mass, the bumper 23 is displaced toward the chassis 21 (from the normal operating position), i.e., a displacement position, and (In response to any such displacement of the bumper 23, a “rebound” mode is implemented that causes the robot 10 to avoid a stationary object or obstacle, and random or weighted random to resume forward movement in a different direction. The bumper 23 returns to the normal operation position when the contact with the stationary object or obstacle is terminated (by the operation of the control module 60 to continue the cleaning routine such as starting a turn). The mounting configuration of the displaceable bumper 23 includes a pair of rotatable support members 23RSM that operate to promote movement of the bumper 23 relative to the chassis 21.

  The pair of rotatable support members 23RSM are mounted symmetrically around the front-rear axis FA of the autonomous floor cleaning robot 10 near the center of the displaceable bumper 23. One end of each support member 23RSM is rotatably attached to the chassis 21 by customary means such as pin / matching pin and sleeve arrangement, and the other end of each support member 23RSM is also rotated to the displaceable bumper 23 by similar customary means. Mounted as possible. A biasing spring (not shown) is provided in combination with each support member 23RSM, and the spring is always moved (by the rotational movement of each support member 23RSM) when the contact with the stationary object or obstacle is terminated. ) Acts to provide the biasing force necessary to return the displaceable bumper 23 to the normal operating position.

  The embodiment described herein includes a pair of bumper arms mounted symmetrically in parallel around the longitudinal axis FA of the autonomous floor cleaning robot 10 distal to the center of the displaceable bumper 23. Includes 23BA. These bumper arms 23BA themselves do not provide structural support for the displaceable bumper 23, but rather a sensor subsystem that acts to determine the location of stationary objects or obstacles encountered via the displaceable bumper 23. Part of 50. One or both bumper arms 23BA can be linearly displaced with respect to the chassis 21 during the encounter with a stationary object or obstacle so that the control module 60 provides a corresponding signal to implement the “rebound” mode. One end of each bumper arm 23BA is firmly fixed to the displaceable bumper 23 and other than each bumper arm 23BA so as to activate the associated sensors such as IR blocking beam sensors, mechanical switches, capacitance sensors, etc. The ends are attached in combination to the chassis 21 in a manner such as slot arrangement. Further details regarding this aspect of the sensor subsystem 50 and alternative embodiments of sensors useful for detecting contact or proximity to stationary objects or obstacles can be found in the applicant's own See in US patent application Ser. No. 10 / 056,804, filed Jan. 24, 2002, entitled Pending “Method and System for Multi-Mode Application to Autonomous Robots”.

  The tip wheel subassembly 24 includes a wheel 24W rotatably mounted in combination with a U-link member 24CM including a mounting shaft. The U link mounting shaft 24CM is disposed in the recess of the chassis at the front end of the chassis 21 on the front and rear diameters of the autonomous floor cleaning robot 10. A biasing spring 24BS (hidden behind the leg of the U link member 24CM in FIG. 6) is provided in combination with the U link mounting shaft 24CM, and the spring has a surface on which the tip wheel subassembly 24 is to be cleaned. Whenever the contact is lost, it acts to bias the tip wheel subassembly 24 to the 'extended' position. During the cleaning operation, the weight of the autonomous floor cleaning robot 10 is partially retracted so that the wheels rotate freely over the surface to be cleaned by overcoming the force exerted by the biasing spring 24BS. It is sufficient to bias the tip wheel subassembly 24 into position. Triangular or conical wings 24TW extend outward from each end of the U-link member, and the side of the wheel is a low-order obstacle during the rolling movement of the autonomous floor cleaning robot 10. Is prevented from engaging. The wing part 24TW acts as an inclined part when the robot turns and slides over the raised part.

  Each end portion 25E of the transfer handle 25 is fixed in combination so as to pivot relative to the cover 22 at the front end portion of the cover 22 centered with respect to the longitudinal axis FA of the autonomous floor cleaning robot 10. When the autonomous floor cleaning robot 10 sits on or moves over the surface to be cleaned, the transport handle 25 is substantially flush with the surface of the cover 22 (in a handle / cover pivot configuration). The weight of the transport handle 25 associated with the placement is sufficient to automatically return the transport handle 25 to this flush position by gravity). When the autonomous floor cleaning robot 10 is lifted by the transfer handle 25, the rear end portion of the autonomous floor cleaning robot 10 is located below the front end portion of the autonomous floor cleaning robot 10, so that the self-adjusting cleaning head -Granular debris does not fall off from the subsystem 80.

  The power subsystem 30 of the described embodiment is a separate component / component of the drive subsystem 40, sensor subsystem 50, side brush assembly 70 and self-adjusting cleaning head subsystem 80 during the cleaning operation. , As well as the circuitry and components of the control module 60, providing energy to power the associated circuits 32-4, 32-5, 32-7, 32-8 and 32-6, respectively (FIG. 1). reference). The power subsystem 30 for the described embodiment of the autonomous floor cleaning robot 10 comprises a rechargeable battery pack 34, such as a NiMH battery pack. The rechargeable battery pack 34 is mounted in a recess formed in the chassis 21 (particularly sized for the battery pack 34 to be mounted / retained) and can be used for any custom purpose such as a spring latch (not shown). Held there by means. The battery recess is covered with a lid portion 34L fixed to the chassis 21 by customary means such as screws. A friction pad 36 that promotes the stop of the autonomous floor cleaning robot 10 is fixed to the lid 34L during the automatic shutdown. The friction pad 36 helps the robot to stop when the robot tries to get over the cliff. The rechargeable battery pack 34 comprises elements / components comprising a drive subsystem 40, a sensor subsystem 50, a side brush assembly 70, a self-adjusting cleaning head subsystem 80, as well as the circuitry and components of the control module 60. If the power requirement is satisfied, it is configured to provide sufficient power to operate the autonomous floor cleaning robot 10 for 60 to 90 minutes at maximum charge.

  The drive subsystem 40 (1) propels the autonomous floor cleaning robot 10 for cleaning operations, (2) activates the side brush assembly 70, and (3) self-activates during such cleaning operations. Independent means for operating the adjustment cleaning head subsystem 80 are provided. Such independent means include left and right main wheel subassemblies 42A and 42B, each having independent motors 42AM and 42BM, respectively, and an independent electric motor 44 for side brush assembly 70, while 46 is for the vacuum assembly. And the other 48 includes two independent electric motors 46, 48 which are for the two-stage brush assembly.

  The left and right main wheel subassemblies 42A and 42B are independently mounted in recesses in the chassis 21 formed at each end of the chassis 21 lateral diameter (the lateral diameter is determined by the longitudinal axis of the robot 10). Orthogonal to FA). When installed at this location, the autonomous floor cleaning robot 10 is provided with enhanced turning capability, since the motors of the main wheel subassemblies 42A, 42B are, for example, acute turning, progressive turning, in-situ. This is because it can be operated independently to perform a wide range of turning operations such as turning.

  The main wheel subassemblies 42A and 42B include wheels 42AW and 42BW that are rotatably mounted in combination with the U link members 42ACM and 42BCM, respectively. Each U link member 42ACM, 42BCM is pivotally attached to the chassis 21 behind the wheel rotation axis (see FIG. 6 showing the wheel rotation axis 42AAR; the wheel rotation axis for the wheel subassembly 42B not shown) The hearts are the same), that is, they are suspended independently. According to the rear pivot axes 42APA and 42BPA (see FIG. 4) of the main wheel subassemblies 42A and 42B, the mobility of the autonomous floor cleaning robot 10, that is, the pivot movement of the subassemblies 42A and 42B over a predetermined arc is promoted. Is done. Motors 42AM and 42BM respectively associated with the main wheel subassemblies 42A and 42B are attached to the rear ends of the U link members 42ACM and 42BCM. One end of the tension spring 42BTS is attached to the rear portion of the U link member 42BCM, and the other end of the tension spring 42BTS is attached to the chassis 21 in front of the respective wheels 42AW and 42BW (the tension spring for the right wheel subassembly 42A). Is not shown, but is the same as the tension spring 42BTS of the left wheel subassembly 42A).

  Each tension spring moves the respective main wheel subassembly 42A, 42B (by pivotal movement over a predetermined arc of the corresponding U link member 42ACM, 42BCM) when the autonomous floor cleaning robot 10 is removed from the floor. It operates to urge the rotation to the “stretched” position (in this “stretched” position, the wheel rotation axis is located below the bottom plane of the chassis 21). When the autonomous floor cleaning robot 10 sits on or moves over the surface to be cleaned, the weight of the autonomous floor cleaning robot 10 causes each main wheel subassembly 42A, 42B to move into the retracted or activated position. It is gravitationally biased, where the rotational axis of each wheel is substantially coplanar with the bottom plane of the chassis 21. The motors 42AM, 42BM of the main wheel subassemblies 42A, 42B are: (1) at the same speed in the same direction of rotation to propel the autonomous floor cleaning robot 10 in a straight line forward or backward (2) (one wheel At different speeds to make a turning pattern for the autonomous floor cleaning robot 10 (including situations where it is operated at zero speed), or (3) reverse to make the robot 10 turn in place, or “turn in a narrow place” Operates to drive each major wheel at the same speed in the direction of rotation.

  The wheels 42AW, 42BW of the main wheel subassemblies 42A, 42B preferably have "uneven" tread configurations 42AKT, 42BKT. This rugged tread configuration 42AKT, 42BKT is especially useful when traversing smooth surfaces and when traversing between successive surfaces of different tissues, for example from bare floor to carpet or vice versa. A large traction force is provided to the robot 10. This uneven tread configuration 42AKT, 42BKT also allows the carpet / rug tufted fabric to be captured by the wheels 42AW, 42BW and caught between each wheel and the chassis 21 during the movement of the autonomous floor cleaning robot 10. To prevent. However, one skilled in the art will appreciate that other tread patterns / configurations are within the scope of the present invention.

  The sensor subsystem 50 comprises a variety of different detection units that can be broadly characterized as (1) a control detection unit 52 or (2) an emergency detection unit 54. As the name implies, the control detection unit 52 operates to adjust the normal operation of the autonomous floor cleaning robot 10 and the emergency detection unit 54 can adversely affect the operation of the autonomous floor cleaning robot 10 (e.g. The autonomous floor cleaning robot 10 operates to allow the control module 60 to perform an appropriate response because it detects the staircase descending from the surface being cleaned and provides a signal in response to such detection. The control detection unit 52 and emergency detection unit 54 of the autonomous floor cleaning robot 10 are summarized and described in the following paragraphs, but a more complete description is a co-pending patent owned by the applicant as well as the present application. US patent application Ser. No. 09 / 768,773 filed Jan. 24, 2001, entitled “Robot Obstacle Detection System”, June 2002, entitled “Method and System for Robot Positioning and Localization” U.S. Patent Application No. 10 / 167,851 filed on the 12th and U.S. Patent Application No. 10 / filed on Jan. 24, 2002, entitled "Method and System for Multi-Mode Application to Autonomous Robots" It can be seen in 056,804.

  The control detection unit 52 includes an obstacle detection sensor 52OD attached in relation to the linear displaceable bumper arm 23BA of the displaceable bumper 23, a wall detection assembly 52WS attached to the right hand portion of the displaceable bumper 23, and A virtual wall detection assembly 52VWS mounted on the top of the displaceable bumper 23 along the front-rear diameter of the autonomous floor cleaning robot 10, and an IR sensor / encoder combination 52WE mounted in combination with each wheel subassembly 42A, 42B including.

  Since each obstacle detection sensor 52OD includes an emitter / detector combination positioned in association with one of each linearly displaceable bumper arm 23BA, sensor 52OD provides a detection signal in response to the displacement of the bumper arm 23BA. Operates to transmit to control module 60. Wall sensing assembly 52WS includes an emitter / detector combination that operates to detect the approach of a wall or other similar structure and send a detection signal to control module 60. Each IR sensor / encoder combination 52WE acts to measure the rotation of the associated wheel subassembly 42A, 42B and send a corresponding signal to the control module 60.

  The virtual wall sensing assembly 52VWS operates to detect force fields and parallel beams emitted by stand-alone emitters (not shown virtual wall units) and transmit respective signals to the control module 60. . Since the autonomous floor cleaning robot 10 is programmed so as not to pass the parallel beam, the virtual wall unit can enter the prohibited area such as an upstairs or access to a room that should not be cleaned. Can be used to prevent The robot 10 is further programmed to avoid the force field generated by the virtual wall unit, thereby preventing the robot 10 from overrunning the virtual wall unit during the floor cleaning operation.

  The emergency detection unit 54 includes a 'upright detector' assembly 54CD mounted in the displaceable bumper 23, and a wheel lowering assembly mounted in relation to the left and right main wheel subassemblies 42A, 42B and the tip wheel assembly 24. For 54WD and the respective current stop detection units 54CS for the motors 42AM, 42BM of each main wheel subassembly 42A, 42B and the motors 44, 48 (these two motors are fed via a common circuit in the described embodiment) One current stop detection unit 54CS is included. For the described embodiment of the autonomous floor cleaning robot 10, four upright detector assemblies 54 CD are mounted in the displaceable bumper 23. Each upright detector assembly 54CD includes an emitter / detector combination that operates to detect a predetermined descent in the path of the robot 10, such as a downstairs, and send a signal to the control module 60. The wheel lowering assembly 54WD detects when the corresponding left and right main wheel subassemblies 42A, 42B and / or the tip wheel assembly 24 enter an extended position such as a contact switch and sends a corresponding signal to the control module 60. It works as much as possible. The current stop detection unit 54CS operates to detect a change in the current of each motor indicating the stop state of the motor corresponding to each component and to transmit a corresponding signal to the control module 60.

  The control module 60 controls the robot 10 to control movement of the autonomous floor cleaning robot 10 in response to signals generated by the sensor subsystem 50 during floor cleaning operations (eg, FIG. 1). Control lines 60-4, 60-5, 60-7 and 60-8) and a microcontroller. The control module 60 of the autonomous floor cleaning robot 10 according to the present invention can be classified as (1) “spot reach” mode, (2) “wall / obstacle tracking” mode, and (3) “rebound” mode. Pre-programmed (in hard connection, software, firmware or a combination thereof) to implement three basic modes of operation or movement patterns. In addition to this, the control module 60 is pre-programmed to initiate an action based on the signal received from the sensor subsystem 50, but such action is not limited and includes movement patterns (2) and ( Implementation of 3), emergency stop of the robot 10, or generation of an acoustic alarm can be mentioned. Further details regarding the operation of the robot 10 by the control module 60 can be found in the United States filed January 24, 2001 under the name of a co-pending “robot obstacle detection system” owned by the applicant as well as the present application. US patent application Ser. No. 09 / 768,773, US patent application Ser. No. 10 / 167,851, filed Jun. 12, 2002, entitled “Robot Positioning and Localization Method and System” and “Multi-Mode for Autonomous Robots” Detailed description is given in US patent application Ser. No. 10 / 056,804, filed Jan. 24, 2002, entitled “Methods and Systems for Application”.

  The side brush assembly 70 captures large and small dust outside the outer periphery of the housing foundation structure 20 of the autonomous floor cleaning robot 10 and passes such dust to the self-adjusting cleaning head subsystem 80. Operates to direct. This provides the robot 10 with the ability to clean the surface near the baseboard (during the wall following mode).

  The side brush assembly 70 is mounted in a recess formed in the lower surface of the right front quadrant of the chassis 21 (in front of the right main wheel subassembly 42A immediately after the right end of the displaceable bumper 23). The side brush assembly 70 includes a shaft 72 having one end rotatably connected to the electric motor 44 for torque transfer, a hub 74 connected to the other end of the shaft 72, and a cover surrounding the hub 74. It comprises a plate 75, brush means 76 secured to the hub 74, and a group of bristle 78.

  The cover plate 75 is configured and secured to the chassis 21 to surround the hub 74 so as to prevent the brush means 76 from clogging below the chassis 21 during the floor cleaning operation.

  For the embodiment of FIGS. 4-6, the brush means 76 includes a counter-brush arm extending outwardly from the hub 74. These brush arms 76 are formed from a constant width “L” / hockey stick-shaped elastic plastic or rubber material. Due to the cooperation of the shape and structure of the brush arm 76, the brush arm 76 can be elastically deformed when an obstacle or obstacle is temporarily encountered during the cleaning operation. Additionally, the use of a constant width counter-brush arm 76 is relative to the operation of the adjacent upright detector assembly 54CD (the leftmost upright detector assembly 54CD in FIG. 5) in the displaceable bumper 23. An alternative (relative to the use of a complete or partially circular brush configuration) to ensure that the action of the brush means 76 of the side brush assembly 70 is not adversely affected (ie by occlusion). The brush arm 76 has a length sufficient to extend beyond the outer periphery of the autonomous floor cleaning robot 10, in particular its displaceable bumper 23. According to such a length, the autonomous floor cleaning robot 10 does not scrape the wall / baseboard (during the wall following mode) by the chassis 21 and / or the displaceable bumper 23 of the robot 10. The surface in the vicinity of can be cleaned.

  A group of bristles 78 is set at the outermost free end of each brush arm 76 (similar to a toothbrush shape) to provide the sweeping capability of the side brush assembly 70. The bristles 78 are long enough to engage the surface being cleaned when the main wheel subassembly 42A, 42B and the tip wheel subassembly 24 are in the operative position.

  Self-adjusting cleaning head subsystem 80 provides a cleaning mechanism for autonomous floor cleaning robot 10 according to the present invention. The cleaning mechanism for the preferred embodiment of the self-adjusting cleaning head subsystem 80 includes a brush assembly 90 and a vacuum assembly 100.

  4-6, the brush assembly 90 is a two-stage brush mechanism, and the two-stage brush assembly 90 and the vacuum assembly 100 provide an efficient cleaning capability while simultaneously providing the robot 10. A structurally and functionally independent cleaning mechanism that is adapted and designed for use with the robot 10 to minimize overall power requirements. In addition to the cleaning mechanism described in the preceding paragraph, the self-adjusting cleaning head subsystem 80 includes a deck structure 82 pivotally connected to the chassis 21, an automatic deck adjustment subassembly 84, a removable dust cartridge 86, And one or more bail 88 that shields the stage brush assembly 90.

  The deck 82 is preferably fabricated as a unitary structure from a material such as plastic and includes each side wall 82SW formed at the rear end of the deck 82 and spaced apart from each other (one of the side walls 82SW is a motor 46). A U-shaped structure that houses the cartridge, a brush assembly dent 82W, and a side that defines an opening between the two-stage brush assembly 90 and the removable dust cartridge 86 by being formed in the middle of the lower deck surface Including an opening 82LA and a mounting bracket 82MB formed on the front portion of the upper deck surface with respect to the motor 48).

  Each side wall 82SW is positioned and configured to attach the deck 82 to the chassis 21 in a pivotal combination by customary means such as a rotary joint (see reference numeral 82RJ in FIG. 4). The pivot axis of the combination of the deck 82 / chassis 21 is orthogonal to the longitudinal axis FA of the robot 10 at the rear end of the autonomous floor cleaning robot 10 (see FIG. 4 for identifying the pivot axis). (See symbol 82PA).

  The mounting bracket 82MB is positioned and configured to attach the constant torque motor 48 to the front lip of the deck 82. The rotational axis of the attached motor 48 is orthogonal to the front-rear diameter of the autonomous floor cleaning robot 10 (see reference numeral 48RA identifying the rotational axis of the motor 48 in FIG. 4). From the mounted motor 48, a shaft 48S for transmitting a constant torque extends to the input side of a customary two-stage output transmission 48B on the fixed side (the housing of the two-stage output transmission 48B is part of the deck 82). Produced).

  The deck adjustment subassembly 84, shown in greater detail in FIGS. 7-9, is mounted in combination with the motor 48, deck 82 and chassis 21, and is combined with the electric motor 48 to provide the two-stage brush assembly 90. Provide the physical mechanism and starting force to pivot the deck 82 relative to the chassis 21 about the pivot axis 82PA whenever a situation is encountered that results in a predetermined reduction in the rotational speed of the two-stage brush assembly 90 It works as much as possible. This situation that most commonly occurs when the autonomous floor cleaning robot 10 transitions between a smooth surface such as a floor and a carpet surface is characterized as an 'adjustment mode' in the remainder of the description.

  The deck adjustment subassembly 84 for the described embodiment of FIG. 4 includes a motor cage 84MC, a pulley 84P, a pulley cord 84C, an anchor member 84AM, and a complementary cage stop 84CS. The motor 48 is fixed in the motor cage 84MC in a non-rotatable manner, and the motor cage 84MC is mounted in a rotatable combination between the mounting brackets 82MB. The pulley 84P is fixedly secured to the motor cage 84MC on the opposite side of the internal mounting bracket 82MB in such a manner that the shaft 48S of the motor 48 passes freely through the center of the pulley 84P. Anchor member 84AM is fixedly fixed to the top surface of chassis 21 in alignment with pulley 84P.

  One end of the pulley cord 84C is fixed to the anchor member 84AM, and the other end is arranged in such a manner that the pulley cord 84C is stretched when the deck 82 is in the 'downward' or non-pivoting position. Fixed to 84P. One of the cage stops 84CS is secured to the motor cage 84MC, and the complementary cage stops 84CS are secured to the deck 82. Each complementary cage stop 84CS abuts when the deck 82 is in the 'down' position due to the weight of the self-adjusting cleaning head subsystem 80 during normal cleaning operations.

  During normal cleaning operations, the torque generated by the motor 48 is transmitted to the two-stage brush assembly 90 by the shaft 48S via the two-stage output transmission 48B. The motor cage assembly is prevented from rotating by the reaction torque generated by the pulley cord 84C on the pulley 84P. When the resistance encountered by the rotating brush changes, the deck height is adjusted to compensate for this. For example, if the brush torque increases as the device rolls from the smooth floor onto the carpet, the torque output of the motor 48 increases. Accordingly, the output torque of the motor 48 increases. This increased torque overcomes the reaction torque exerted on pulley 84P by pulley cord 84C. As a result, the pulley 84P itself rotates to effectively pull the pulley cord 84C. This causes the deck to pivot about the pivot axis, the brush is raised, the friction between the brush and the floor is reduced, and is required by the two-stage brush assembly 90. Torque is reduced. This continues until the reaction torque generated on the pulley 84P by the motor 48 and pulley cord 84C is rebalanced and a new deck height is established.

  In other words, the torque transmission mechanism is cut off during the adjustment mode because the shaft 48S is essentially stationary. Under this condition, the motor 48 effectively rotates around the shaft 48S. Since the motor 48 is non-rotatably fixed to the motor cage 84MC, the motor cage 84MC and incidentally the pulley 84P rotate with respect to the mounting bracket 82MB. The pulley 84P is 'wound up' around the pulley cord 84PC toward the anchor member 84AM by the rotational motion applied to the pulley 84P. Since the motor cage 84MC is effectively attached to the front lip of the deck 82 by the mounting bracket 82MB, this movement of the pulley 84P causes the deck 82 to pivot to an “up” position about its pivot axis 82PA. Move. By this pivoting operation, the front portion of the deck 82 moves away from the surface on which the autonomous floor cleaning robot passes.

  Such pivoting also effectively moves the assembly away from the surface with which the two-stage brush assembly 90 was in contact, so that the two-stage brush assembly 90 increases in speed (transmitted from the motor 48). The steady state rotational speed can be resumed (corresponding to the constant torque being applied). At this time (when the two-stage brush assembly 90 reaches its steady state rotational speed), the deck 82 may be 'downward' or normal, i.e., the bottom surface of the chassis 21 due to the weight of the front edge of the deck 82 (mainly the motor 48). Gravitally biased to return and pivot in a planar manner, where each complementary cage stop 84CS abuts.

  The deck adjustment subassembly 84 described in the preceding paragraph is a preferred pivoting mechanism for the autonomous floor cleaning robot 10 according to the present invention, but those skilled in the art will be able to pivot the deck 82 in the adjustment mode described above. It will be appreciated that other mechanisms may be employed to utilize the torque developed by the deck adjustment subassembly 84 to induce. For example, the deck adjustment subassembly may be a spring loaded clutch mechanism such as that shown in FIG. 9 (identified by reference numeral SLCM) or centrifugal clutch that pivots the deck 82 to the “up” position during the adjustment mode. A mechanism or a torque limiting clutch mechanism can be used. In other embodiments, the motor torque uses either the spring or the weight of the cleaning head to generate a reaction torque by replacing the pulley with a cam and constant force spring or replacing the pulley with a rack and pinion. And can be used to adjust the height of the cleaning head.

  The removable dust cartridge 86 provides temporary storage of large and small dust swept by the action of the two-stage brush assembly 90 and small dust sucked by the action of the vacuum assembly 100. The removable dust cartridge 86 includes a first storage chamber 86SC1 for large and small dust swept by the two-stage brush assembly 90, and a second storage chamber 86SC2 for small dust sucked by the action of the vacuum assembly 100. Is configured as a dual chamber structure. Since the removable dust cartridge 86 is further configured to be inserted in combination with the deck 82, the segments of the deck adjustment subassembly 84 define a portion of the rear external sidewall structure of the autonomous floor cleaning robot 10.

  As shown in FIGS. 10 and 11, the removable dust cartridge 86 includes a bottom plate member 86FM and a top plate member 86CM that are joined to each other by the opposing side wall members 86SW. The bottom plate member 86FM and the top plate member 86CM extend beyond the side wall member 86SW to define an open end 86OE, and the free end of the bottom plate member 86FM is slightly angled to form a plurality of baffle protrusions 86AJ. Including, removes debris trapped by the brush mechanism of the two-stage brush assembly 90, and inserts a removable dust cartridge 86 combined with the deck 82 and sweeps into the removable dust cartridge 86 Promotes the retention of generated dust. A rear wall member 86BW that comes into contact with and engages with the side wall member 86SW is attached between the bottom plate member 86FM and the top plate member 86CM at the distal end of the open end 86OE. The rear wall member 86BW has a baffle configuration for the purpose of angularly deflecting the dust to prevent the dust swept by the two-stage brush assembly 90 from splashing back into the brush assembly 90. The bottom plate member 86FM, the top plate member 86CM, the side wall member 86SW, and the rear wall member 86BW are combined to define the first storage chamber 86SC1.

  The removable dust cartridge 86 further includes a curved arcuate member 86CAM that defines the rear external sidewall structure of the autonomous floor cleaning robot 10. The curved arc member 86CAM engages with the top plate member 86CM, the bottom plate member 86F, and the side wall member 86SW. A gap is formed between the curved arc-shaped member 86CAM and the one side wall member 86SW to define a vacuum inlet 86VI for the removable dust cartridge 86. A replaceable filter 86RF is configured to be elastically fitted and inserted in combination with the bottom plate member 86FM. The replaceable filter 86RF, the curved arc member 86CAM, and the rear wall member 86BW are combined to define the second storage chamber 86SC1.

  Since the detachable dust cartridge 86 is configured to be inserted between the opposing side walls 82SW of the deck 82, the open end of the detachable dust cartridge 86 is aligned with the lateral opening 82LA formed in the deck 82. . A latch member 86LM is attached to the outer surface of the top plate member 86CM. The latch member engages with a complementary shoulder formed on the upper surface of the deck 82 so that the removable dust cartridge 86 is integrated with the deck 82. It works to hang in combination.

  The divider frame 88 includes one or more narrow gauge wire structures that cover the two-stage brush assembly 90. For the described embodiment, the divider 88 comprises a continuous narrow gauge wire structure formed in a castellated shape, ie, alternating side open rectangles. Alternatively, the divider frame 88 may consist of a plurality of side-opening single rectangles formed of narrow gauge wires. The divider frame 88 is designed and configured to be press-fitted into complementary retaining grooves 88A, 88B formed in the deck 82 in the immediate vicinity of both sides of the two-stage brush assembly 90, respectively. The divider 88 acts to shield the two-stage brush assembly 90 from large external objects such as carpet tresses, tufted cloth, rug edges, etc. during the cleaning operation, i.e. Deviation away from the staged brush assembly 90 prevents the object from becoming entangled with the brush mechanism.

  The two-stage brush assembly 90 for the described embodiment of FIG. 4 comprises a flapper brush 92 and a main brush 94 shown schematically in FIG. Structurally, the flapper brush 92 and the main brush 94 are asymmetric with respect to each other, and the main brush 94 has an OD greater than the OD (outer diameter) of the flapper brush 92. Flapper brush 92 and main brush 94 are mounted in the recesses of deck 82 as described in more detail below to minimize the spacing between each sweeping perimeter defined by their respective rotating elements. To do. Functionally, the flapper brush 92 and the main brush 94 rotate counterclockwise, the flapper brush 92 rotates in the first direction that directs large dust into the removable dust cartridge 86, and the main brush 94 is large. In order to direct the small and small dust particles into the removable dust cartridge 86, the autonomous floor cleaning robot 10 rotates in the second direction opposite to the forward movement. In addition, this rotational movement of the main brush 94 is large and small so that dust that is not swept by the two-stage brush assembly 90 can continue to be sucked (sucked) by the vacuum assembly 100 as the autonomous floor cleaning robot 10 moves. It has the secondary effect of directing small dust to the pick-up area of the vacuum assembly 100.

  Flapper brush 92 includes a central member 92CM having first and second ends. The first and second ends connect the flapper brush 92 to the deck 82 and the first output port of the two-stage output transmission 48B so that the rotation of the flapper brush 92 is provided by the torque transmitted from the electric motor 48. Designed and configured to attach to 48BO1 in a rotatable combination (transmission 48B is configured so that the rotation speed of flapper brush 92 is related to the speed of autonomous floor cleaning robot 10, and the robot 10 is described. The example has a maximum speed of about 0.9 feet / second). In other embodiments, the flapper brush 92 rotates at a substantially higher speed than the traversing speed, with or without the traversing speed. Forcing the hair and other similar objects away from the flapper brush 92 prevents the object from becoming entangled at each end of the central member 92CM and preventing the two-stage brush assembly 90 from stopping. Each axle guard 92AG having a slope configuration is integrally formed in the vicinity of the first and second end portions.

  The brush element of the flapper brush 92 includes a plurality of cleaning segments formed of an elastic plastic material that is secured to and extends along the central member 92CM between the inner ends of each axle guard 92AG. A strip 92CS is provided (for the illustrated embodiment, the sleeve to be fitted and secured to the central member 92CM has an integral segment strip extending outwardly therefrom). When these cleaning segment strips 92CS are arranged in a herringbone pattern or a chevron pattern, an optimum cleaning effect (function) is obtained for the two-stage brush assembly 90 of the autonomous floor cleaning robot 10 according to the present invention. And noise level) were provided. Further, when the cleaning segment strip 92CS is arranged in a herringbone / chevron pattern, the large-sized dust captured by the strip 92CS is moved to the center of the flapper brush by the rotation of the flapper brush 92. Thus, it has been confirmed that cleaning strips arranged in a linear / straight pattern cause exciting flapping noise when the brush is rotated. In addition, the cleaning strips arranged in a spiral pattern moved large particulates toward each end of the brush, and dust was the result of leaving the sweeping action provided by the rotating brush.

  For the described embodiment, six cleaning segment strips 92CS were spaced equidistantly around the circumference of the central member 92CM in a herringbone / chevron pattern. One skilled in the art will appreciate that a greater or lesser number of cleaning segment strips 92CS may be employed in the flapper brush 90 without departing from the scope of the present invention. Each cleaning strip 92S is segmented at a predetermined interval. The segmentation interval depends on the configuration (interval) between the wires forming the partition frame 88. As a result of the embodiment of the partition frame 88 described above, each cleaning strip 92CS of the described embodiment of the flapper brush 92 has five segments.

  The main brush 94 comprises a central member 94CM having first and second straight ends (i.e. aligned along the centerline of the helix) (for the described embodiment, the central member 94CM is a round having a helical configuration. Shaped metal member). In combination with the central member 94CM, the segmented protection member 94PM is integrated. Each segment of the protective member 94PM includes a semi-circular end cap 94EC that is spaced apart to have an integral rib 94IR extending between the respective semi-circular end caps. For the described embodiment, each pair of semicircular end caps EC has two integral ribs extending between them. The protective member 94PM is assembled by joining the complementary end caps 94EC with any conventional means such as screws, such that the assembled complementary semi-circular end caps 94EC have a circular shape.

  Since the protective member 94PM is combined and integrated with the central member 94CM, the central member 94CM is disposed along the center line of the protective member 94PM, the first end of the central member 94CM terminates with one circular cap 94EC and The second end of the central member 94CM extends through the other circular end cap 94EC. The second end of the central member 94CM is attached to the deck 82 in a rotatable combination, and the circular end cap 94EC cooperating with the first end of the central member 94CM is connected to the electric motor via the transmission 48B. Designed and configured to be attached in a rotatable combination to the second output port 48BO2 of the transmission 48B so that rotation of the main brush 94 is provided by torque transmitted from 48.

  Each bristles 94B is combined with the central member 94CM and is set to extend between each integral rib 94IR of the protective member 94PM and beyond the OD established by each circular end cap 94EC. Each integral rib 94IR is configured and acts to prevent the main brush 94 from sucking objects such as rugs and tufted cloth.

  The bristles 94B of the main brush 94 can be made from any material customarily used to form bristles for surface cleaning operations. The bristles 94B of the main brush 94 are greatly swept by being specially configured to provide a "flicking" action with respect to dust encountered during the cleaning operation performed by the autonomous floor cleaning robot 10 according to the present invention. Provide ability. For the described embodiment, each bristles 94B has a diameter of about 0.010 inches, a length of about 0.90 inches, and a round free end. It has been confirmed that this shape provides an optimal tapping action. While bristles having a diameter of greater than about 0.314 millimeters (0.014 inches) have a longer wear life, such bristles may be too tough to provide a suitable tapping action with the two-stage brush assembly 90 of the present invention. Absent. Also, bristle diameters of less than 0.254 millimeters (0.010 inches) are subject to premature wear of the free ends of such bristles, reducing the sweep capability of the primary brush. In a preferred embodiment, the main brush is set slightly below the flapper brush to ensure that the flapper does not touch the hard surface floor.

  The vacuum assembly 100 is independently powered by the electric motor 46. By operating the vacuum assembly 100 independently of the self-adjustable brush assembly 90, a higher vacuum force can be used with battery power than is possible when the vacuum assembly is operated depending on the brush system. Can be produced and maintained. In another embodiment, the main brush motor may drive a vacuum. In this document, independent operation is used in that the inlet to the vacuum assembly 100 is an independent structural unit having dimensions that are independent of the “sweep area” defined by the two-stage brush assembly 90.

  The vacuum assembly 100, i.e. the rear vacuum source, placed immediately after the two-stage brush assembly 90 is oriented so that the vacuum inlet faces forward in the immediate vicinity of the main brush 94 of the two-stage brush assembly 90. Thus, the effectiveness of suction or evacuation of the vacuum assembly 100 is enhanced. Referring to FIGS. 13 and 14, the vacuum assembly 100 includes a vacuum inlet 102, a vacuum compartment 104, a compartment cover 106, a vacuum chamber 108, an impeller 110, and a vacuum channel 112. The vacuum inlet 102 includes first and second blades 102A, 102B formed of semi-rigid / elastic plastic or elastic material, but these blades are of a certain size (width and gap-see description below). Since constructed and arranged to provide the inlet 102, the vacuum assembly 100 reliably provides a constant air inflow rate that is about 4 m / sec for the described embodiment.

  The first blade 102A has a generally rectangular shape with a predetermined width (lateral) dimension such that each end of the first blade 102A extends beyond the lateral dimension of the two-stage brush assembly 90. One lateral edge of the first blade 102A is in close proximity to the main brush 94 in a substantially symmetrical orientation with the front-to-back diameter of the autonomous floor cleaning robot 10, but away from the brush and below the deck 82. Attached to the side surfaces (the lateral ridges formed in the deck 82 provide a separation between them in addition to embodying the retaining grooves for the partition frame 88 described above). This lateral edge also extends into the vacuum compartment 104 where it is in sealing engagement with the front edge of the vacuum compartment 104. The first blade 102A is angled forward with respect to the bottom surface of the deck 82 and has a length such that the free end 102AFE of the first blade 102A just rubs the surface to be cleaned.

  The free end 102AFE has a fortified shape that prevents the vacuum inlet 102 from pressing dust during the cleaning operation. A protrusion 102P having a predetermined height is aligned with the fortified segment 102CS of the free end 102AFE spaced apart along the width of the first blade 102A. For the given embodiment, the height of the protrusion 102P is about 2 mm. The predetermined height of the protrusion 102P defines a “gap” between the first and second blades 102A, 102B.

  Second blade 102B has a flat unitary configuration that is complementary in width and length to first blade 102A. However, the second blade 102B does not have a fortified free end, and instead the free end of the second blade 102B has a straight edge. The second blade 102B is joined in a sealing combination to the front edge of the compartment cover 106 and is angled with respect to the compartment cover 106 to be substantially parallel to the first blade 102A. When the section cover 106 is fitted into a predetermined position of the vacuum section 104, the flat surface of the second blade 102B comes into contact with the plurality of protrusions 102P of the first blade 102A, so that the first and second blades 102A and 102B are in contact with each other. A “gap” is formed in

  The vacuum compartment 104 in fluid communication with the vacuum inlet 102 includes a recess formed in the lower surface of the deck 82. This recess includes a compartment bottom plate 104F and a continuous compartment wall 104CW that draws the peripheral edge of the vacuum compartment 104. An opening 104A is formed through the bottom plate 104 and offset from one side of the bottom plate 104F. Because of the location of this aperture 104A offset from the geometric center of the compartment bottom plate 104F, it is advisable to form several guide ribs 104GR that project upward from the compartment bottom plate 104F. These guide ribs 104GR act to distribute the air flowing through the gap between the first and second blades 102A and 102B over the entire partition bottom plate 104, so that a constant air inflow is generated over the entire gap. And maintained, ie, the vacuum inlet 102 has a substantially constant 'negative' pressure (with respect to atmospheric pressure).

  The compartment cover 106 has a configuration complementary to the shape of the peripheral edge of the vacuum compartment 104. The cover 106 is further configured to be press-fit with a seal combination against the continuous compartment wall 104CW, where the vacuum compartment 104 and the vacuum cover 106 are combined to define the vacuum chamber 108 of the vacuum assembly 100. The compartment cover 106 can be removed to remove any debris from the vacuum channel 112. The compartment cover 106 is preferably made of a transparent or translucent plastic material so that the user can visually determine when clogging has occurred.

  The impeller 110 is mounted in combination with the deck 82 in such a manner that the inlet of the impeller 110 is located in the opening 104A. Since the impeller 110 is operatively connected to the electric motor 46, torque from the motor 46 is transmitted to the impeller 110, the impeller is rotated at a constant speed, and air is supplied from the vacuum chamber 108. Sucked. The discharge port of the impeller 110 is integrated with one end of the vacuum channel 112 by a seal combination.

  The vacuum channel 112 is a hollow structural member formed as a separate structure and attached to the deck 82 or formed as an integral part of the deck 82. The other end of the vacuum channel 110 is integrated with the vacuum inlet 86VI of the removable dust cartridge 86 by a seal combination. The outer surface of the vacuum channel 112 is complementary to the external shape of the curved arcuate member 86CAM of the removable dust cartridge 86.

  Various modifications and variations of the present invention are possible in light of the above teachings. For example, the preferred embodiment described above includes a self-adjusting cleaning head subsystem 80, i.e., deck 82 is automatic with respect to chassis 21 in response to a predetermined increase in brush torque of two-stage brush assembly 90 during an adjustment mode. Was able to pivot. Another embodiment of an autonomous floor cleaning robot according to the present invention is as described above, except that the cleaning head subsystem is not adjustable, i.e. the deck is not pivotable with respect to the chassis. This embodiment does not include the deck adjustment subassembly described above, i.e., the deck is rigidly secured to the chassis. Alternatively, the deck can be made as an integral part of the chassis, in which case the deck is a practical configuration, i.e. the identification of each component comprising the cleaning head subsystem and their combined integration to the robot. It is the structure which simplifies.

  It is therefore to be understood that within the scope of the appended claims, the invention may be practiced otherwise than as specifically described herein.

10 ... autonomous floor cleaning robot
20… Housing basic structure
21 ... Chassis
22 ... Cover
23 ... Bumper
23RSM… Rotatable support member
24 ... tip wheel assembly
25 ... Handle for transport
30 ... Power subsystem
34… Rechargeable battery pack
40 ... Drive subsystem
42A, 42B ... Wheel subassembly
42AAR ... Wheel rotation axis
42AM, 42BM… Motor
44… Electric motor
48 ... Motor
48B ... Transmission
48S ... Shaft
50 ... Subsystem
52 ... Control detection unit
60 ... Control module
60 ... Control line
72 ... Shaft
74 ... Hub
75 ... Plate
76 ... Brush means
78 ... Bristle
82MB… Mounting bracket
82PA ... pivot axis
82SW: Each side wall
84… Automatic deck adjustment subassembly
84 AM…Anchor material
84CS: Complementary cage stop
84MC… Cage
86 ... Detachable dust cartridge
86AJ ... Baffle protrusion
86BW… Rear wall member
86CAM: Curved arc member
86CM ... top plate
86FM… Bottom plate member
86LM ... Latch member
86OE… Open end
86RF ... replaceable filter
86VI… Vacuum intake
94PM ... Segmented protective member
94PM ... Protective member
100 ... Vacuum assembly

Claims (20)

An autonomous floor cleaning robot,
A housing and a chassis;
A plurality of wheels disposed at least partially within the housing and configured to move the robot on the floor, each coupled to the chassis via corresponding arms each having a tip and a proximal end; At least one motor for driving the plurality of wheels;
A controller disposed in the housing and controlling movement of the robot on the floor;
At least one sensor for detecting an obstacle and transmitting obstacle information to the controller so that the controller can control the robot so that the robot reacts to the obstacle;
A removable trash can disposed at least partially within the housing and configured to receive particles;
A first rotating member configured to direct particles to the waste container,
Each of the plurality of wheels is rotatably coupled to the tip of the corresponding arm, and the proximal end of the arm is rotatably coupled to the chassis;
The plurality of wheels are urged to an extended position away from the chassis by a spring extending between the arm and the chassis,
During cleaning, the weight of the robot overcomes the force of the spring that biases the plurality of wheels to the extended position, respectively.
Autonomous floor cleaning robot.   The autonomous floor cleaning robot according to claim 1, further comprising a second rotating member that cooperates with the first rotating member to direct particles toward the garbage container.   3. The autonomous floor cleaning robot according to claim 2, wherein the first rotating member is in contact with the floor surface and agitates particles toward the second rotating member.   The autonomous floor cleaning robot according to claim 3, wherein the second rotating member is arranged to receive particles from the first rotating member and direct the particles to the garbage container.   The autonomous floor cleaning according to any one of the preceding claims, further comprising an airflow generation system disposed at least partially within the housing and configured to suck particles and direct them toward the waste container. robot.   The autonomous floor cleaning robot according to claim 5, wherein the first rotating member cooperates with the airflow generation system to direct particles to the garbage container.   The autonomous floor cleaning robot according to claim 5 or 6, wherein air moved by the air flow generation system passes through a filter before being released from the housing. The at least one sensor includes a wheel lowering sensor that detects that one of the plurality of wheels has lowered to the extended position;
8. The control unit according to claim 1, wherein when the wheel lowering sensor detects that one of the plurality of wheels has decreased to the extended position, the control unit stops the movement of the robot on the floor surface. The autonomous floor cleaning robot according to claim 1.   The autonomous floor cleaning robot according to claim 1, wherein the first rotating member is a brush. An autonomous floor cleaning robot,
A housing and a chassis;
A first wheel and a first arm for coupling the first wheel to the chassis, a proximal end rotatably coupled to the chassis, and a tip to which the first wheel is rotatably coupled A first arm having;
A first elastic member that connects the first arm to the chassis and biases the tip of the first arm and the first wheel to an extended position;
A second wheel and a second arm for coupling the second wheel to the chassis, a proximal end rotatably coupled to the chassis, and a tip to which the second wheel is rotatably coupled A second arm having,
A second elastic member that connects the second arm to the chassis and biases the tip of the second arm and the second wheel to an extended position;
At least one motor disposed at least partially within the housing and driving the first wheel and the second wheel to move the robot on a floor surface;
A controller disposed in the housing and controlling movement of the robot on the floor;
At least one sensor for detecting an obstacle and transmitting obstacle information to the controller so that the controller can control the robot so that the robot reacts to the obstacle;
A removable trash can disposed at least partially within the housing and configured to receive particles;
A rotating brush configured to incite particles and move toward the trash container,
During cleaning, the weight of the robot overcomes the forces of the first elastic member and the second elastic member that bias the first wheel and the second wheel to the extended position;
Autonomous floor cleaning robot. The at least one sensor includes a wheel lowering sensor that detects that one of the first wheel and the second wheel is lowered to the extended position;
The control unit stops movement of the robot on the floor surface when the wheel lowering sensor detects that one of the first wheel and the second wheel is lowered to the extended position. 10. The autonomous floor cleaning robot according to 10.   12. The garbage container according to claim 10 or 11, wherein the garbage container is configured to receive particles directed to the garbage container by the rotating brush and the rotating member, and the particles move to the garbage container without passing through a filter. Autonomous floor cleaning robot.   The autonomous floor cleaning robot according to claim 12, wherein the rotating member is disposed at least partially in the housing and is disposed farther from the floor surface than the rotating brush.     14. The autonomous floor cleaning robot according to any one of claims 10 to 13, further comprising an airflow generation system disposed at least partially within the housing and configured to attract particles.   The autonomous floor cleaning robot according to claim 14, wherein the rotating brush cooperates with the airflow generation system to direct particles to the garbage container.   The autonomous floor cleaning robot according to claim 14 or 15, wherein the air moved by the airflow generation system passes through a filter before being released from the housing. A method of moving particles from the floor to a trash can,
The cleaning robot is moved on the floor surface by driving a wheel coupled to a cleaning robot chassis by a rotating arm and biased to an extended position by a spring extending between the arm and the chassis;
When the cleaning robot is in a use position, the weight of the cleaning robot is used to overcome the force of the spring that biases the wheel to the extended position;
Detecting obstacles,
Let the cleaning robot avoid the detected obstacle,
Instigate particles from the floor to the removable garbage container of the cleaning robot,
Directing the particles that have been agitated by generating a negative pressure to the garbage container,
A method of retaining the particles in the garbage container.   The method of claim 17, comprising filtering the air used to direct the particles carried by the air to the trash container after the particles are retained in the trash container.   Inciting the particles from the floor surface toward the garbage container means directing the particles at least partially to a rotating member disposed in the housing and rotating the rotating member to cause the particles to move to the garbage container. 19. A method according to claim 17 or 18, comprising directing to. Detecting the wheel drop when one of the wheels drops to the extended position;
The method according to any one of claims 17 to 19, further comprising stopping the movement of the cleaning robot on the floor surface when it is detected that one of the wheels has been lowered to the extended position.

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