JP6942102B2 - Self-propelled vacuum cleaner - Google Patents

Description

The present invention relates to a self-propelled vacuum cleaner, and more particularly to a self-propelled vacuum cleaner that removes dust by changing a traveling pattern when dust is found.

In recent years, there has been known a self-propelled vacuum cleaner that cleans the floor surface while autonomously avoiding obstacles while self-propelling in a predetermined traveling pattern.
For example, Patent Document 1 describes a self-propelled vacuum cleaner having an obstacle avoidance control mode in which the main body changes the moving direction of the main body when the obstacle detecting means detects an obstacle while the main body is moving. There is.

Further, Patent Document 2 describes a self-propelled vacuum cleaner that reduces the amount of dust left behind even when dust is solidified in a specific place in a room.
The self-propelled device of Patent Document 2 includes a dust detecting means for detecting dust on a floor surface, a traveling means for normally traveling in a predetermined traveling pattern, and a traveling control means for controlling the traveling direction of the traveling means. It is equipped with a distance measuring means for measuring the distance to an obstacle.
Further, when the dust detecting means detects dust on the cleaning surface, the self-propelled device carefully travels around the dust, and then changes the traveling pattern so as to return to the normal traveling.

Here, as the dust detecting means, a light emitting unit and a light receiving unit are installed in the middle of the suction means for sucking the dust on the surface to be cleaned, and the light output from the light emitting unit is blocked when the dust passes through the suction means. Those that detect the amount of dust by detecting that are described.

Japanese Unexamined Patent Publication No. 2002-078650 Japanese Unexamined Patent Publication No. 2004-243202

However, it is possible to remove the dust at the place where the dust is detected by going back and forth many times, but in the case of a vacuum cleaner with high suction power, it is not necessary to clean the same place many times.
In addition, since there is a high possibility that dust remains in the vicinity of the dust detection location, it may be preferable to expand the range of careful cleaning to some extent rather than limiting it to a specific location.

In normal driving, there is a pattern in which the vehicle travels randomly in the room, and a pattern in which the vehicle travels in the entire room while repeating straight-line driving and rotation. It may not be possible to efficiently remove locally existing dust.

When dust is detected, it is conceivable to perform spot operation in which cleaning is performed while turning spirally around the detection position and gradually increasing the radius of the circle.
However, in spot driving, it is difficult to determine how large the radius of the circle should be. For example, if the radius of the circle is gradually increased, it will eventually collide with obstacles such as desk legs and chairs existing in the room.

In the event of a collision, you will have to change direction to avoid the obstacle and continue driving after that, but the collision may cause a shift in the driving course, so it is better to return to the position where you started spot driving. difficult.
If you cannot return to the starting position of spot operation in this way, dust may be left behind or you may have to drive on the same route again, so it is not always possible to remove dust efficiently. Not exclusively.

Therefore, the present invention has been made in consideration of the above circumstances, and when dust is detected, spot operation for intensively removing the dust within a range that does not collide with the obstacle is performed to make the obstacle. An object of the present invention is to provide a self-propelled vacuum cleaner capable of returning to a position where dust is detected even in the event of a collision and continuing the subsequent running to perform efficient cleaning.

The self-propelled vacuum cleaner according to one aspect is determined to have dust in the normal running mode in which the vacuum cleaner moves in a predetermined running pattern and when it is determined that dust is present or there is a lot of dust. A self-propelled vacuum cleaner that collects dust while moving in a predetermined floor area including the initial spot position and its surroundings, and performs a spot driving mode starting from the initial spot position, unlike the normal driving mode. The housing, the traveling control unit for running the housing, the dust collecting unit for collecting dust on the floor surface, the dust detecting unit for detecting the presence or absence of dust on the floor surface, and the detected dust detecting unit. Based on the presence or absence of dust, a dust determination unit that determines whether or not a predetermined amount or more of dust is present on the floor surface, and if the dust determination unit determines that dust is present, the travel control unit determines that dust is present. The housing is provided with a control unit for moving the predetermined floor surface area in the traveling pattern of the spot traveling mode and collecting dust in the predetermined floor surface area by the dust collecting unit, and the predetermined size. When the floor surface area is a rectangular area and the spot travel mode is determined by the dust determination unit to have dust or a large amount of dust, the direction is substantially parallel to and opposite to the direction in which the dust has traveled in the rectangular area. return to direction by a predetermined distance, characterized in that it comprises the operation across the trajectory has been traveling in the rectangular region.

According to the present invention, the housing is moved so as to draw a traveling locus that changes the radius of the circle in the circular region in a predetermined direction, and after the movement in the predetermined direction is completed, the circle in the circular region is moved in the direction opposite to the predetermined direction. Since it is moved so as to draw a traveling locus that changes the radius, dust can be removed efficiently.

It is a block diagram of one Example of the self-propelled vacuum cleaner of this invention. It is a schematic perspective view of the self-propelled vacuum cleaner of this invention. It is explanatory drawing of Example 1 of the spot traveling mode of this invention. It is explanatory drawing of Example 2 of the spot traveling mode of this invention. It is explanatory drawing of Example 3 of the spot traveling mode of this invention. It is explanatory drawing of Example 4 of the spot traveling mode of this invention. It is a flowchart of 1st Example of the automatic running process of the self-propelled vacuum cleaner of this invention. It is a flowchart of the 2nd Example of the automatic running process of the self-propelled vacuum cleaner of this invention. It is a flowchart of 3rd Example of the automatic running process of the self-propelled vacuum cleaner of this invention.

Hereinafter, the best mode for carrying out the present invention will be described with reference to the drawings. It should be noted that this does not limit the invention.
<Structure of self-propelled vacuum cleaner>

FIG. 1 shows a block diagram of an embodiment of the self-propelled vacuum cleaner of the present invention.
In FIG. 1, the self-propelled vacuum cleaner of the present invention (hereinafter, also referred to as a vacuum cleaner or a cleaner) mainly has a control unit 11, a rechargeable battery 12, a failure detection unit 13, an angle detection unit 14, a dust detection unit 15, and dust. Judgment unit 16, distance measurement unit 17, guidance signal reception unit 18, spot maximum radius determination unit 19, charging stand connection unit 20, travel control unit 21, drive wheel 22, intake port 31, exhaust port 32, dust collection unit 33, It includes an input unit 34 and a storage unit 41.

In addition, the charging stand 100 is fixedly installed at a predetermined position such as a room to be cleaned. By connecting the charging stand 100 and the self-propelled vacuum cleaner 1, the self-propelled vacuum cleaner 1 receives power from the charging stand in contact with the charging stand 100, and the rechargeable battery of the self-propelled vacuum cleaner 1 is supplied. 12 is charged.
The self-propelled vacuum cleaner 1 of the present invention cleans the floor surface by sucking in air containing dust on the floor surface and exhausting the air from which the dust has been removed while self-propelling on the floor surface of the place where the dust is installed. It is a cleaning robot that does. The self-propelled vacuum cleaner 1 of the present invention has a function of autonomously returning to the charging stand when cleaning is completed.
In addition, it has a plurality of running patterns for cleaning the floor surface, and in particular, when a predetermined amount or more of dust is detected, the entire floor surface of a predetermined room is cleaned while focusing on the area around the detected position. Has a function to perform.

FIG. 2 shows a schematic perspective view of an embodiment of the self-propelled vacuum cleaner of the present invention.
In FIG. 2, the self-propelled vacuum cleaner 1 of the present invention includes a disk-shaped housing 2, and inside and outside the housing 2, a rotating brush, a side brush 10, a dust collector 33, an electric blower, and a plurality of them. The drive wheel 22, the fault detection unit 13, the guidance signal reception unit 18, and other components shown in FIG. 1 are provided.
In FIG. 2, the portion where the guidance signal receiving unit 18 is arranged is the front portion, the portion where the rear wheel of the driven wheel (not shown) is arranged is the rear portion, and the dust detecting portion 15 and the dust collecting portion 33 are inside the housing. The arranged part is called an intermediate part. The self-propelled vacuum cleaner 1 usually travels toward the front of the front portion.

The housing 2 has a circular bottom plate having an intake port 31 in a plan view, and a top plate 2b having a lid portion 3 in the center portion that opens and closes when the dust collecting portion 33 housed in the housing 2 is taken in and out. It includes a bottom plate and a side plate 2c having an annular shape in a plan view provided along the outer peripheral portion of the top plate 2b. Further, the bottom plate is formed with a pair of drive wheels and a plurality of holes for projecting the lower portions of the rear wheels from the inside of the housing 2 to the outside, and an exhaust port 32 is formed near the boundary between the front portion and the intermediate portion of the top plate 2b. Is formed. The side plate 2c is divided into two parts in the front and rear, and the front part of the side plate functions as a bumper.

In the self-propelled vacuum cleaner 1, a pair of drive wheels 22 rotate forward in the same direction to move forward, rotate in the same direction to move backward, and rotate in opposite directions to rotate in a stationary state. For example, when the vacuum cleaner 1 reaches the peripheral edge of the cleaning area or collides with an obstacle in the path, the drive wheels stop and the pair of drive wheels rotate in opposite directions to change the direction. As a result, the vacuum cleaner 1 self-propells over the entire installation location or the entire desired range while avoiding obstacles.

Further, the self-propelled vacuum cleaner 1 receives the guidance signal emitted from the guidance signal transmission unit 102 of the charging stand, and for example, when cleaning is completed, when the remaining charge of the rechargeable battery 12 is low, or When the set time of the set cleaning timer has elapsed, the vehicle automatically repeats linear running and rotation, or running on the wall in the direction of approaching the charging stand 100, and reaches the charging stand 100. Return.
However, if there is an obstacle, it moves in the direction of the charging stand 100 while avoiding it.

Hereinafter, each component shown in FIG. 1 will be described.
The control unit 11 of FIG. 1 is a part that controls the operation of each component of the vacuum cleaner 1, and is mainly realized by a microcomputer including a CPU, a ROM, a RAM, an I / O controller, a timer, and the like.
The CPU organically operates each hardware based on a control program stored in advance in a ROM or the like to execute the cleaning function, the running function, and the like of the present invention.
For example, as will be described later, when the dust determination unit 16 determines that dust is present, the control unit 11 spots the housing and a predetermined floor area including the spot initial position where dust is determined to be present. It is moved according to the traveling pattern of the traveling mode, and the dust collecting unit 33 collects dust in a predetermined floor surface area.

The rechargeable battery 12 is a portion that supplies electric power to each functional element of the vacuum cleaner 1, and is mainly a portion that supplies electric power for performing a cleaning function and traveling control. For example, a rechargeable battery such as a lithium ion battery, a nickel hydrogen battery, or a Ni-Cd battery is used.
The rechargeable battery 12 is charged with the vacuum cleaner 1 and the charging stand 100 connected to each other.
The vacuum cleaner 1 and the charging stand 100 are connected by bringing the exposed charging terminals, which are the connecting portions (20, 101), into contact with each other.
A battery level detection unit (not shown) is provided to detect the remaining capacity of the rechargeable battery (battery level), and based on the detected battery level (%), whether or not to return to the charging stand. You may decide whether or not to return.

The travel control unit 21 is a portion that controls the autonomous travel of the self-propelled vacuum cleaner 1, and automatically controls the rotation of the drive wheels 22 described above to perform linear travel and rotational operation. Run the housing. The drive wheel 22 is composed of a left wheel and a right wheel, and is driven by different drive motors to perform operations such as forward movement, backward movement, rotation, and stationary of the self-propelled vacuum cleaner 1.

In the present invention, it is assumed that there are mainly two types of driving modes, a normal driving mode and a spot driving mode.
The normal driving mode is a mode in which the vehicle moves in a predetermined indoor space while avoiding obstacles regardless of the presence or absence of dust and the amount of dust. Clean the entire room by using a zigzag running pattern that repeats running.

As will be described later, in the spot driving mode, when the dust determination unit 16 determines that dust is present or there is a large amount of dust, the spot driving mode includes the position where the dust is determined to be present and the periphery of the position. It is a mode to move the floor area of.
In the spot running mode, for example, the housing starts at a position where dust is determined to be present, and the radius of the circle around that position is gradually increased to draw a spiral running locus. Clean with a running pattern (spiral running pattern) that moves the.
In this spiral run, a circular area within a predetermined radius centered on a position where dust is present or dust is determined to be abundant is intensively cleaned.
The position where it is determined that the dust is present or the dust is abundant is called the spot initial position.

Alternatively, cleaning may be performed with a traveling pattern (rectangular traveling pattern) that moves within a predetermined rectangular region including the spot initial position starting from the spot initial position where it is determined that dust is present.
Examples of this spot running pattern are shown in FIGS. 3, 4, 5, and 6 which will be described later.
In addition, encoders (not shown) are provided on the left and right wheels of the drive wheels, respectively, and are self-propelled from a predetermined reference point (for example, the position of the charging stand) depending on the number of rotations, the direction of rotation, the rotation position, and the rotation speed of the wheels. The moving distance of the vacuum cleaner may be measured.

The obstacle detection unit 13 is a portion that detects an obstacle existing around the housing 2. For example, the self-propelled vacuum cleaner 1 comes into contact with or approaches an obstacle such as a desk or a chair in the room while traveling. Detect that. As the obstacle detection unit 13, for example, a contact sensor or an obstacle sensor including a microswitch, an ultrasonic sensor, an infrared distance measuring sensor, or the like is used, and is arranged at the front portion of the side plate 2C of the housing 2.
Further, since the step is also considered to be one of the obstacles, a cliff detection sensor for detecting the step may be provided as the obstacle detection unit 13.
The CPU recognizes the position where the obstacle exists based on the signal output from the obstacle detection unit 13. Based on the recognized position information of the obstacle, the direction to avoid the obstacle and the next direction to drive is determined.
Further, as will be described later, when the obstacle detection unit 13 detects an obstacle in a predetermined floor surface area while the housing is being moved in the spot travel mode, the travel control unit 21 moves the housing. , Return to the spot initial position.

The angle detection unit 14 is a so-called gyro sensor, which detects the angle of the self-propelled vacuum cleaner 1 in the traveling direction.
The angle from the reference direction is calculated based on the signal output from the gyro sensor 14. As a result, the direction of movement is detected.
For example, when turning 90 degrees to the left, while checking the state of the gyro sensor, control the drive motor so that it rotates 90 degrees to the left from the initial angle position, and keep the right wheel stationary. And the left wheel are rotated in opposite directions.
In addition, the gyro sensor 14 is also used for confirming the current position, correcting an error in movement control, and finely adjusting the posture.

The dust detection unit 15 is a part that detects the presence or absence of dust on the floor surface, and is mainly a part that detects dust contained in the air sucked from the intake port 31 of the self-propelled vacuum cleaner 1.
As the dust detection unit 15, for example, an optical sensor is used, and the dust detection unit 15 includes a light emitting unit and a light receiving unit which are arranged in the vicinity of the intake port 31 so as to sandwich the intake port 31. For example, an infrared light emitting diode is used as the light emitting unit, a phototransistor is used as the light receiving part, and when there is no dust, the infrared light output from the infrared light emitting diode is detected by the phototransistor. NS.
On the other hand, when dust is sucked into the intake port 31, the dust blocks the infrared light when the dust passes near the intake port, so that the infrared light is not received by the phototransistor.
Therefore, the passage (presence / absence) of dust can be detected depending on the presence / absence of infrared light received by the phototransistor.
From the phototransistor, a signal corresponding to the presence or absence of light reception of infrared light is given to the dust determination unit 16.

The dust determination unit 16 is a unit that determines whether or not a predetermined amount or more of dust is present on the floor surface or the amount of dust based on the presence or absence of dust detected by the dust detection unit 15.
For example, the amount of dust can be determined by counting the number of times that infrared light is not received per fixed time.
When the number of times that the infrared light is not received is considered as the dust detection number (GC), a predetermined value is stored in advance as the dust judgment value (Gmax) 47, and the dust detection number (GC) is determined. If it is equal to or higher than the dust judgment value (Gmax) (GC ≧ Gmax), the dust detection position is considered as a spot to be cleaned intensively, and it is judged that there is dust.
On the other hand, when the number of detected dust (GC) is smaller than the dust determination value (Gmax), that is, when GC <Gmax, it is determined that there is no dust.
The determination result of the dust determination unit 16 is used for determining whether to perform spot travel, stop spot travel, or perform normal travel, as will be described later.
For example, as will be described later, when the dust determination unit 16 determines that there is no dust when the housing is moved in the driving pattern of the spot driving mode, the spot driving mode is stopped and the housing is moved. , Return to the initial spot position.

The distance measuring unit 17 is a part that measures the distance from the current position of the housing 2 to the obstacle detected by the obstacle detecting unit 13. For example, the distance to the obstacle is measured by using the received signal of the ultrasonic wave output from the ultrasonic sensor and reflected by the obstacle.
Further, as will be described later, the distance to the obstacle detected by the distance measuring unit 17 is measured at the spot initial position where the dust determining unit 16 determines that dust is present.
Further, based on this measurement distance, a predetermined floor surface area for moving the housing in the traveling pattern of the spot traveling mode is set in a range that does not collide with the detected obstacle.

The induction signal receiving unit 18 is arranged in the front portion of the housing 2 and is a portion that receives a signal output from the induction signal transmitting unit 102 of the charging stand 100. The guidance signal is used for the return processing of the self-propelled vacuum cleaner and the connection processing to the charging stand, and for example, an infrared signal is used.
As will be described later, when the spot maximum radius determination unit 19 performs spiral travel while gradually increasing the radius of the circle with the spot initial position as the center of the circle in the spot travel mode, the maximum radius of the circle of the spiral travel is performed. Is the part that determines.
The maximum radius is calculated from the distance to the obstacle measured by the distance measuring unit 17.
For example, if the minimum distance from the housing to the obstacle is Lmin among several obstacles found, even if the self-propelled vacuum cleaner 1 approaches the obstacle by spiral running, the obstacle The maximum radius Rm is set to be shorter than the minimum distance Lmin to the obstacle so as not to come into contact with an object.

The charging stand connection unit 20 is a terminal for inputting electric power for charging the rechargeable battery 12.
By physically contacting the charging stand connection portion 20 with the vacuum cleaner connecting portion 101 of the charging stand 100, the electric power supplied from the power supply unit 104 of the charging stand 100 is supplied to the rechargeable battery 12 to charge the rechargeable battery 12.
The charging stand connection portion 20 is formed in a state of being exposed on the side surface of the vacuum cleaner 1 main body in order to make contact with the vacuum cleaner connection portion 101.
After returning to the vicinity of the charging stand 100, the self-propelled vacuum cleaner 1 uses the infrared rays received by the induction signal receiving unit 18 to bring the charging stand connecting portion 20 and the vacuum cleaner connecting portion 101 into contact with each other. , Perform connection processing.

The dust collecting unit 33 is a part that collects dust on the floor surface, and is a part that executes a cleaning function that collects dust and dirt taken in from the intake port 31. Mainly, it includes a dust collecting container (not shown), a filter portion, and a cover portion that covers the dust collecting container and the filter portion.
Further, it has an inflow path communicating with the intake port 31 and an discharge path communicating with the exhaust port 32, and guides the air sucked from the intake port 31 into the dust collection container via the inflow path, and after collecting dust. Air is discharged to the outside from the exhaust port 32 through the discharge path.
The intake port 31 and the exhaust port 32 are portions for sucking and exhausting air for cleaning, respectively, and are formed at the positions as described above.

The input unit 34 is a portion for the user to instruct and input the operation of the vacuum cleaner 1, and is provided on the surface of the housing of the vacuum cleaner 1 as an operation panel or an operation button.
Alternatively, as the input unit 34, a remote control unit is provided separately from the vacuum cleaner main body, and when the user presses an operation button provided on the remote control unit, infrared rays or radio wave signals are transmitted, and the input unit 34 operates by wireless communication. You may enter instructions.
As the input unit 34, a power switch, a start switch, a main power switch, a charge request switch, other switches (operation mode switch, timer switch) and the like are provided.
For example, when the charge request switch is pressed during automatic driving, it is determined that it is necessary to return to the charging stand, and the return process is executed.

The storage unit 41 is a part that stores information and programs necessary for realizing various functions of the self-propelled vacuum cleaner 1, and is a storage device such as a semiconductor storage element such as RAM or ROM, a hard disk, or SSD, and the like. Storage medium is used.
The storage unit 41 mainly stores the current position 42, the spot initial position 43, the maximum radius 44, the current radius 45, the measurement distance 46, the dust determination value 47, the distance determination value 48, and the like.

The current position 42 indicates the relative position of the self-propelled vacuum cleaner 1 from a predetermined reference point. For example, when the reference point is set as the position of the charging stand 100, the position of the charging stand is set to XY. As the origin (0,0) of the coordinates, the current position 42 is represented by an XY coordinate value.
The current position 42 can be calculated using, for example, the moving distance from the charging stand to the current position of the self-propelled vacuum cleaner after leaving the charging stand and the moving direction detected by the gyro sensor 14. can.
The spot initial position 43 indicates a position at which the spot travel mode is started, and is also represented by position coordinates relative to a reference point such as a charging stand.
The position where the spot travel mode is started is, for example, a position determined by the dust determination unit 16 to have dust. The spot initial position 43 is also the center point of the spiral running circle.

The maximum radius 44 is the maximum radius of a circular region centered on the initial spot position in the spot travel mode, and determines the size of the floor surface region for moving the housing. It also means the radius from the center point of the circle at the position where the spiral running ends when the spiral running is performed.
The current radius 45 means the radius from the center point of the circle at the current position of the housing during spiral traveling. In other words, the current radius 45 corresponds to the distance between the current position of the housing and the initial spot position. The center point of the circle corresponds to the spot initial position 43.

Assuming that the maximum radius 44 is Rm and the current radius 45 during spiral traveling is Ra, the current radius Ra gradually increases as the self-propelled vacuum cleaner 1 moves, but the current radius Ra becomes the maximum radius Rm. If, the spiral running in the spot running mode is stopped. When the spot running mode is canceled, the housing may be returned to the spot initial position.
The current radius 45 gradually changes as the spiral running progresses, but the maximum radius 44 is set to a preset fixed value.
As the maximum radius 44, an appropriate numerical value may be stored in the storage unit 41 as a fixed value at the time of shipment, but the user can change the setting of a numerical value that he / she considers appropriate for his / her own room to be cleaned. You may.

Further, as will be described later, before starting the spot driving mode, it is checked whether or not there is an obstacle around the initial spot position, and if, for example, a wall is detected as an obstacle, the distance measuring unit 17 measures the distance Ls to the wall, and based on the measured distance Ls, a predetermined floor surface area for moving the housing in the running pattern of the spot running mode is set to a range that does not collide with the detected wall. do. When the traveling pattern in the spot traveling mode is spiral traveling, a distance that does not collide with the wall is determined as the maximum radius Rm and stored in the storage unit 41.
For example, a numerical value smaller than the measurement distance Ls by about 1 cm is set as the maximum radius Rm.

The measurement distance 46 is a distance measured by the distance measuring unit 17, and mainly corresponds to a distance from the self-propelled vacuum cleaner 1 to an obstacle such as a wall or a chair.
The dust determination value 47 is a threshold value for the dust determination unit 16 to determine “with dust”.
As the dust determination value 47, a predetermined fixed value may be set at the time of shipment, but the setting may be changed depending on the material of the floor surface or the like.
As described above, for example, when the number of dust detected by the dust detection unit 15 is the dust determination value 47 or more, it is determined that there is dust, and when the number of dust detected is smaller than the dust determination value 47, "dust". It shall be judged as "none".

The distance determination value 48 is a threshold value for determining whether or not an obstacle exists near the current position of the housing. As described above, when the distance to the obstacle measured by the distance measuring unit 17 is smaller than the distance determination value 48 (measurement distance <distance determination value), it is determined that an obstacle exists nearby.
On the other hand, when the measurement distance ≥ the distance determination value, it is determined that the obstacle is not nearby.

The self-propelled vacuum cleaner 1 of the present invention may have other necessary configurations and functions in addition to the above configurations.
For example, a configuration (ion generator) that generates ions may be provided during cleaning or in a stationary state to sterilize or deodorize (or deodorize).
In addition, a timer switch is provided to set the time to execute the cleaning process, and when the timer switch is turned on (ON), counting of a preset time (for example, 60 minutes) is started and the set time is set. The cleaning process may be executed until the time has passed.
After this set time has elapsed, the cleaning process may be stopped and the device may automatically return to the charging stand.

<Charging stand configuration>
In FIG. 1, the charging stand 100 mainly includes a vacuum cleaner connection unit 101, an induction signal transmission unit 102, a control unit 103, and a power supply unit 104, and is connected to an outlet of a commercial power source 105 arranged on an indoor wall or the like. Receives AC AC power.
The power supply unit 104 is a portion that receives AC power from the commercial power source 105, converts it into DC power that can charge the vacuum cleaner 1, and gives it to the vacuum cleaner connection unit 101.

The guidance signal transmission unit 102 is, for example, a portion that transmits an infrared signal.
The control unit 103 of the charging stand 100 is a part that realizes various functions of the charging stand, and mainly performs transmission processing of infrared signals and supply control of charging power. The control unit 103 can be realized by a microcomputer including a CPU, a ROM, a RAM, an I / O controller, a timer, and the like.

<Explanation of spot driving pattern>
Below are some examples of spot driving patterns that are performed when dust is detected and it is determined that there is dust.
(Spot running pattern-Example 1)
FIG. 3 shows a schematic explanatory view of the first embodiment of the spot running pattern. Here, an example of a traveling locus in the case of spiral traveling is shown.
The "start S" in FIGS. 3 (a) and 3 (c) indicates the initial spot position of the self-propelled vacuum cleaner, and the "end E" in FIGS. 3 (b) and 3 (d) indicates the end position of the spot running. Shown. The end position of the spot run shall be the same as the initial spot position.
The “start S” corresponds to a position determined by the dust determination unit 16 to have dust.
The garbage collection operation is continued even during the spiral running.

3 (a) and 3 (b) show a case where there is no obstacle near the initial spot position where the spot running is started.
The positions of "Rm" in FIGS. 3 (a) and 3 (b) indicate the positions where the radius of the circle is gradually increased by the circular motion of the spiral running to reach the predetermined maximum radius Rm of the circle. ing.
The spiral running starts from the initial spot position indicated by the “start S” in FIG. 3A, and rotates counterclockwise while increasing the radius of the spiral circle at a predetermined rate of increase. However, the direction of rotation may be the same as that of the clock.
During the spiral running, the current radius Ra is always stored and compared with the maximum radius Rm stored in the storage unit 41.
Then, in the state where the current radius Ra <maximum radius Rm, the spiral running is advanced as it is, and when the current radius Ra matches the maximum radius Rm, the spiral running is temporarily stopped at that position. That is, the spiral running that increases the radius is stopped.
For example, if the maximum radius Rm = 1 meter is set, it means that the circular area having a radius of 1 m centered on the initial spot position has been intensively cleaned.

After that, as shown in FIG. 3B, the spiral running is restarted so as to return to the initial spot position while gradually reducing the radius of the circular motion from the position where the spiral running was stopped.
FIG. 3B shows a case where the spot is rotated counterclockwise to return to the initial spot position while reducing the radius, as in FIG. 3A.
However, at the stop position of the spiral running in FIG. 3A, the rotation may be performed by 180 degrees, and the trajectory of the spiral running shown in FIG. 3A may be traced in the reverse direction to return to the initial spot position.
As shown in FIG. 3B, after returning to the spot initial position, the normal driving mode may be restored so that the vehicle travels in the room in the traveling pattern defined as the normal traveling mode.

3 (c) and 3 (d) show an example of a traveling pattern when a pillar, which is an obstacle, is in the vicinity of the initial spot position and collides with the pillar during spiral traveling. Is shown.
In FIG. 3C, when the spiral running is performed in the same manner as in FIG. 3A, the obstacle detection unit 13 detects that the spiral has collided with the pillar before the current radius of the spiral matches the maximum radius Rm. Suppose you did.
At this time, the spiral running is temporarily stopped at the position where the collision is detected, and the rotation is reversed 180 degrees at that position.
After that, as shown in FIG. 3 (d), the trajectory of the spiral running shown in FIG. 3 (c) is traced in the reverse direction, and the initial spot position corresponding to the end position of the spiral is gradually reduced while the radius of the circle is gradually reduced. Return to.
In FIG. 3D, after returning to the spot initial position, the mode is switched to the normal traveling mode, and the cleaning process is continued in a predetermined traveling pattern.

After colliding with a pillar that is an obstacle, it is possible to avoid the position of the pillar and continue spiral running, but in this case, the shape of the spiral circle becomes a broken running pattern, and the initial spot position. It may take some time to return to, or it may be difficult to return to.
For example, if you continue to increase the radius of the circle after the collision, if you try to follow the spiral trajectory in the opposite direction after reaching the position of the maximum radius, you will collide with the pillar again and return to the initial spot position. It takes time.

Therefore, if the spiral collides with an obstacle before the current radius matches the maximum radius, it is considered that the intensive cleaning near the initial position of the spot where dust was detected has been completed, and the rest of the room to be cleaned is considered. In order to quickly clean the area, it is preferable to return to the initial spot position as soon as possible.

(Spot running pattern-Example 2)
FIG. 4 shows a schematic explanatory view of the second embodiment of the spot running pattern.
Here, an example of a traveling locus in the case where the area to be intensively cleaned is a rectangular area and the spot driving is performed while traveling in the rectangular area in a zigzag in the lateral direction is shown.
It is assumed that the position indicated by "S" in FIGS. 4A and 4B is the spot initial position, and the position indicated by "E" is the spot end position.
FIG. 4A shows a case where there is no obstacle in the rectangular area where the spot running is performed.
The rectangular area (vertical L1, horizontal W1) indicated by the broken line is defined as a predetermined spot running area.

In FIG. 4A, the initial spot position “S” is outside the rectangular area, but the initial spot position may be included in the rectangular area. Further, the dust detection position is assumed to be, for example, a central position in the rectangular region, and a position returned by a predetermined distance in the direction opposite to the traveling direction may be set as the initial spot position.
In the case of FIG. 4A, the spot initial position “S” is started, the vehicle travels according to the trajectory as shown in the figure, and the spot travel mode ends when the spot end position “E” is reached.
After that, it returns to the normal operation mode and continues cleaning in a predetermined running pattern from the spot end position.

FIG. 4B shows a case where there is a pillar that is an obstacle in the rectangular region where the spot running is performed, and the pillar collides with the pillar during the spot running.
In FIG. 4B, if it collides with a pillar while moving to the right, it temporarily stops at that position, rotates 180 degrees, and returns by a predetermined distance. Alternatively, the vehicle may move backward by a predetermined distance from the stopped position as it is.
As a predetermined distance to return, it is not possible to determine an appropriate distance, but for example, it is sufficient to return by a distance of about 10 or more cm so as not to hit the pillar again.
After that, the spot running is restarted from the returned position, and the running is performed while drawing a trajectory as shown in FIG. 4 (b).
Here, in consideration of the returned position, the rectangular region after restarting the spot running may have a width W2 smaller than the width W1 of the rectangular region of FIG. 4A (W1> W2).
That is, the rectangular area to be intensively cleaned may be changed so as not to collide with the pillar again.
In FIG. 4B, for example, after performing the second zigzag run, the spot end position “E” may be set at the point where the rectangular area is exited, and the spot run mode may be terminated at this point.
Further, as shown in FIG. 3D, the spot may return to the initial position after colliding with the pillar.

(Spot running pattern-Example 3)
FIG. 5 shows a schematic explanatory view of the third embodiment of the spot running pattern.
Here, the area to be intensively cleaned is a rectangular area, and the traveling locus when spot driving is performed while traveling in the rectangular area in a figure eight pattern is shown.
FIG. 5A shows a case where the vehicle starts from the spot initial position “S” determined in the same manner as in FIG. 4A and travels as if one figure 8 was drawn. Here, only a little inside of a predetermined rectangular area is cleaned.
Assuming that the vehicle did not collide with an obstacle when traveling in the figure 8 in FIG. 5 (a), as shown in FIG. 5 (b), the figure 8 pattern in FIG. 5 (a) is slightly outside. It runs on the trajectory indicated by the broken line of.
Assuming that there are no obstacles in the rectangular area, the spot running mode is terminated at the spot ending position "E" after traveling in the figure eight pattern as shown by the broken line.

On the other hand, FIGS. 5 (c), 5 (d), and 5 (e) show a case where there is a pillar which is an obstacle in the rectangular area.
As shown in FIG. 5C, it is assumed that there is a pillar on the path of the figure 8 running on the second lap at the lower right position of the rectangular area.
In this case, it is assumed that the vehicle collides with a pillar during the spot run, as shown in FIG. 5 (d).
When it is detected that it has collided with a pillar, it temporarily stops at that position and stops the spot running. For example, a running locus shown by a broken line as shown in FIG. 5 (e) is drawn, and the spot end position "E".
Proceed to.
Alternatively, if the spot end position cannot be set, the spot may return to the original spot initial position "S" from the position where the collision is detected.
After reaching the spot end position "E" or the spot initial position "S", the normal operation mode is returned and cleaning is continued in a predetermined running pattern.

If, as shown in FIG. 5 (d), after colliding with a pillar and further attempting to continue running in the figure eight pattern, the figure eight pattern collapses and the running pattern becomes complicated, so that spot operation is performed. It may be delayed to reach the end position "E" or the initial position "S", or it may not be possible to return to the initial position.
Therefore, as shown in FIG. 5 (e), when the vehicle collides with a pillar, it is better to end the spot driving mode and quickly return to the normal driving mode to avoid unnecessary driving and clean the entire room. Can be terminated early.

(Spot running pattern-Example 4)
FIG. 6 shows a schematic explanatory view of the fourth embodiment of the spot running pattern.
Here, after detecting dust at the initial spot position, the spiral running as shown in FIG. 3 is started. If it is determined that there is no dust in the dust detection and determination process during spiral running, the spiral running that increases the radius is temporarily stopped at the position where it is determined that there is no dust (position "A" in FIG. 6). After that, the traveling locus when returning to the original spot initial position by performing a spiral traveling to reduce the radius is shown.

In FIGS. 6 (a) and 6 (c), the spiral run was started in the counterclockwise direction from the initial spot position indicated by the “start S”, and then traveled to the position “A” determined to be free of dust. Shows the case.
FIG. 6B shows that the spiral running is continued in the same direction from the position “A”, and the radius is gradually reduced while returning to the end position “end E” corresponding to the spot initial position “start S”. Is shown.
Further, FIG. 6D shows a case where the vehicle temporarily stops at the position “A”, rotates 180 degrees, follows the trajectory of the spiral running in the opposite direction, and returns to the end position “end E”.
If the current radius at the position "A" determined to be dust-free is smaller than the maximum radius Rm, spot cleaning of the area outside the position "A" where the dust is expected to be small will be omitted. Intensive cleaning of the area near the initial spot position, which is considered to be dusty, can be efficiently performed, and the spot driving mode can be ended earlier.

<Automatic running process of self-propelled vacuum cleaner>
The flowcharts of three examples of the automatic running process of the self-propelled vacuum cleaner of the present invention are shown below.
In the following flowchart, the spot running mode is started after it is determined that there is dust, but the spot running mode will be described as performing spiral running with the spot initial position as the center of the circle. However, as shown in FIGS. 4 and 5, the vehicle may travel in a rectangular region.

(First Example of Automatic Driving Processing)
FIG. 7 shows a flowchart of the first embodiment of the automatic driving process of the present invention.
In FIG. 7, it is assumed that the self-propelled vacuum cleaner 1 is activated, and as shown in step S1, cleaning is currently performed in the automatic traveling pattern set by the normal traveling mode.
For example, suppose that the vehicle is running in a predetermined zigzag pattern.
In step S2, it is checked whether or not the dust detection unit 15 has detected dust.
For example, the number of garbage detected at regular intervals is counted.
In step S3, the dust determination unit 16 determines whether or not it should be determined that there is dust based on the result of dust detection.

For example, it is determined whether or not the number of detected dust is larger than the dust determination value 47 stored in the storage unit 41, and if the number of detected dust is equal to or greater than the dust determination value, it is determined that there is dust.
On the contrary, when the number of dust detected is less than the dust determination value, it is determined that there is no dust.
If it is determined that there is dust, the process proceeds to step S6, and if it is determined that there is no dust, the process proceeds to step S4.
In step S4, the control unit 11 checks whether or not the normal traveling mode should be terminated.
The case where the normal running mode should be terminated is, for example, a case where the remaining amount of the rechargeable battery becomes less than a predetermined value, or a case where a predetermined cleaning time has elapsed.

If the normal mode should be terminated, the process proceeds to step S5, otherwise the process returns to step S1.
In step S5, the return process to the charging stand is executed.
In the return process to the charging stand, for example, the guidance signal receiving unit 18 returns to a certain direction of the charging stand 100 while receiving the guidance signal output from the charging stand 100 and traveling in a straight line or on a wall. It is a process.
By returning to the vicinity of the charging stand 100 and bringing the vacuum cleaner connecting portion 101 into contact with the charging stand connecting portion 20, the process is completed after the charging is possible.

In step S6, the maximum radius 44 during spiral travel in the spot travel mode is read from the storage unit 41.
Here, the maximum radius 44 is a predetermined fixed value or a numerical value set and input by a user or the like.
In step S7, the position determined to have dust is stored in the storage unit 41 as the spot initial position 43.
Here, the stored position is, for example, relative position coordinates from a predetermined reference point (for example, a charging stand) calculated using a gyro sensor 14 or the like.
In step S8, the control unit 11 starts the spot running mode.
Here, the spiral running as shown in FIG. 3 is started. First, the initial value of the radius of the spiral circle is set to the current radius of 45 and stored in the storage unit 41.

In step S9, the control unit 11 causes the travel control unit 21 to spirally travel while gradually increasing the current radius 45 at a predetermined increase rate.
In step S10, the fault detection unit 13 checks whether or not the vehicle has collided with an obstacle.
If it is detected in step S11 that it has collided with an obstacle (for example, a wall), the process proceeds to step S16, and if not, the process proceeds to step S12.

In step S16, the traveling direction is reversed by 180 degrees to change the traveling direction.
That is, since it collided with an obstacle, it pauses, stops the spiral running that increases the radius, and prepares to return to the original spot initial position.
After that, the process proceeds to step S17.

In step S12, the distance measuring unit 17 measures the distance to an obstacle (for example, a wall) around the current position by using a signal acquired by an ultrasonic sensor which is one of the obstacle detecting units 13. ..
In step S13, the measurement distance is a predetermined distance determination value 48 stored in the storage unit 41.
If it is smaller than, the process proceeds to step S16, and if not, the process proceeds to step S14.
If the measured distance is less than the distance judgment value, it means that there is an obstacle nearby, and if the spiral running that increases the radius is continued as it is, there is a possibility of collision with the obstacle. It means that there is.
Therefore, if the vehicle has not actually collided with the obstacle but may collide with the obstacle in the near future, the process proceeds to step S16 in order to stop the spiral running.

In step S14, the current radius 45 at the current position of the spiral run is compared with the read maximum radius 44, and it is checked whether or not the current radius ≥ the maximum radius.
If the current radius ≥ the maximum radius, it is considered that the originally planned cleaning of the spiral area has already been completed, and the process proceeds to step S17.
On the other hand, when the current radius is less than the maximum radius, the process proceeds to step S15 in order to continue the spiral running.
In step S15, the radius of the spiral circle is increased at a predetermined rate of increase, and the current radius 45 is updated and stored in the storage unit 41.
After that, the process returns to step S9 and the spiral running is continued.

In step S17, the control unit 11 causes the spiral reverse traveling to be performed while reducing the radius of the spiral circle. As a result, the trajectory of the spiral running that has been running up to now is traced in reverse, and the spot returns to the initial position.
In step S18, the current position 42 is checked.
The current position 42 is calculated using the gyro sensor 14 or the like in the same manner as in step S7.
In step S19, the calculated current position 42 is compared with the spot initial position 42 stored in the storage unit 41, and it is checked whether or not the two are substantially the same.
When the positions of the two are substantially the same, the spot driving mode is ended and the process returns to step 1.
If the current position 42 has not yet returned to the spot initial position 43, the process proceeds to step S20.
In step S20, the radius of the spiral circle is reduced at a predetermined reduction rate, and then the process returns to step S17, and the spiral running is continued while reducing the radius.

By the above processing, when the spot running mode is started, the dust around the spot initial position is focused on by performing spiral running around the position determined to have dust (spot initial position). Can be removed.
In addition, if an obstacle is collided with or an obstacle is found in the vicinity during spiral running, the spiral running is stopped and the original spot initial position, which is the starting position of the spiral running, is returned. It is possible to quickly clean other areas of the room.

(Second Example of Automatic Driving Processing)
FIG. 8 shows a flowchart of the second embodiment of the automatic driving process of the present invention.
Here, unlike the first embodiment in which the maximum radius stored in the storage unit 41 is read out and used in advance, when it is determined that there is dust, the position where it is determined that there is dust before the spot running mode is started. The distance from (the initial spot position) to the obstacle is measured, and the maximum radius of spiral running is determined based on the measured distance to the obstacle.
In the flowchart of FIG. 8, the same reference numerals are given to the steps that perform the same processing as the steps of FIG. 7.

In FIG. 8, the processes of steps S1 to S5 are the same as those in FIG. 7, and when it is determined in step S3 that there is dust, the process proceeds to step S31.
In step S31, the distance measuring unit 17 measures the distance to a surrounding obstacle (for example, a wall) by using the signal acquired from the ultrasonic sensor of the obstacle detecting unit 13.
At this time, the distance to the obstacle is measured in all directions of 360 degrees around the position where it is determined that there is dust, and is stored in the storage unit 41. If there are multiple obstacles found, the minimum distance to those obstacles is stored.

In step S32, the spot maximum radius determination unit 19 determines and stores the maximum value (maximum radius 44) of the radius of the circle during spiral traveling by using the distance to the obstacle measured in step S31. It is stored in the part 41.
In order to avoid colliding with the found obstacle during spiral running, the maximum radius 44 is set to be shorter than the measured distance to the obstacle.
The standard for setting a numerical value as the maximum radius does not have to be limited to one standard, and any standard can be adopted.
For example, the maximum radius 44 may be set uniformly shorter than the measured distance by 1 cm. Alternatively, the maximum radius 44 may be set to a value that is 5% shorter than the measured distance.

After step S32, the processes from step S7 to step S20 are executed in the same manner as shown in FIG.
As a result, before entering the spot driving mode, the maximum radius of the spiral considering the distance to the obstacle is set in advance, the spiral traveling within the range that does not collide with the obstacle is performed, and the spiral traveling is performed without colliding with the obstacle. It is possible to quickly clean the area where dust exists, centering on the initial spot position.

(Third Example of Automatic Driving Processing)
FIG. 9 shows a flowchart of the third embodiment of the automatic driving process of the present invention.
Here, a dust detection process is executed during the spiral running, and if it is determined that there is no dust, the spiral running that increases the radius at that position is stopped, and the process of returning to the spot initial position will be described.
This flowchart corresponds to FIGS. 6 (c) and 6 (d).
In FIG. 9, instead of the processes of steps S10 to S13 of FIG. 7, the processes of steps S41 and S42 are executed.
Since the other steps are processed in the same manner as the steps in the flowchart shown in FIG. 7, the same reference numerals are given.

In FIG. 9, steps S1 to S9 are the same as the process of FIG. 7, and thus the description thereof will be omitted.
However, instead of step S6, steps S31 and S32 of FIG. 8 may be executed.
After starting the spiral running in step S9, the dust detection unit 15 performs a dust detection confirmation process in step S41.
The processing content of this step S41 may be the same as that of step S2.

In step S42, the dust determination unit 16 determines whether or not it can be determined that there is dust based on the number of detected dust.
The processing content of this step S42 may be the same as that of step S3.
If it is determined in the determination process of step S42 that there is dust, the process proceeds to step S14 in order to continue the spiral running.
On the other hand, if it is determined that there is no dust, it is considered that no further cleaning is necessary, and the process proceeds to step S16 in order to stop the spiral running.

Hereinafter, the processes from step S14 to step S20 are the same as those in FIG. 7.
According to this process, as shown in FIGS. 6 (c) and 6 (d), when it is determined that there is no dust during the spiral running, the cleaning of the spot running mode can be stopped, which is faster. After finishing the spiral running and returning to the initial spot position, cleaning can be performed in the normal running mode.

<Summary of Embodiment>
(Embodiment 1)
When it is determined by the dust determination unit that dust is present, the predetermined floor surface area including the initial spot position is intensively cleaned in the driving pattern of the spot traveling mode. As the traveling pattern of this spot traveling mode, any one of the following may be used.
(1-a) Spiral running A spiral running locus is drawn in which the floor area to be cleaned is circular, the initial spot position at the center of the circle is the starting position, and the radius of the circle in the circular area gradually increases. To move the housing.
(1-b) Running of rectangular area A rectangular area having a predetermined size including the initial spot position is set as a floor surface area to be cleaned, and the rectangular area is run in a zigzag manner. The zigzag running pattern may be random. Alternatively, the housing may be moved within the rectangular area so as to draw a figure eight.
(1-c) Other running The shape of the floor surface region is not limited to a circular shape or a rectangular shape, and may be another shape. Further, as the traveling pattern, for example, the housing may be moved in a zigzag pattern.

(Embodiment 2)
There are mainly the following three patterns as a method of canceling the spot driving mode.
(2-a) Collision detection When the housing is moved in the driving pattern of the spot traveling mode, if it actually collides with an obstacle, the spot traveling mode is stopped at the collision position.
(2-b) Judgment based on the distance to the obstacle When an obstacle is detected, the distance to the obstacle is measured, and when the measured distance becomes smaller than the predetermined distance judgment value, the position where the judgment is made. Then, the spot driving mode is stopped.
(2-c) Judgment by dust detection When it is determined that there is no dust when the housing is moved in the driving pattern of the spot driving mode, the spot driving mode is stopped at the position where the determination is made. Let me.
(2-d) Judgment based on traveling position When the housing reaches a predetermined position, for example, in spiral traveling, when the current radius reaches a position corresponding to the maximum radius, or a predetermined floor area. When the entire cleaning of the is moved to the position where it should be finished, the spot driving mode is stopped at that position.

(Embodiment 3)
(3-a) As the floor area to travel in the spot travel mode when it is determined that dust is present, the region of the preset travel pattern is used as it is, or a plurality of travel patterns are stored. If so, the user may be able to set the area of the traveling pattern to be used by using the input unit. For example, the user may set whether to perform spiral traveling or random traveling in a rectangular area.

(Embodiment 4)
(4-a) Regarding the size of the floor surface area traveled in the spot driving mode, the preset size is used as it is, or the size is used before the driving in the spot driving mode is actually started. May be set within a range that does not collide with obstacles. In order to set the range so that it does not collide with obstacles, the distance to the obstacle is measured in all directions while resting at the initial spot position, and only within the range shorter than the measured distance when viewed from the initial spot position. Set the floor area to run so that it moves.
(4-b) When traveling in a spiral, the maximum radius of the spiral is set based on the measured distance to an obstacle.
(4-c) When traveling in a rectangular area, the lengths of the vertical and horizontal sides of the rectangular area are set based on the measured distance to an obstacle.

(Embodiment 5)
If the spot driving mode is canceled, one of the following measures can be taken. (5-a) The spot returns to the initial spot position where the spot running mode was started, and the normal running mode is restarted from the spot initial position.
(5-b) The normal driving mode is restarted from the position where the spot driving mode is stopped.

(Embodiment 6)
Any of the following methods may be used as the dust detection method.
(6-a) A light emitting unit and a light receiving unit are provided in the vicinity of the intake port, and the presence or absence of dust is detected based on the presence or absence of light received by the light receiving unit. Visible light, infrared light, or the like may be used as the emitted light.
(6-b) In addition, a method of detecting the presence or absence of dust by increasing or decreasing the suction force is also conceivable.

(Embodiment 7)
As an obstacle detection method, any of the following methods may be used. However, it is preferable to use both (7-a) and (7-b).
(7-a) A micro switch interlocked with a bumper (front part of the side plate) provided on the side surface of the housing is provided, and when the micro switch comes into contact with an obstacle, the micro switch is pushed down to detect the collision with the obstacle. do.
(7-b) The distance to an obstacle is measured by an ultrasonic sensor, and when the measured distance is shorter than a predetermined distance determination value, it is determined that the obstacle has been detected.
(7-c) In addition, a step is detected by a cliff detection sensor.

11 Control unit, 12 Rechargeable battery, 13 Failure detection unit, 14 Angle detection unit, 15 Dust detection unit, 16 Dust determination unit, 17 Distance measurement unit, 18 Induction signal reception unit, 19
Spot maximum radius determination part, 20 Charging stand connection part, 21 Travel control part, 22 Drive wheel, 31 Intake port, 32 Exhaust port, 33 Dust collector, 34 Input part, 41 Storage part, 42 Current position, 43 Spot initial position , 44 maximum radius, 45 current radius, 46 measurement distance, 47 dust judgment value, 48 distance judgment value, 100 charging stand,
101 Vacuum cleaner connection, 102 Induction signal transmitter, 103 Control, 104 Power supply, 105 Commercial power supply

Claims (3)

A normal driving mode in which the vehicle moves according to a predetermined driving pattern, and when it is determined that dust is present or a large amount of dust is present, a predetermined spot including the initial spot position where dust is determined to be present and the surroundings of the spot is included. It is a self-propelled vacuum cleaner that collects dust while moving on the floor surface area of the vehicle and performs a spot traveling mode starting from the spot initial position, unlike the normal traveling mode.
With the housing
A traveling control unit for traveling the housing and
A dust collector that collects dust on the floor,
A dust detection unit that detects the presence or absence of dust on the floor surface,
A dust determination unit that determines whether or not a predetermined amount or more of dust is present on the floor surface based on the presence or absence of the detected dust.
When the dust determination unit determines that dust is present, the travel control unit moves the housing to the predetermined floor surface area in the travel pattern of the spot travel mode, and the dust collector unit moves the housing. It is equipped with a control unit that collects dust in a predetermined floor area.
The predetermined floor surface area is a rectangular area, and the predetermined floor surface area is a rectangular area.
The spot running mode, the present dust by dust determination unit, or if it is determined that there are many dust, the rectangular direction has been traveling in a region substantially parallel direction, and return in the opposite direction by a predetermined distance , A self-propelled vacuum cleaner comprising an operation of crossing a locus that has traveled in the rectangular region. The travel control unit is characterized in that, in the spot travel mode, the housing is moved so as to return in the opposite direction, and then the housing is moved so as to proceed in the direction in which the vehicle has traveled. Item 1. The self-propelled vacuum cleaner according to item 1. 1. Self-propelled vacuum cleaner described in.

Images