JP6581556B2 - Self-propelled vacuum cleaner - Google Patents

Description

  The present invention relates to a self-propelled electric vacuum cleaner.

  As a vacuum cleaner that cleans the floor where dust is falling, a so-called canister type in which the suction port reciprocates by a user's operation and a self-propelled vacuum cleaner that the vacuum cleaner itself drives autonomously are known. ing.

  Patent Document 1 discloses a rotary cleaning body having a tangle prevention blade 45 in order to reliably prevent dust such as lint and hair from getting entangled with a cleaning member of the rotary cleaning body (summary).

JP 2011-188951 A

  Japanese Patent Laid-Open No. 2004-228561 suppresses hair curling or the like on the rotating cleaning body, and does not disclose any configuration that suppresses hair entanglement or the like on the driven wheel that is driven to rotate.

The vacuum cleaner of the present invention made in view of the above circumstances is a self-propelled vacuum cleaner having two drive wheels, an electric blower, a rechargeable battery, and a brush having a rotating shaft in the horizontal direction. ,
The brush have a weight therein, the brush is a brush driven to rotate, characterized in that it has a separate brush for motor driving.

1 is a perspective view of a self-propelled electric vacuum cleaner according to Embodiment 1. FIG. It is a perspective view of the state where the upper case and dust case of the self-propelled electric vacuum cleaner concerning Embodiment 1 were removed. It is a bottom view of the self-propelled electric vacuum cleaner according to the first embodiment. It is AA sectional drawing of FIG. It is a perspective view of a suction mouth part, a dust sensor unit, and a dust case of a self-propelled electric vacuum cleaner concerning Embodiment 1. FIG. 3 is an exploded view of a suction part, a dust sensor unit, and a dust case of the self-propelled electric vacuum cleaner according to the first embodiment. It is a front view of the dust sensor unit of the self-propelled electric vacuum cleaner concerning Embodiment 1. It is a side view of the dust sensor unit of the self-propelled electric vacuum cleaner concerning Embodiment 1. It is CC sectional drawing of FIG. It is DD sectional drawing of FIG. It is a perspective view of the dust case in the self-propelled electric vacuum cleaner body according to the first embodiment. It is a perspective view including the area | region where a dust case is mounted | worn among the self-propelled electric vacuum cleaner main bodies which concern on Embodiment 1. FIG. It is a principal part enlarged view of FIG. It is BB sectional drawing of FIG. It is a perspective view containing the prop storage part and prop which concern on Embodiment 1. FIG. It is a back perspective view of the main body which attached the dust case which concerns on Embodiment 1. FIG. It is a perspective view of the self-propelled electric vacuum machine which removed the upper case concerning Embodiment 1. It is EE sectional drawing of FIG. 3 is a perspective view of a rotating brush according to Embodiment 1. FIG. 3 is an enlarged perspective view of an auxiliary wheel according to Embodiment 1. FIG. It is a disassembled perspective view of the state which removed the airtight member concerning Embodiment 1 from a main part. 3 is a rear perspective view of the airtight member according to Embodiment 1. FIG. It is a block diagram which shows the apparatus connected to the control apparatus of the self-propelled vacuum cleaner which concerns on Embodiment 1, and a control apparatus. It is a perspective view of the self-propelled electric vacuum cleaner which removed the upper case concerning Embodiment 2. It is a perspective view of the self-propelled electric vacuum machine which removed the switch sheet from the state of FIG. (A) which concerns on Embodiment 2 is a front perspective view of the switch sheet 22, (b) is a back surface perspective view of the switch sheet 22. FIG. It is a perspective view of the side brush which concerns on Embodiment 3. FIG. It is a side view when the side brush which concerns on Embodiment 3 is bent. It is the front perspective view which saw through the lid | cover and filter of the dust case which concern on Embodiment 3. FIG.

  Embodiments of the present invention will be described in detail with reference to the accompanying drawings. Similar components are denoted by the same reference numerals, and the same description will not be repeated. The various components of the present invention do not necessarily need to be composed of one member. For example, one component is composed of a plurality of members, and a plurality of components are composed of one member. , A part of a certain component and a part of another component are allowed to overlap each other.

  Of the directions in which the self-propelled vacuum cleaner 1 (see FIG. 1) travels, the direction in which the self-propelled vacuum cleaner 1 normally travels is forward, the direction opposite to the direction of gravity is upward, and the drive wheels 116 (FIG. 3) are the left and right directions. That is, as shown in FIG. In the present embodiment, a side brush 15 is attached to the front side of the self-propelled electric vacuum cleaner 1.

<Embodiment 1>
[Self-propelled vacuum cleaner 1]
FIG. 1 is a perspective view of a self-propelled electric vacuum cleaner 1 according to the present embodiment.
The self-propelled electric vacuum cleaner 1 is a vacuum cleaner that cleans while moving autonomously in a cleaning area (for example, a room). The self-propelled vacuum cleaner 1 includes an upper case 111 that is an upper wall (and some side walls), a lower case 112 that is a bottom wall (and some side walls), and a bumper 18 that is installed at the front. The main body 11 comprised is provided. In the upper case 111, a switch sheet 22 and a circular operation button 221 and an annular operation button 222 as operation buttons for giving a command to the control unit 2 of the self-propelled electric vacuum cleaner 1 are arranged.

  A dust case 4 is provided on the upper rear side of the self-propelled electric vacuum cleaner 1. The self-propelled electric vacuum cleaner 1 of the present embodiment autonomously drives and cleans the drive wheels 116 by the arithmetic processing of the control device 2, but may be driven by receiving a user's command from a remote controller or the like.

[Lower case 112]
2 is a perspective view with the upper case 111 and the dust case 4 removed, FIG. 3 is a bottom view of the self-propelled vacuum cleaner 1, and FIG. 4 is a cross-sectional view taken along line AA in FIG. 5 is a perspective view of the suction port 113, the dust sensor unit 12, and the dust case 4.
The lower case 112 includes a drive mechanism housing portion 114 that houses a drive mechanism including a drive wheel 116, a travel motor 1161, an arm 1141, and a speed reduction mechanism 1142, a side brush attachment portion 1121, a travel motor 1161, and a rotation. The brush motor 1133, the electric blower 16, the rechargeable battery 19, a battery accommodating portion 115 (see FIG. 4) that accommodates the rechargeable battery 19, the control device 2, and the suction port 113 are thin disk members. .

  The lower case 112 includes a bumper frame 1127 provided on the entire side surface or substantially the entire periphery including the lower end side of the side surface, preferably the lower end. The bumper frame 1127 is formed of a material softer than members forming other portions of the side surface, and for example, a resin material such as an elastomer can be employed. Further, the bumper frame 1127 protrudes to the outer peripheral side of the other part of the side surface, for example, the bumper 18. Thereby, even if self-propelled vacuum cleaner 1 collides with furniture etc., it can control that furniture etc. are damaged.

  In addition, since the self-propelled vacuum cleaner 1 mainly moves forward, the side surface on the front side is likely to collide with furniture or the like. It is preferable to provide a bumper frame 1127. Since the bumper 18 is annular, the bumper frame 1127 can be positioned on the outer peripheral side of the bumper 18 by forming the bumper frame 1127 in an annular shape as in this embodiment. If it carries out like this, since the bumper 18 can be pressed from an outer peripheral side, it will be easy to assemble.

(Balance of self-propelled vacuum cleaner 1)
Among the members provided in the main body 11, those that are relatively heavy are the rechargeable battery 19 and the electric blower 16. The rechargeable battery 19 is often heavier than the electric blower 16. In order to balance the weight of the main body 11 of the present embodiment, first, the electric blower 16 is provided in the approximate center of the lower case 112, and the rechargeable battery 19 is provided on the front side.

  Here, on the rear side of the center of the lower case 112, a suction port 113 that houses the rotating brush 14 and a scraping brush 13 are provided. Since the electric blower 16 is on the center side (between the two drive wheels 116) and the rechargeable battery 19 is on the front side, it is preferable to balance by placing heavy objects on the rear side. For this reason, in this embodiment, a weight is fixed to the inner periphery of the scraping brush 13 by sticking or the like (not shown). Thereby, the dead space in the scraping brush 13 can be utilized effectively. In this embodiment, since the scraping brush 13 is on the side farther from the center than the rotating brush 14, it is preferable to provide a weight here. Further, it is preferable that the weight is provided on the center side in the left-right direction of the main body 11 from the viewpoint of the left-right balance. Although a weight may be provided in the rotating brush 14, the rotating brush 14 is a brush driven by the rotating brush motor 1133, and thus providing a weight causes a load on the motor. For this reason, it is preferable to provide a weight in the scraping brush 13 that rotates without being driven by a motor. Moreover, it is preferable that the center of gravity of the self-propelled electric vacuum cleaner 1 is approximately centered in the front-rear direction (substantially coincides with the axis of the drive wheel 116) by weight.

(Projection of lower case 112)
With respect to the lower case 112, at least a part of a rear protrusion 1123 that is a convex portion provided on the bottom surface of the lower case 112 is provided on each of the outer sides of the rotating brush 14 in the left-right direction (the right outer side and the right outer side). At least a part of each of the rear protrusions 1123 is also located just behind the drive wheels 116.

  A central front protrusion 1124 and a central rear protrusion 1125 are provided in the central region of the lower case 112, which corresponds to the region between the two drive wheels 116. The center front projection 1124 is a convex portion located on the front end side of the drive wheel 116 in the front-rear direction and on the center side of the lower case 112 in the left-right direction. The central rear projection 1125 is a convex portion that extends rearward from the central front projection 1124 and extends in the front-rear direction.

  In the self-propelled electric vacuum cleaner 1 of the present embodiment, the rear end of the drive wheel 116 and the outer end of the rotating brush 14 are close to each other. Specifically, the distance from the left and right inner portions of the rear end of the drive wheel 116 to the left and right outer portions of the front end of the rotating brush 14 is set to 20 mm or less, for example, from the viewpoint of miniaturization. The rotary brush 14 and / or an airtight member 118 described later protrudes from the lower case 112 in order to make it easier to suck dust near the floor surface, and the drive wheels 116 protrude in the same manner to contact the floor surface. . Therefore, there is an obstacle in the area between the two drive wheels 116 (the central area where the protrusions 1124 and 1125 are provided) and the area behind the drive wheels 116 (the area where the protrusions 1123 are provided). If it gets in, it may fit between the drive wheel 116 and the rotating brush 14, and may prevent the self-propelled vacuum cleaner 1 from being driven. In order to suppress such a situation, the protrusion 1123, the protrusion 1124, and the protrusion 1125 are provided. Any of the protrusions 1123, 1124, and 1125 is a protrusion that is adjusted to a dimension that is separated from the floor surface while the self-propelled vacuum cleaner 1 is traveling on at least a flat floor surface.

[Driving mechanism accommodating portion 114]
The drive mechanism housed in the drive mechanism housing portion 114 shown in FIG. 3 and the like is a mechanism that supports the drive wheel 116 on the main body 11. The drive mechanism includes a travel motor 1161, an arm 1141 that supports the drive wheels 116 from the left and right inner sides, and a speed reduction mechanism 1142. The arm 1141 is provided between the two drive wheels 116, and is a member having one end extending in the front-rear direction and the other end connected to the drive wheel 116. This is a member that can rotate each of the drive wheels 116. Each of the rotation shafts is located between the two drive wheels 116, particularly in the present embodiment, between each of the drive wheels 116 and the central protrusion 1124 and the protrusion 1125.

[Battery housing 115]
As shown in FIG. 4 and the like, the battery accommodating portion 115 is a space for accommodating the rechargeable battery 19 therein, and is located on the front side of the center of the lower case 112. The battery housing portion 115 is configured to have a downward opening in order to replace the rechargeable battery 19. Note that side brush attachment portions 1121 for attaching the side brush 15 are formed on the left and right sides of the battery housing portion 115.

[Driving wheel 116]
As shown in FIG. 3 and the like, each of the driving wheels 116 is a member that receives the driving force of each of the traveling motors 1161 via each of the speed reduction mechanisms 1142. As a result, the drive wheel 116 itself rotates, so that the main body 11 can be moved forward, backward, and turned. The drive wheels 116 are arranged on both the left and right sides.

[Front lid 117]
As shown in FIG. 3 and the like, the front lid 117 is a substantially rectangular plate-like member that closes the opening of the battery housing portion 115 (see FIG. 4) formed on the front end side of the lower case 112 from the lower surface of the lower case 112. Further, the front lid 117 includes a circular auxiliary wheel attachment portion 1122 for attaching the auxiliary wheel 17 near the center side of the lower case 112.

[Auxiliary wheel 17]
FIG. 20 is an enlarged perspective view of the auxiliary wheel 17. As shown in FIGS. 3 and 20, the auxiliary wheel 17 is an auxiliary wheel for smoothly moving the self-propelled electric vacuum cleaner 1 while separating the lower case 112 from the floor surface. Is provided. The auxiliary wheel 17 is supported by a fixed shaft 173 so as to be driven and rotated by frictional force generated between the auxiliary wheel 17 and the floor surface as the main body 11 is moved by the driving wheel 116.

  The auxiliary wheel 17 includes a substantially circular grounding wheel 171, a disc portion 172, and a small disc portion 174 that are rotatably provided with a fixed shaft 173 as a rotation axis. The grounding wheel 171 rotates in contact with the floor surface as the self-propelled vacuum cleaner 1 travels. The small disc portion 174 is adjacent to the grounding wheel 171, has a smaller diameter than the grounding wheel 171 and a larger diameter than the fixed shaft 173, and can rotate around the fixed shaft 173. The disc portion 172 is adjacent to the small disc portion 174, has a smaller diameter than the ground ring 171 and a larger diameter than the small disc portion 174, and can rotate around the fixed shaft 173.

  When hair dust or the like adheres to the grounding wheel 171 as the grounding wheel 171 rotates, the hair dust or the like may turn around the fixed shaft 173 and become entangled with the fixed shaft 173. At this time, since the small disk part 174 and the disk part 172 are adjacent to the ground ring 171, hair dust or the like is easily entangled with the disk part 172 instead of the fixed shaft 173. For this reason, by removing the disk portion 172 around the fixed shaft 173, it is possible to remove hair dust relatively easily. The small disk portion 174 and the disk portion 172 are preferably formed integrally.

Further, the auxiliary wheel 17 is configured such that its orientation is freely rotatable by 360 ° in the horizontal direction. The auxiliary wheel 17 shown in FIG. 3 is provided at the center in the left-right direction in front of the main body 11 and is attached to the auxiliary wheel attachment portion 1122.
The grounding ring 17 may be replaced with a driven roller 1186 described later, and the airtight member 118 may be provided with the same configuration as the disc portion 172.

[Bumper 18]
The bumper 18 is installed so as to be movable in the front-rear direction, preferably further in the left-right direction, according to the pressing force acting from the outside. The bumper 18 is urged forward by a pair of left and right bumper springs (not shown). When a drag force from an obstacle acts on the bumper spring via the bumper 18, the bumper spring is deformed, and the bumper 18 is allowed to move backward while urging the bumper 18 forward. When the bumper 18 moves away from the obstacle and loses the drag, the bumper 18 returns to its original position by the biasing force of the bumper spring. Incidentally, the backward movement of the bumper 18 (that is, contact with an obstacle) is detected by a bumper sensor (infrared sensor), and the detection result is input to the control device 2. Since the amount of displacement of the bumper 18 varies depending on the contact position of the obstacle or the like, it is also possible to detect the position of the obstacle or the like with respect to the main body 11.

[Scraping brush 13]
The scraping brush 13 is a brush having a flock on a part or almost the entire surface thereof and having an axis in a direction substantially parallel to a rotating brush 14 described later. In this embodiment, the scraping brush 13 is driven to rotate or rotate by contact with the floor surface. To do. In the case of rotation, the rotation range is regulated by providing a stopper or the like. When cleaning the flooring (between the plates), the tip of the scraping brush 13 is preferably spaced from the floor by about 0.5 mm. Moreover, it is preferable that the position of the flocking of the scraping brush 13 overlaps with the hair of the carpet when cleaning the carpet. For this reason, the scraping brush 13 can collect | recover so that dust may be scraped off from the carpet surface.

  When the scraping brush 13 is used in such a manner that it is provided with a stopper and is rotated, a predetermined area can be kept in contact with the floor surface and dust can be scraped off. At this time, it is preferable that the area | region which will keep contacting a floor surface among scraping brush 13 is a flat shape. That is, the shape of the scraping brush 13 is a shape obtained by replacing a part of the cylindrical shape with a flat plane as viewed in the axial direction (for example, a shape obtained by cutting a part of a circle with a string or a substantially half-moon shape). Preferably there is.

[Rotating brush 14]
FIG. 19 is a perspective view of the rotating brush 14. The rotating brush 14 is disposed substantially parallel to an axis (left-right direction) passing through the rotation center of the drive wheel 116 (see FIG. 3). The rotary brush 14 has a cylindrical shape having a rotation axis in the horizontal direction (left and right direction in the present embodiment), and is rotatably supported by the suction port 113. The rotating brush 14 is driven to rotate by receiving a driving force from a rotating brush motor 1133 (see FIG. 2). The rotating brush 14 includes a plurality of flocks 142 that protrude in the normal direction from the outer peripheral surface of the shaft portion 141. The flocking 142 of the rotating brush 14 includes a plurality of types of flocking such as flocking with different lengths and flocking with different hardness, and each flocking is arranged in a row in a spiral manner with respect to the rotation axis (see FIG. 19).

  A non-woven fabric 143 is provided adjacent to part or all of the flocked 142. Each non-woven fabric 143 shares the root with respect to each hair transplant 142. This can be realized, for example, by fusing the flocked hair 142 and the nonwoven fabric 143 with ultrasonic waves so that the flocked hair 142 and the nonwoven fabric 143 are integrated. As the flocking, one having a certain degree of hardness is desirable. For example, nylon can be adopted.

  Further, in the present embodiment, the non-woven fabric 143 adjacent to the hair transplantation 142, for example, in the present embodiment, each of the hair transplantation 142 and the non-woven fabric 143 sharing the root is non-woven fabric before the hair transplantation 142 when the rotary brush 14 is rotated by the rotary brush motor 1133. 143 is arrange | positioned so that a floor surface may be contacted. Thereby, since the hair dust etc. which exist on a floor surface contact the nonwoven fabric 143 previously, it is suppressed that the hair transplantation 142 is entangled. In addition, the nonwoven fabric 143 is provided with one or more slits 1431 extending in the radial direction. Thereby, the twist of a nonwoven fabric can be suppressed.

  In addition, the structure which arrange | positions the braid | blade member which consists of elastic materials, such as rubber | gum, between the flocks 142 arrange | positioned helically may be added, and it can change suitably. The dust picked up by the rotating brush 14 passes through the opening 17 and is stored in the dust case 4. Moreover, in order to suppress that the flock 142, the nonwoven fabric 143, or a braid | blade member contacts the bridge | crosslinking part 1181 of the airtight member 118 mentioned later, you may shorten the length of some of these, or provide a notch.

[Airtight member 118]
FIG. 21 is an exploded perspective view of the airtight member 118 removed from the main body 11, and FIG. 22 is a rear perspective view of the airtight member 118.
An airtight member 118 is attached to a portion located below the rotary brush 14. The airtight member 118 includes, in a bottom view of the self-propelled electric vacuum cleaner 1, a bridging portion 1181 provided in a region below the rotary brush 14 in the front-rear direction, a swing shaft 1182 extending in the left-right direction, and the rotary brush 14. A frame body portion 1183 that surrounds the airtight member 118, a removal claw 1184 used when removing the airtight member 118, a bridging portion 1181 and a biasing portion 1185 that biases the frame body portion 1183 downward, and a driven roller 1186.

  The airtight member 118 is a member that swings separately from the suction port 113 and the rotating brush 14, and is urged downward by the urging unit 1185. For this reason, the airtight member 118 moves up and down with the traveling of the steps of the self-propelled vacuum cleaner 1. Thereby, since the position which the airtight member 118 adjoined or contacted the floor surface is maintained, airtightness can be improved. Further, since the airtight member 118 swings separately from the suction port 113 and the rotating brush 14, it is not necessary to provide a swinging space for the suction port 113 in the main body 11, which contributes to downsizing of the main body 11.

  The swing shaft 1182 of this embodiment is provided coaxially with the scraping brush 13, and the scraping brush 13 can be attached to the swing shaft 1182. Thereby, when providing both the airtight member 118 and the scraping brush 13, since an installation space can be reduced, it contributes to size reduction of the self-propelled electric vacuum cleaner 1. FIG. The swing shaft 118 is provided on the rear end side of the airtight member 118.

  The swing shaft 118 may be provided on the front end side of the airtight member 118. In this way, the airtight member 118 has an upward inclination as it goes from the rear to the front, so that it is possible to reduce the load when it collides with an obstacle ahead. Moreover, the front end of the airtight member 118 forms an inclined portion 1187 that goes downward as it goes from the front to the rear (see FIG. 4 and the like). For this reason, the load at the time of colliding with the front obstacle can further be reduced.

  The removal claw 1184 is attached to the left and right sides of the airtight member 118, and the removal claw 1184 can be detached from the main body 11 by moving in the left-right direction (in this embodiment, inward in the left-right direction). . Since the self-propelled vacuum cleaner 1 mainly moves in the front-rear direction, it can be removed by moving in the left-right direction in this way, so that the airtight member 118 can be prevented from dropping from the main body 11 during travel. .

  The urging portion 1185 is provided on the back surface side of the airtight member 118, and is, for example, a spring-like member that can urge the frame body portion 1183 or the vicinity thereof downward. The airtight member 118 is urged by the urging unit 1185 so as to come into contact with the floor surface while the self-propelled vacuum cleaner 1 is traveling. Thereby, since airtightness around the rotating brush 14 can be improved, dust collection efficiency can be improved.

  The driven rollers 1186 are respectively provided on the left and right outer portions of the airtight member 118, and can contact the floor surface and support the airtight member 118 as the self-propelled electric vacuum cleaner 1 travels. Thereby, even if the airtight member 118 is urged downward, frictional resistance with the floor surface can be suppressed, and energy loss and damage to the floor surface can be suppressed. Further, since the driven roller 1186 is positioned on the opposite side of the auxiliary wheel 17 via the driving wheel 116 in the front-rear direction, the self-propelled vacuum cleaner 1 is effectively supported by these three components. Can do.

[Side brush 15]
The side brush 15 illustrated in FIG. 3 and the like is a brush that is outside the main body 11 such as a corner of a room and guides dust to a suction port 113 (suction port 1131) where it is not easy to reach the rotary brush 14. It is. The rotation axis of the side brush 15 is vertical, and a part of the side brush 15 is exposed from the main body 11 in plan view. The side brush 15 has three bundles of brushes that extend radially at 120 ° intervals in plan view, and is disposed on each of the front left and right sides of the lower case 112. The base of the side brush 15 is fixed to the side brush holder 151.

  Each brush of the side brush 15 is a brush portion 154 whose side brush holder 151 side (base side) is a base elastic portion 153 having flexibility such as elastomer, and whose tip side is a brush, for example. In this embodiment, the side brush holder 151 and the root elastic part 153 that form the rotation shaft (hub) of the side brush 15 are integrally formed. By making the base of the side brush 15 an elastic body such as the base elastic portion 153, the brush portion 154 is less likely to bend the brush portion 154 than the configuration in which the brush portion 154 extends from the root to the tip. The durability of can be improved.

  The flocks of the side brush 15 are inclined so as to approach the floor surface toward the tip, and the vicinity of the tip is in contact with the floor surface.

  The side brush holder 151 is installed near the bottom surface of the lower case 112 and is connected to the side brush motor 152 (see FIG. 2). When the side brush motor 152 is driven, the side brush 15 rotates inward (in the direction of the arrow attached to FIG. 3), and dust is collected in the suction port 1131.

[Electric blower 16]
The electric blower 16 shown in FIG. 4 has a fan having a shaft in the front-rear direction, and when the fan is driven to rotate, the air in the dust case 4 is discharged to the outside to generate a negative pressure. It has a function of sucking dust through 1131 (suction port 113). An elastic body 161 is installed on the outer peripheral surface of the electric blower 16. By interposing the elastic body in this manner, the vibration of the electric blower 16 is attenuated and hardly transmitted to the main body 11, and the vibration and noise of the main body 11 can be reduced. In the present embodiment, the electric blower 16 is disposed near the center of the lower case 112.

[Mouthpiece 113]
6 is an exploded perspective view of the suction port 113, the dust sensor unit 12, and the dust case 4, FIG. 7 is a front view of the dust sensor unit 12, and FIG. 8 is a right side view of the dust sensor unit 12.
The suction port 113 is a member in which a suction port 1131 communicating with the dust case 4 is formed and the scraping brush 13 and the rotating brush 14 are accommodated. A rotary brush motor 1133 may be attached to the suction port 113. The upstream side of the suction port 1131 (the rotary brush 14 side) is a space for storing the rotary brush 14 and has a larger cross-sectional area than the suction port 1131.

  In the present embodiment, the air sucked by the negative pressure of the electric blower 16 includes the suction port 1131, the dust sensor unit 12, the duct 42 and the main accumulation chamber 41 of the dust case 4, the dust collection filter 46, the electric blower 16, and And the exhaust port 1126 in this order. The air often contains dust and is blocked by the dust collection filter 46 and stored in the dust case 4. Hereinafter, a direction substantially perpendicular to the suction port 1131 and the frame 121 of the dust sensor unit 12 (a front view direction of the frame 121) is referred to as a main direction. Note that six exhaust ports 1126 are provided in the lower case 112, and six exhaust ports 1126 are positioned between the two drive wheels 116 in the present embodiment.

  The suction port 113 of the present embodiment does not have a portion extending in the main direction from the suction port 1131, but extends in the main direction, for example, like a duct 42 of the dust case 4 described later, and the suction port 113. You may have a suction part duct integral with. In this case, the suction port duct, the dust sensor unit 12 and the duct 42 surround the path from the suction port 1131 to the inside of the dust case 4. In this regard, as will be described later, from the viewpoint of improving the volume of the dust case 4, the length of the suction duct (for example, the length in the main direction) and the length of the frame 121 (for example, the length in the main direction) are included in this path. ), The length of the duct 42 (for example, the length in the main direction) is preferably longer.

[Dust sensor unit 12]
The dust sensor unit 12 is disposed between the suction port 113 and the dust case 4.
The dust sensor unit 12 includes a frame 121, a light emitting unit 122 and a light receiving unit 123 that are provided on the frame 121 and face each other, a contact member 124 attached to the dust case 4 side of the frame 121, and a substrate 127. The dust sensor unit 12 is formed as a separate member from the suction port 113 and the dust case 4. By attaching the frame 121 to the suction port 113 and mounting in this state, the light emitting unit 122, the light receiving unit 123, and the connector 126. The contact member 124 can be attached at the same time. For this reason, the dust sensor unit 12 of this embodiment is excellent in assemblability.

(Frame 121)
The frame 121 is a member that can attach the light emitting unit 123 and the light receiving unit 124 to the frame 121 itself or in the vicinity thereof while securing a space on the optical axis connecting the light emitting unit 123 and the light receiving unit 124. The frame 121 of the present embodiment has a shape having a longitudinal direction and a short direction, and may be a rectangular shape, for example. In this embodiment, it is substantially rectangular. A light receiving portion 123 and a substrate 127 are attached to one side of the frame 121 in the longitudinal direction. A light emitting unit 122 is attached to the other side of the frame 121 in the longitudinal direction. The light emitting unit 122 and the light receiving unit 123 may be provided in the short direction of the frame 121. Further, the frame 121 may be square, circular, elliptical, egg-shaped, or the like.

(Light emitting unit 122 and light receiving unit 123)
The light emitting unit 122 and the light receiving unit 123 face each other, and light such as infrared rays emitted from the light emitting unit 122 is received by the light receiving unit 123. What the light emitting unit 122 emits is not limited to light, and may be various known ones as long as it can detect the presence or absence of dust such as ultrasonic waves. Although the light emitting unit 122 and the light receiving unit 123 may be provided on the same side, it is preferable that the light emitting unit 122 and the light receiving unit 123 face each other from the viewpoint of miniaturization.

(Wiring 125, connector 126, substrate 127)
The substrate 127 can be mounted with a drive circuit for the light emitting unit 122, an amplification circuit for the light receiving unit 123, a comparator that outputs a decrease in the amount of received light as a pulse by comparing the amplified signal with a certain reference voltage, and the like. Instead of or in addition to the comparator, it may be possible to detect that the amount of light received by the light receiving unit 123 continuously decreases. In this case, it can be estimated whether the dust case 4 is full.

  The light emitting unit 122 and the substrate 127 are electrically connected by a wiring 125. The wiring 125 is wound in the vicinity of the frame 121, in the frame 121, or incorporated between the frame 121 and the contact member 124 along the opposing direction of the light emitting unit 122 and the light receiving unit 123. A driving current for the light emitting portion 122 flows through the wiring 125. The light receiving portion 123 is also electrically connected to the substrate 127 by wiring (not shown). These wirings are electrically connected to the connector 126.

(Adhesion member 124)
The contact member 124 has a shape that matches the peripheral shape of the frame 121, and is a hollow, substantially rectangular shape in the present embodiment. The shape of the frame 121 is matched to the shape of the suction port 1131. As the contact member 124, packing or the like can be employed.

(Advantages of the dust sensor unit 12)
Since the dust sensor unit 12 configured in this way can hold the light emitting unit 122 and the light receiving unit 123 together, it is easy to match the optical axes. In addition, since the light receiving unit 123 and the substrate 127 can be arranged close to each other, the distance from the light receiving unit 123 to the amplifier circuit can be shortened, and the influence of electromagnetic noise on the output of the light receiving unit 123, which is a weak signal, is reduced. can do. Further, the wiring 125 of the light emitting unit 122 is also integrated in the dust sensor unit 12, and when connecting electrically to the control device 2, it is only necessary to connect the wiring (not shown) to the connector 126. Is excellent.

  In addition, it is preferable to use a material having elasticity such as an elastomer for the contact member 124 which is a member in contact with the dust case 4, but such a material deteriorates relatively faster than other parts. Also, the surfaces of the light emitting unit 122 and the light receiving unit 123 are likely to be contaminated or damaged by dust. According to the present embodiment, parts that are likely to be replaced due to such deterioration, dirt, and scratches can be replaced at the same time by replacing the dust sensor unit 12, which is excellent in maintainability.

(Dimensions in the non-opposing direction of the frame 24, etc.)
9 is a cross-sectional view taken along the line CC of FIG. Regarding the dust sensor unit 12, a direction substantially perpendicular to the facing direction of the light emitting unit 122 and the light receiving unit 123 in a direction parallel to the frame 121 (a direction perpendicular to the main direction) is referred to as a non-facing direction. In the frame 121, when the width in the non-facing direction on the suction port 1131 side is a and the width in the non-facing direction on the dust case 4 side is b, a≈b and a <b. As a result, the cross-sectional area of the surface perpendicular to the main direction is reduced more than necessary and the loss is suppressed. Further, a center line 90 (substantially parallel to the main direction) of the region surrounded by the frame 121 is a straight line passing through the midpoints of the dimensions a and b. That is, as illustrated in FIG. 9, when considering a straight line that satisfies a1 = a2 = a / 2 and b1 = b2 = b / 2, a1 and b1 are above the center line, and a2 and b2 are below the center line. It is. At this time, the light emitting unit 122 and the light receiving unit 123 are disposed below the center line 90 in the non-facing direction. Since dust is heavier than air and has a high probability of passing below the center line 90, it is possible to detect the dust with high accuracy by providing the light emitting unit 122 and the light receiving unit 123 on the lower side.

  10 is a cross-sectional view taken along the line DD of FIG. The light emitting unit 122 includes a light emitting element 1221 and a transparent resin cap 1239, and the light receiving unit 123 includes a light receiving element 1232 and a transparent resin cap 1239. Regarding the attached transparent resin cap 1239, the area between the light emitting element 1221 and the light receiving element 1232 has a dimension smaller than the dimension in the direction perpendicular to the optical axis of the light emitted from the light emitting element 1221. As a result, the transparent resin cap 1239 can protect the element, and can guide the light from the light emitting element 32 while suppressing the vertical and front dimensions of the dust sensor unit 12 from being increased.

(Dimensions in the opposite direction of the frame 24)
Of the directions parallel to the frame 121, a direction substantially parallel to the facing direction of the light emitting unit 122 and the light receiving unit 123 is referred to as a facing direction. When the width in the facing direction on the suction port 1131 side is e and the width in the facing direction on the dust case 4 side is d, e> d. That is, the width of the frame 121 in the facing direction decreases as it goes toward the dust case 4 side. Thereby, the air containing the dust flows in the direction of the arrow 91, and the dust flows away from the wall surface due to inertia. For this reason, scratches and dirt on the transparent resin cap 1239 can be suppressed.

[Dust case 4]
11 is a perspective view showing a state in which the dust case 4 is removed from the main body 11, FIG. 12 is a perspective view including a region of the main body 11 to which the dust case 4 is mounted in the self-propelled vacuum cleaner 1, and FIG. FIG. 14 is a cross-sectional view taken along the line BB of FIG. 5, FIG. 15 is a perspective view including the prop housing portion 1102 and the prop 95, and FIG. 16 is a rear perspective view of the main body 11 to which the dust case 4 is attached. is there.
The dust case 4 is a container that accumulates dust sucked from the floor via the suction port 1131 (suction port 113). The dust case 4 includes a duct 42 formed on the suction port 1131 side, a main accumulation chamber 41 that mainly accumulates collected dust, a lid 45 that allows the accumulated dust to be taken out from the filter 46 side (upper side), and rotation Then, a backflow suppression valve 44 capable of opening and closing the opening on the lower side (duct 42 side) of the main storage chamber 77 and a foldable handle 43 are provided. The dust case 4 is attached from obliquely upward to obliquely downward of the main body 11.

(Main storage room 41)
The main accumulation chamber 41 is formed of a resin material, for example, and is a region that encloses the space. The lid 45 and the backflow suppression valve 44 suppress dust from leaking out of the space. The lid 45 can block the opening on the horizontal direction side of the main accumulation chamber 41, and the backflow suppression valve 44 can block the opening on the lower side of the main accumulation chamber 41. The cross-sectional area of the space contained in the main storage chamber 41 is larger than the cross-sectional area of the frame 121. As the cross-sectional area of the space contained in the main storage chamber 41 here, for example, a cross-sectional area in a direction perpendicular to the filter 46 can be used.

(Duct 42)
The duct 42 has one end on the lower side of the main accumulation chamber 41 and the other end that can be opened and closed by the backflow suppression valve 44. The duct 42 is an integral part of the dust case 4 that forms a part, almost all or all of the path from the suction port 1131 to the main accumulation chamber 41. The duct 42 of the present embodiment has a shape in which one end side extends substantially in the vertical direction and extends obliquely downward from the middle toward the other end side, but only the latter, that is, oblique to the other end side. You may consist only of the part extended in the downward direction.

  Thus, as a whole, the duct 42 extends obliquely downward from one end to the other end. One end of the duct 42 can be provided, for example, on the lower surface of the main storage chamber 41, and preferably provided at a position farther from the center of the lower surface of the main storage chamber 41 than the other end of the duct 42 in a top view. It is done. Thereby, it is easy to make the size of the dust case 4 in a top view smaller.

(Handle 43)
The handle 43 is a member that is rotatably provided with the upper side of the main storage chamber 41 as a rotation axis, and includes a grip portion 431, a retaining portion 432, an action point portion 433, and a locking portion 434. The handle 43 can rotate approximately 90 ° to 100 ° from the front to the upper side of the rotary shaft. In order to achieve the effects of both the action point portion 433 and the locking portion 434 described later, the rotation storage range is more than 90 °, approximately 135 ° or less, preferably 120 ° or less. Here, the state in which the grip portion 431 lies down (the state in which the grip portion 431 is locked to the locking portion 434) is set to a rotation angle of 0 °. Note that the state illustrated in FIG. 16 is a rotation angle of approximately 90 °.

  The grip portion 431 is a portion that is easy for the user to grip the dust case 4 and use it for attaching and detaching operations, and is provided with a locking portion 434 at the front end. When the dust case 4 is attached to the main body 11, the locking portion 434 is locked to a non-locking portion (not shown) provided in the upper case 111, and the handle 43 can be locked.

  The retaining portion 432 is a protrusion-like portion provided near the rotation shaft and closer to the locking portion 434 (rotation angle 0 ° side) than the rotation shaft. In a state where the handle 43 is positioned on the front side, the retaining portion 432 enters the main body 11 and comes into contact with a portion in the main body 11 to generate a frictional resistance. Thereby, the handle 43 is prevented from coming off.

  The action point portion 433 is a portion that comes into contact with the upper surface side of the main body 11 when the user further applies a force toward the rear (the rotation angle exceeds 90 °) with the handle 43 positioned on the upper side. It is. In this state, the action point portion 433 serves as an action point of the force that lifts the dust case 4 from the main body 11, and the rotation shaft serves as a fulcrum. Thereby, it can become assistance when a user removes the dust case 4. FIG. Although it does not restrict | limit especially as the upper surface side of the main body 11, For example, it can be set as the guide level | step difference 119 mentioned later.

[Dust case 4 shape and prop storage section]
The dust case 4 has a shape in which the rear upper side protrudes rearward, and when attached to the main body 11, the rear upper side forms part of the side surface of the self-propelled electric vacuum cleaner 1 (see FIG. 16 and the like). For this reason, the region of the main body 11 that is directly below the rear upper region in the dust case 4 also forms part of the side surface of the self-propelled electric vacuum cleaner 1. In the present embodiment, a small tool storage portion 1102 as illustrated in FIG. 15 or the like is provided in the vicinity of a part of the side surface of the main body 11, and a cleaning brush 95 as an example of a small tool is stored. The cleaning brush 95 can be used for a user to clean the inside of the dust case 4, for example, and has a shape bent along the outer peripheral shape of the main body 11. The cleaning brush 95 has a brush 951 and a jig portion 952. The brush portion 951 can be used when cleaning the dust case 4 and the like, and the jig portion 952 can be used when removing the side brush 15.

  By making the shape bent along the outer peripheral shape of the main body 11, a space required for storing the cleaning brush 95 can be provided along the inner periphery of the side surface of the main body 11. For example, it is not preferable that the cleaning brush 95 or the like is mounted on the outer surface of the dust case 4 because the capacity of the dust case 4 can be reduced. Further, by setting the storage space for the cleaning brush 95 and the like as the attachment / detachment region of the dust case 4, it is possible to suppress a situation in which the cleaning brush 95 and the like are unintentionally dropped.

  Instead of this embodiment, for example, instead of or in addition to the cleaning brush 95, a jig for removing the side brush 15 and other props may be stored.

  The manner of storing props is not limited to the above, and it is only necessary to provide the main body 11 with a region surrounded by the main body 11 and the dust case 4 when the dust case 4 is attached to the main body 11.

(Backflow suppression valve 44)
The backflow suppression valve 44 is attached to the main surface 441 that can close the opening as the other end of the duct 42, and is integrally or separately attached to the main surface 441, and is located outside the duct 42 in a direction substantially parallel to the main surface 441. It has a protruding portion 442 that protrudes, and a biasing portion 443 that biases the main surface 441 and the protruding portion 442 in a rotating direction. In the present embodiment, the protrusions 442 are provided on the outer sides in the direction substantially parallel to the main surface 441.

The urging portion 443 is a member that urges the backflow suppression valve 44 in a direction in which the main surface 441 closes the opening, and various known members can be used, and for example, a spring can be used. If the urging portion 443 is, for example, a coil spring, the urging portion 443 can serve as a rotating shaft.
For this reason, the backflow suppression valve 44 closes the other end of the duct 42 when no external force is applied.

  When the dust case 4 is attached to the main body 11, the protruding portion 442 comes into contact with a guide step 119 serving as a counter biasing portion provided in a region where the dust case 4 is stored. The guide step 119 is two step portions provided in a region of the main body 11 that is visible when the dust case 4 is removed. Each of the guide steps 119 is provided along the direction in which the dust case 4 is attached. In the present embodiment, the guide steps 119 extend from the upper rear to the lower front.

  By the downward movement of the dust case 4 accompanying the mounting of the dust case 4 to the main body 11, the protrusion 442 contacts and slides on each of the guide steps 119, and receives a force in the direction in which the main surface 441 opens the opening. Thereby, the backflow suppression valve 44 opens the other end of the duct 42 against the biasing force of the biasing portion 443. Like the guide step 119 exemplified in this embodiment, the main surface 441 receives a force opposite to the urging force of the urging portion 443 due to the contact between the counter urging portion and the protruding portion 442, and the other end of the duct 42. The opening can be opened.

  Specifically, the backflow suppression valve 44 rotates around the longitudinal direction, and the other end of the duct 42 is opened. Since the backflow suppression valve 44 of the present embodiment has a substantially rectangular shape, the backflow suppression valve 44 rotates around the short direction or about the direction perpendicular to the main surface 441. Therefore, it is preferable to rotate about the longitudinal direction as an axis. That is, the urging unit 443 rotates the backflow suppression valve 44 around the longitudinal direction of the main surface 441.

  In addition, the protrusion part 442 should just be able to make the backflow suppression valve 44 open by contacting a certain member (counter biasing part) of the self-propelled electric vacuum cleaner 1.

  A clearance 1101 is provided in front of the front end of the guide step 119 of the present embodiment, and the backflow suppression valve 44 slides while being pressed by the guide step 119 in a state where the dust case 4 is attached to the main body 11. In the gap 1101. The gap 1101 is positioned outside the main direction projection plane of the frame 121. For this reason, in a state where the dust case 4 is mounted, the other end of the duct 42 contacts the dust sensor unit 12, particularly in close contact with the contact member 124 in the present embodiment.

[Structures provided from the suction port 1131 to the main storage chamber 41]
In particular, as illustrated in FIG. 14, the dimension 92 of the dust sensor unit 12 is shorter than the dimension 93 on the other end side of the duct 42 in the main direction. That is, the dimension 93 on the other end side of the duct 42 forms a part of the path connecting the suction port 1131 to the main storage chamber 41, preferably more than the dimension 92. Thereby, since a part of dust case 4 can be provided in the area | region from the suction opening 1131 to the main storage chamber 41, the volume of the dust case 4 can be expanded.

  Here, the duct 42 can include an upright portion 421 that forms one end side of the duct 42 and has a dimension 94 and extends vertically. The upright portion 421 prevents dust from leaking from the main accumulation chamber 41 to the other end side of the duct 42.

  Here, the dimension 93 is measured with a straight line substantially parallel to the dimension 92 of the dust sensor unit 12 by imitating the lower surface of the dust case 4 to a flat surface (approximate the main storage chamber 41 to a box shape). It can be considered as the distance from the plane to the dust sensor unit 12. Note that the main storage chamber 41 of this embodiment can be considered as a box shape.

[Clogging of Duct 42 by Backflow Control Valve 44]
As described above, when the dust case 4 is attached to the main body 11, the backflow suppression valve 44 is stored on the upper side of the rotating brush 14. When the dust case 4 is removed from the main body 11, the backflow suppression valve 44 is rotated by the urging force of the urging portion 443 to close the opening at the other end on the duct 42 side. Thereby, even if dust is accumulated in the duct 42, it is possible to prevent the dust from spilling out from the dust case 4. The main surface 441 may have a flat plate shape or a mesh shape that can suppress the passage of dust.

[Dust full detection]
When the self-propelled vacuum cleaner 1 sucks dust, the sucked dust is first accumulated in the main accumulation chamber 41 and is also accumulated in the duct 42 when the main accumulation chamber 41 is full. Since the duct 42 is inclined downward facing the horizontal direction from the gravity direction, it is possible to suppress the dust from falling from the duct 42. Further, since it faces the gravitational direction side from the horizontal direction, dust tends to be accumulated in the duct 42 relatively soon after the main accumulation chamber 41 is full, and the dust sensor unit 12 can easily detect dust.

  In addition, the upright portion 421 can suppress the dust flowing into the duct 42 and falling, although the main storage chamber 41 has a margin. In the dust case 4 of the present embodiment, a majority of the space contained in the main accumulation chamber 41 is provided in front of one end of the duct 42, so that dust tends to accumulate on the front side. However, since the upright portion 421 is provided between the majority of the space and the duct 42, the dust moves rearward as the self-propelled vacuum cleaner 1 accelerates forward, which is the main movement direction. Moreover, it can suppress effectively that dust falls to the duct 42. FIG. That is, from the front to the rear, the majority of the space contained in the main storage chamber 41 is positioned in the order of the upright portion 421 and one end of the duct 42.

  When dust accumulates in the duct 42 and becomes almost full, the dust continues to block the light from the light emitting unit 122, and the state in which the amount of light received by the light receiving unit 123 decreases continues. By detecting this state, it is possible to detect that the dust case 4 is full and notify the user, or to start control of returning the self-propelled vacuum cleaner 1 to a charging stand (not shown).

[Detection of passing dust amount]
When the light from the light emitting unit 122 is momentarily blocked, the amount of light received by the light receiving unit 123 decreases in a pulse manner. Thereby, it can be detected that dust is passing toward the dust case 4. In the present embodiment, the cross-sectional area in the main direction is larger on the rotating brush 14 side than the suction port 1131, smaller on the frame 121 and the duct 42, and larger on the main accumulation chamber 41. That is, the cross-sectional area in the path from the storage space of the rotating brush 14 to the main accumulation chamber 41 is the smallest in the frame 121 and / or the duct 42. Therefore, the sucked dust is concentrated on the frame 121 having a small cross-sectional area according to the shape of the duct 42. Since the light emitting unit 122 and the light receiving unit 123 are provided on the frame 121, most of the dust passes between the light emitting unit 122 and the light receiving unit 123. That is, the amount of dust can be measured with high accuracy.

  Further, since the dust after passing through the frame 121 passes through the duct 42 having a substantially the same cross-sectional area, a vortex is hardly generated in the vicinity of the frame 121. That is, dust can be prevented from flowing back and swirling due to eddy currents. Furthermore, since the cross-sectional area after passing through the duct 42 increases, windage loss can be suppressed.

  Further, the cross-sectional area upstream of the dust sensor unit 12, that is, the cross-sectional area from the suction port 113 to the dust sensor unit 12 may be monotonously decreased. If it carries out like this, a eddy current will arise in the dust sensor unit 12 upstream, and it can control that dust is detected by the dust sensor unit 12 in multiple.

[Layout]
17 is a perspective view of the self-propelled electric vacuum cleaner 1 from which the upper case 111 is removed, and FIG. 18 is a cross-sectional view taken along line EE of FIG.
In order to make the vertical dimension of the self-propelled electric vacuum cleaner 1 small, the vertical dimension of the main body 11 is substantially the same as the vertical dimension of the electric blower 16. As illustrated in FIG. 17, when the upper case 111 is removed, the convex shape 113 covering a part of the upper surface of the electric blower 16 can be seen. This contributes to downsizing of the main body 11 in the vertical dimension. In addition, the bottom surface side of the main body 11 may have a convex shape protruding downward at a position overlapping the electric blower 16 in a bottom view.

  In addition, when the cylindrical electric blower 16 is arranged obliquely, it is necessary to increase the vertical dimension of the main body 11. Therefore, the axial direction of the electric blower 16 is horizontal or ± 10 degrees or less from the horizontal direction, preferably The deviation is ± 5 degrees or less.

  As viewed in the axial direction of the electric blower 16, as illustrated in FIG. 18, the rotation shaft side of the arm 1141 is located inside a substantially square area circumscribing the cylindrical electric blower 16. Although this area is likely to become a dead space, by arranging a part of the arm 1141 in this way, the space can be effectively used to realize the miniaturization of the self-propelled electric vacuum cleaner 1. Moreover, since the exhaust port 1126 is located directly under the electric blower 16 or directly under the opening on the downstream side of the electric blower 16, the exhaust air passage can be shortened.

  The present embodiment includes various configurations for miniaturization, and as a result, the vertical dimension can be brought close to the vertical dimension of the electric blower 16. Specifically, the vertical dimension of the self-propelled vacuum cleaner 1 in a state where the self-propelled vacuum cleaner 1 is placed on the floor surface (that is, the arm 1141) even if the influence on the dimensions by the drive wheels 116 is taken into consideration. The vertical dimension of the electric blower 16 is within a range of 70% or more, preferably 75% or more or 85% or more of the vertical dimension in a state where the drive wheel 116 is accommodated by rotating upward. Yes.

  The vertical dimension of the area surrounding the upper and lower cases 111 and 112 and the vertical dimension of the electric blower 16 are substantially the same. Specifically, the vertical dimension of the electric blower 16 is 90% or more, preferably 95% or more of the vertical dimension of the region surrounded by the upper case 111 and the lower case 112.

  Further, as described above, the rechargeable battery 19 and the electric blower 16 are the ones having a large weight among the structures placed on the main body 11. If the rechargeable battery 19 is disposed on the center side, wiring and the like are likely to be hindered. Therefore, in the present embodiment, the electric blower 16 is disposed on the center side, and the rechargeable battery 19 is disposed on the front side.

[Rotation speed of side brush 15]
The self-propelled vacuum cleaner 1 has side brushes 15 on the left side and the right side, respectively. In the present embodiment, the rotation speed of the side brush 15 can be changed. Specifically, when the self-propelled vacuum cleaner 1 is executing a wall-side cleaning mode in which the wall is located on the left side, the left side brush 15 on the same side as the side on which the wall is located. The rotational speed is controlled to be faster than the rotational speed of the other side brush 15. Thereby, the cleaning by the wall can be performed more effectively. The wall-side cleaning mode can be executed by various known methods. For example, the wall-side cleaning mode can be realized by running control so that the distance measuring sensor 210 provided on the left side of the main body 11 continuously detects the wall surface (obstacle).

  The same control can be performed when the wall-side cleaning mode in which the wall is located on the right side is being executed. In addition, when the rotational speed of the side brush 15 on the wall side during execution of the wall-side cleaning mode is detected in another control mode, for example, a wall surface or an obstacle, the traveling direction is changed in a direction away from the wall surface or the obstacle. The same effect can be obtained even when the rotational speed is controlled to be higher than the rotational speed during the execution of the reflective traveling mode to be resumed. Further, similarly to the side of the wall, the rotation speed and the torque described later can be similarly controlled at the corner where the two wall surfaces intersect.

[Torque of side brush 15]
Each of the side brushes 15 is driven by a side brush motor 152 that is driven by the power of the rechargeable battery 19. In the present embodiment, a DC motor is employed as the side brush motor 152. The DC motor can transmit a higher torque when the duty ratio is higher (the voltage application time is longer) even if the voltage output in time average is the same value. When the side brush 15 is in contact with a wall or an obstacle, the torque is reduced due to the friction thereof, so that the cleaning efficiency is likely to be lowered.

  For this reason, in this embodiment, for example, when the wall-side cleaning mode in which the wall runs on the left side is executed, torque is transmitted to the left side brush 15 that is the same side as the side on which the wall is located. The duty ratio of the side brush motor 152 can be controlled to be higher than the duty ratio of the side brush motor 152 that transmits torque to the other side brush 15.

  In addition, when the energy of the rechargeable battery 19 decreases and the output voltage decreases, the torque decreases even at the same duty ratio. Therefore, the duty ratio is increased as the remaining power of the rechargeable battery 19 is lower.

  For the same reason, since the torque to be output differs depending on the material of the floor surface, the duty ratio may be determined according to the type of the floor surface. For example, the duty ratio during carpet cleaning can be controlled to be higher than during flooring cleaning.

  Furthermore, the duty ratio can be reduced as the number of detected dust in the dust sensor unit 12 is larger. Thereby, it is possible to prevent the side brush 15 from scattering dust in a region where there is a large amount of dust.

  In addition, when the duty ratio of the side brush 15 on the wall side during execution of the wall-side cleaning mode is detected in another control mode, for example, a wall surface or an obstacle, the traveling direction is changed in a direction away from the wall surface or the obstacle. The same effect can be obtained even when the duty ratio is controlled to be higher than the duty ratio during execution of the reflective traveling mode to be resumed.

[Sensors]
FIG. 23 is a schematic configuration diagram illustrating the control device 2 of the self-propelled electric vacuum cleaner and the devices connected to the control device 2. The bumper sensor (obstacle detection means) is a sensor that detects the backward movement of the bumper 18 (that is, contact with the obstacle).

  A distance measuring sensor 210 (obstacle detection means) illustrated in FIG. 2 and the like is an infrared sensor that detects a distance to an obstacle. In the present embodiment, distance measuring sensors are provided at a total of five locations, three at the front and two at the side.

  The distance measuring sensor 210 includes a light emitting unit (not shown) that emits infrared light, and a light receiving unit (not shown) that receives reflected light that is reflected by the infrared light reflected by an obstacle. The distance to the obstacle is calculated based on the reflected light detected by the light receiving unit. In addition, at least the vicinity of the distance measuring sensor in the bumper 18 is formed of resin or glass that transmits infrared rays.

  The floor distance measuring sensor 211 (floor surface detection means) illustrated in FIG. 3 and the like is an infrared sensor that measures the distance to the floor surface, and is installed at four positions on the front, rear, left and right of the lower surface of the lower case 112. . More specifically, it is located on the front side of the auxiliary wheel 17, on the rear side of the rotating brush 14 and the scraping brush 13, on the front side of each drive wheel 116 and on the outer side in the left-right direction.

  By detecting a large step such as a staircase or the like using the floor surface ranging sensor, the self-propelled vacuum cleaner 1 can be prevented from falling (from the staircase or the like). For example, when a level difference of about 30 mm is detected forward by the distance measuring sensor for the floor surface, the control device 2 controls the travel motor to move the main body 11 backward to change the traveling direction.

  The floor surface ranging sensor 211 on the front side of the auxiliary wheel 17 (the front end side of the lower case 112) detects that the distance from the floor surface is far, and the rear side of the rotating brush 14 (the rear end side of the lower case 112). ), The control device 2 may continue to move the main body 11 as it is. This is because, in the case of such a combination of detections, the self-propelled vacuum cleaner 1 is considered to often climb a step. Similarly, the floor surface distance measuring sensor 211 on the front side of the auxiliary wheel 17 detects that the distance from the floor surface is short, and the floor surface element distance sensor 211 on the rear side of the rotating brush 14 is far from the floor surface. When detecting that, the control device 2 may continue to advance the main body 11 as it is. “Near” here is, for example, equal to or less than the distance detected by the floor surface ranging sensor 211 when the self-propelled vacuum cleaner C is traveling on a flat floor surface, For example, when the self-propelled electric vacuum cleaner C is traveling on a flat floor surface, the distance is detected by the floor surface distance measuring sensor 211 that exceeds the distance. In addition, one or two appropriate threshold values may be set and compared with this.

  The rotational speed and rotational angle of the traveling motor 1161 are detected using the traveling motor pulse output shown in FIG. The control device 2 calculates the moving speed and moving distance of the main body 11 based on the rotation speed and rotation angle detected from the travel motor pulse output, the gear ratio of the speed reduction mechanism, and the diameter of the drive wheel 116.

  The traveling motor current measuring instrument is a measuring instrument that measures the current flowing through the armature winding of the traveling motor 1161. Similarly, the electric blower current measuring device measures the current value of the electric blower 16, and the rotating brush motor current measuring device measures the current value of the rotating brush motor 1133. The two side brush motor current measuring devices measure the current value of the side brush motor 152. Each current measuring instrument outputs the measured current value to the control device 2. Using the detection result of the current value, for example, it is possible to detect an abnormality in which a foreign object is entangled with the rotating brush and the rotation stops, and the user can be notified by an operation button.

  Further, when the state of the floor surface on which the main body 11 is traveling is detected from the current value of the rotary brush motor 1133 and the current value of the traveling motor 1161, for example, if it is recognized as being on a carpet, the input of the electric blower 16 is increased and the suction force is increased. Is increased, and on the flooring, the input of the electric blower 16 is set to be small, and control for suppressing the power consumption of the rechargeable battery 19 is performed.

  When dust is detected by the dust sensor unit 12, the input of the electric blower 16 is increased for a certain time. The input increase time of the electric blower 16 is not determined (for example, extended) according to the detected dust amount. Thereby, the power consumption of the electric blower 16 is suppressed. Further, even if dust is detected, the main body 11 is not reversed or reciprocated. Thereby, the fall of a moving speed can be avoided.

[Driver]
The travel motor drive device (left) (right) shown in FIG. 23 is an inverter that drives the left and right travel motors 1161 or a pulse waveform generator by PWM control, and operates according to a command from the control device 2. . The same applies to the electric blower driving device, the rotating brush motor driving device, and the side brush motor driving device (left) (right). Each of these driving devices is installed in the control device 2 (see FIG. 2) in the main body 11.

[Control device 2]
The control device 2 is, for example, a microcomputer (not shown), reads a program stored in a ROM (Read Only Memory) and develops it in a RAM (Random Access Memory), and a CPU (Central Processing Unit) performs various processes. It is supposed to run. The control device 2 executes arithmetic processing in accordance with the signals input from the switch seat 22 (see FIG. 1) and each of the sensors described above, and outputs a command signal to each of the drive devices described above.

  The self-propelled vacuum cleaner according to the present invention has been described in detail with reference to the embodiment. Needless to say, the content of the present invention is not limited to the embodiment, and can be appropriately modified and changed without departing from the spirit of the present invention. In the present embodiment, the self-propelled cleaner has been described as an example, but the same effect can be obtained when applied to canister-type, stick-type and handy-type cleaners.

<Embodiment 2>
The configuration of the second embodiment can be the same as that of the first embodiment except for the following points.
[Switch sheet 22]
24 is a perspective view of the self-propelled electric vacuum cleaner 1 with the upper case 111 removed, FIG. 25 is a perspective view of the self-propelled electric vacuum cleaner 1 with the switch sheet 22 further removed from the state of FIG. 24, and FIG. ) Is a front perspective view of the switch sheet 22, and FIG. 26B is a rear perspective view of the switch sheet 22.

The switch sheet 22 is provided between the upper case 111 and the control board 21. The control board 21 is located below the upper case 111 in the main body 11. In addition, a resin support plate 80 on which the switch sheet 22 is placed is provided between the control board 21 and the switch sheet 22.
The switch sheet 22 includes operation buttons 221 and 222 that output an operation signal according to a user operation to the control device 2 and a soft portion 223. As the operation buttons 221 and 222, a circular operation button 221 having a circular shape and an annular ring-shaped operation button 222 surrounding the circular operation button 221 are provided. By pressing the operation buttons 221 and 222, the control device 2 can output a signal. The operation buttons 221 and 222 and the soft part 223 are assembled in advance and formed as one member.
The operation buttons 221 and 222 are exposed on the upper surface of the self-propelled electric vacuum cleaner 1. For example, the operation buttons 221 and 222 can have a function of outputting to the control device 2 a signal for turning on / off the power, starting / ending cleaning, and changing the cleaning mode.
The soft portion 223 can be a flexible rubber member surrounding the operation buttons 221 and 222, for example. By placing the soft portion 223 on the support plate 80 and sandwiching the soft portion 223 between the upper case 111 and the support plate 80, the operation buttons 221 and 222 exposed near the upper surface of the self-propelled electric vacuum cleaner 1 can be used. Infiltration of water droplets or the like can be suppressed. With this configuration, the operation buttons 221 and 222 can be exposed on the upper surface of the self-propelled electric vacuum cleaner 1 while suppressing the intrusion of water droplets and the like, so that the push-down operation buttons 221 and 222 are waterproof. Since it is possible to reduce the necessity of surrounding with a member, the design can be improved.

  The soft part 223 has one or more through holes 2231. A light emitting unit (not shown) such as an LED is provided on the side opposite to the upper case 111 via the through hole 2231. The light emitting unit can be provided on the control board 21, for example. By changing the color of light emitted by the light emitting unit in response to pressing of the operation buttons 221 and 222, the user can be notified that the operation by the operation buttons 221 and 222 has been recognized by the control device 2. The through hole 2231 is separated from the operation buttons 221 and 222 when the switch sheet 22 is viewed from the front. Thereby, it can suppress that a water droplet permeates into the through-hole 2231.

  The display panel drive device is a device that issues a light emitting unit by applying a voltage to the electrodes of the display panel in response to a command from the control device 2. For example, the light emitting unit may be, for example, an operation state mode (automatic or manual) or a state (notification of whether or not garbage is discarded or a remaining charge value) of the self-propelled vacuum cleaner 1, a timer reservation time, or an input mode (strong, medium, Weak) etc. is displayed.

  The support plate 80 has a through hole 801 at a position overlapping the operation buttons 221 and 222. Further, the operation buttons 221 and 222 have protrusions 2211 and 2221 and a support protrusion 2232 on the back surface. The support protrusion 2232 suppresses the protrusions 2211 and 2221 from contacting the switch on the control board 21 when the operation button 221.222 is not pressed, and the protrusions 2211 and 2221 when the operation button 221 and 222 are pressed. Can enter the through hole 801 and come into contact with the switch of the control board 21. Note that a through hole 802 is also provided at a position overlapping the light emitting portion and the through hole 2231 described above.

  Note that the operation buttons 221 and 222 do not have a display unit that notifies the detection of dust. Since the input mode of the electric blower changes when dust is detected, the input mode display unit of the electric blower is also used. As a result, the cost of the display unit can be reduced.

  The rechargeable battery 19 is, for example, a secondary battery that can be reused by charging, and is accommodated in the battery accommodating portion 115 (see FIG. 4). The electric power from the rechargeable battery 19 is supplied to each sensor, each motor, each drive device, and the control device 2.

<Embodiment 3>
The configuration of this embodiment can be the same as that of Embodiment 1 or 2 except for the following points.
[Shape of side brush 15]
FIG. 27 is a perspective view of the side brush 15, and FIG. 28 is a view showing a state in which the side brush 15 is bent. The base elastic part 153 of the side brush 15 has a narrow part 1531 which is a part (base side) on the side brush holder 151 side, which is thinner than a thick part 1532 which is a part on the brush part 154 side. Since the narrow portion 1531 is connected to the side brush holder 151, the thick portion 1532 and the brush portion 154 can bend relatively easily with the narrow portion 1531 as an axis. For this reason, even if the power cord or the like contacts the side brush 15, as illustrated in FIG. 28, the side brush 15 rotates without being entangled with the power cord or the like by being bent with the narrow portion 1531 as an axis. Easy to continue.

  Further, the dimension (length dimension) along the brush part 154 of the root elastic part 153 is the same as that when the autonomously traveling cleaner S is placed on the floor surface, even if the root elastic part 153 is bent toward the floor surface. The length does not reach the floor. Thereby, for example, even if the power cord or the like contacts the side brush 15 and the side brush 15 is bent, it is possible to suppress a situation in which the base elastic portion 153 contacts the floor surface and the side brush 15 is violently folded from the base. That is, the base elastic part 153 is dimensionally adjusted so that the tip thereof does not contact the floor surface during traveling of the self-propelled electric vacuum cleaner 1.

  Further, the distance in the direction perpendicular to the brush portion 154 from the upper surface portion of the narrow portion 1531 to the upper surface portion of the thick portion 1532 (the dimension of the step between the thin portion 1531 and the thick portion 1532) is 1 .2 mm or less.

  The narrow portion 1531 has a shape in which the surfaces on both sides in the rotational direction are thinner than the thick portion 1532, and can be used in common for the two side brushes 15. Here, when there is no thinned part on either side in the rotational direction, the base elastic part 153 is easily bent downward when it comes into contact with an obstacle. At this time, the brush portion 154 may be greatly bent and become hazy. On the other hand, when there is a narrowed portion in either direction of rotation, the base elastic portion 153 tends to bend obliquely downward when it comes into contact with an obstacle. In other words, the brush portion 154 is difficult to be sandwiched between the floor surface and the habit can be suppressed. However, at this time, the rotation directions of the two side brushes 15 are usually reversed, so that the directions in which the thinned portions should be provided are reversed by the two side brushes 15. That is, it is difficult to use the two side brushes 15 as common parts. And when there exists a part which became thin to both rotation directions like this embodiment, while being able to suppress a habit to the fundamental elastic part 153, the two side brushes 15 can be used as a shared part.

  As illustrated in FIG. 3, the side brush holder 151 has a jig insertion hole 1512 on the lower surface. The jig insertion hole 1512 penetrates the upper and lower sides of the side brush holder 151, and two claws that form attachment claws 1511 are located on both sides of the jig insertion hole 1512. The attachment claw 1511 is attached to an attached portion (not shown) provided in the lower case 112. The attached portion has a substantially rectangular shape as can be seen from the shape of the attachment claw 1511.

  The user can remove the side brush 15 by inserting the jig portion 952 of the rod-shaped prop 95 into the jig insertion hole 1512 and applying force using the principle of the lever. Thereby, it is possible to allow the user to replace or clean the side brush 15 while fixing the side brush 15 firmly. Moreover, even if the side brush 15 rotates by making the shape of the attachment nail | claw 1511 and a to-be-attached part into a substantially rectangular shape, drop-off | omission of the side brush 15 can be suppressed. The attached portion may be another polygon.

[Rib 47 of dust case 4]
FIG. 29 is a front perspective view of the dust case 4 through the lid 45 and the filter 46. Ribs 47 attached to the inner surface of the dust case 4 are provided above one end of the duct 42, just above, or above and behind. The rib 47 affects the airflow flowing into the main accumulation chamber 41 from one end of the duct 42 and can guide dust. It is preferable that at least a part of the rib 47 overlaps directly above one end of the duct 42. The rib 47 is a portion that protrudes in the front-rear direction on the inner surface of the main storage chamber 41 and extends substantially in the left-right direction. Moreover, it inclines upwards as it goes to the center side from the left-right walk outer side. By tilting upward toward the center side, dust is easily guided to the center side of the main storage chamber 41.

(Other technical ideas)
This application includes the following technical ideas. In addition, each technical idea described as appendices mn (m and n are natural numbers) can be arbitrarily combined as long as there is no problem in context. In addition, the “electric vacuum cleaner” mentioned below includes a so-called canister type or stick type electric vacuum cleaner.

[Appendix 1-1]
A suction port having a suction port;
A dust case having a main accumulator,
A self-propelled vacuum cleaner in which a part or all of a path from the suction port to the main accumulation part is surrounded by a duct integral with the dust case.

  According to Supplementary Note 1-1, a small self-propelled electric vacuum cleaner having an improved dust collection volume can be provided.

[Appendix 1-2]
The suction port includes a suction port duct that forms a part of a path from the suction port to the main accumulation portion, and the length of the suction port duct is shorter than the length of the duct. The self-propelled electric vacuum cleaner as described in 1-1.

[Appendix 1-3]
A dust sensor unit separate from the dust case and the suction port in the path from the suction port to the main storage unit,
The said duct forms the path | route longer than the path | route which the said dust sensor unit forms among the path | routes from the said inlet to the said main accumulation | storage part, The self-according to appendix 1-1 or 1-2 characterized by the above-mentioned. A traveling vacuum cleaner.

[Appendix 1-4]
A dust sensor unit comprising: a frame; a light emitting portion and a light receiving portion which are provided on the frame and face each other; and a contact member attached to the frame.

[Appendix 1-5]
Integrally having a box-shaped main accumulation portion and a duct extending obliquely downward from the main accumulation portion;
A backflow control valve capable of opening and closing the duct;
The backflow suppression valve is a dust case having a main surface, a protruding portion, and an urging portion.

[Appendix 2-1]
An electric blower,
A suction part having a suction port;
A dust sensor unit having a light emitting part and a light receiving part facing each other, and detecting dust passing by the light emitting part and the light receiving part;
A self-propelled electric vacuum cleaner comprising a dust case,
The cross-sectional area perpendicular to the main direction, which is the direction in which air mainly flows by driving the electric blower, decreases from the upstream side of the suction port toward the dust sensor unit, and from the dust sensor unit to the dust case. A self-propelled vacuum cleaner characterized by its large size.

  According to Supplementary Note 2-1, a self-propelled electric vacuum cleaner having a dust sensor unit capable of effectively detecting the amount of dust passing therethrough can be provided.

[Appendix 2-2]
The section according to appendix 2-1, wherein a cross-sectional area of a portion of the suction port, the dust sensor unit, and the dust case facing the light emitting portion and the light receiving portion is substantially minimum or minimum. A traveling vacuum cleaner.

[Appendix 2-3]
The dust case has a duct formed integrally,
The self-propelled electric vacuum cleaner according to appendix 2-1 or 2-2, wherein a dimension in the main direction is longer in the duct than in the dust sensor unit.

[Appendix 3-1]
A vacuum cleaner comprising a dust case having a main storage chamber and a handle that is rotatable about a rotation axis,
The said handle has an action point part which can become an action point of the force applied to this handle | steering-wheel by rotating this handle | steering wheel and making it contact with the said vacuum cleaner, The vacuum cleaner characterized by the above-mentioned.

  According to attachment 3-1, the vacuum cleaner which can remove a dust case easily can be provided.

[Appendix 3-2]
The vacuum cleaner according to appendix 3-1, wherein the dust case is lifted upward by causing the force applied to the handle to act as the point of action.

[Appendix 4-1]
A vacuum cleaner having a dust case detachable from the main body,
The main body has a region surrounded by the main body and the dust case when the dust case is attached to the main body.
A vacuum cleaner characterized in that props are stored in the area.

  According to Supplementary Note 4-1, a vacuum cleaner capable of storing a prop, preferably a prop related to a dust case, can be provided.

[Appendix 4-2]
The vacuum cleaner according to appendix 4-1, wherein the prop is a brush having a shape bent along the shape of the side surface of the main body.

[Appendix 4-3]
The vacuum cleaner according to appendix 4-1 or 4-2, wherein the prop has a jig portion that can be used to remove a brush and a brush of the vacuum cleaner.

[Appendix 5-1]
A self-propelled electric vacuum cleaner having a suction port for storing a rotating brush, and an airtight member provided on the lower side of the rotating brush and the suction port,
The self-propelled vacuum cleaner, wherein the airtight member is biased downward and swings with respect to the rotating brush and the suction port.

  According to appendix 5-1, a small self-propelled electric vacuum cleaner can be provided.

[Appendix 5-2]
The airtight member has a removal claw;
The self-propelled electric vacuum cleaner, wherein the airtight member can be removed from the self-propelled electric vacuum cleaner by moving the removal claw in the left-right direction.

[Appendix 5-3]
The self-propelled electric vacuum cleaner according to appendix 5-1 or 5-2, wherein the airtight member has a rotation shaft on a front side or a rear side.

[Appendix 5-4]
Having a scraping brush that rotates following,
The rotating shaft of the airtight member is coaxial with the scraping brush, The self-propelled electric vacuum cleaner according to any one of appendices 5-1 to 5-3.

[Appendix 6-1]
The lower case,
And a rotating brush having a rotating shaft provided in front of or behind the driving wheel and having a rotation axis in a direction substantially parallel to the facing direction of the two driving wheels. A traveling vacuum cleaner,
The distance between the end portions of the driving wheel and the rotating brush is 20 mm or less,
A rear protrusion provided immediately before or after the drive wheel and on an extension line of the rotation shaft, and / or
A self-propelled electric vacuum cleaner having a central protrusion provided between the two drive wheels.

  According to Supplementary Note 6-1, a self-propelled electric vacuum cleaner that can suppress the insertion of an obstacle can be provided.

[Appendix 7-1]
A self-propelled vacuum cleaner having an electric blower provided in the upper case and the lower case, and a drive wheel attached to the lower case side,
About the self-propelled vacuum cleaner placed with the drive wheel in contact with the floor, the axial direction of the electric blower is horizontal or inclined at 10 degrees or less with respect to the horizontal direction,
The said upper case and / or the said lower case have a dent of the direction away from the said electric blower in the upper-lower end surface vicinity of the said electric blower, The self-propelled vacuum cleaner characterized by the above-mentioned.

  According to appendix 7-1, a small self-propelled electric vacuum cleaner can be provided.

[Appendix 7-2]
The ratio of the vertical dimension of the electric blower attached to the area to the vertical dimension of the area where the upper case and the lower case surround the upper and lower sides is 0.90 or more. Self-propelled vacuum cleaner as described.

[Appendix 7-3]
A drive wheel provided on the lower case side, and a drive mechanism for rotating the drive wheel,
The vertical dimension of the region surrounded by the upper case and the lower case is 70% or more of the vertical dimension when the self-propelled vacuum cleaner is placed on the floor and the driving wheel is in contact with the floor. The self-propelled electric vacuum cleaner according to appendix 7-2, which corresponds to the self-propelled vacuum cleaner.

[Appendix 8-1]
A self-propelled vacuum cleaner having two drive wheels, an electric blower, a rechargeable battery, and a brush having a rotating shaft in the horizontal direction,
The brush has a weight inside, and is a self-propelled electric vacuum cleaner.

  According to Supplementary Note 8-1, it is possible to provide a self-propelled vacuum cleaner capable of arranging the electric blower on the center side while maintaining the balance of the center of gravity.

[Appendix 8-2]
The brush is a driven rotating brush,
The self-propelled electric vacuum cleaner according to appendix 8-1 having another brush driven by a motor.

[Appendix 8-3]
The said brush is provided in the position far from the center of the said self-propelled vacuum cleaner compared with the said another brush, The self-propelled vacuum cleaner of Additional remark 8-2 characterized by the above-mentioned.

[Appendix 8-4]
The self-propelled electric vacuum cleaner according to any one of appendices 8-1 to 8-3, wherein a center of gravity substantially coincides with an axis of the drive wheel.

[Appendix 9-1]
A self-propelled vacuum cleaner having a DC motor for transmitting power to a side brush and a sensor for detecting a wall surface,
The direct current motor performs control to increase the rotation speed of the side brush or increase the duty ratio of the direct current motor during execution of the near wall cleaning mode in which the self-propelled vacuum cleaner travels near the wall. A self-propelled electric vacuum cleaner.

  According to Supplementary Note 9-1, the cleaning efficiency during the wall-side cleaning mode can be improved.

[Appendix 9-2]
A self-propelled vacuum cleaner having a DC motor that transmits power to a side brush and a sensor that distinguishes and detects two or more types of floor surfaces,
The DC motor controls the rotational speed of the side brush or the duty ratio of the DC motor according to the type of floor surface detected by the sensor.

  According to Supplementary Note 9-2, cleaning can be performed more appropriately according to the type of floor surface.

[Appendix 9-3]
A self-propelled vacuum cleaner having a DC motor for transmitting power to the side brush and a sensor for detecting the amount of dust passing through the suction mouth,
A self-propelled vacuum cleaner that controls the DC motor such that a negative phase is established between the number of dust detected by the sensor and a duty ratio of the DC motor.

  According to Supplementary Note 9-3, it is possible to suppress the side brush from scattering dust in an area where there is a lot of dust.

[Appendix 9-4]
There are two side brushes on each of the left and right sides,
Among the side brushes, when the rotational speed of the side brush on the wall side is increased or the duty ratio is increased, the other side brush is also increased in rotational speed or the duty ratio is increased. The self-propelled electric vacuum cleaner as described in any one of 1 thru | or 9-3.

[Appendix 10-1]
A vacuum cleaner having a rotating brush that rotates about a horizontal direction by a motor,
The rotary brush has flocks and a non-woven fabric adjacent to each other, and the non-woven fabric is provided so as to come into contact with the floor surface before the flocking in the rotation direction by the motor. Machine.

  According to Supplementary Note 10-1, a vacuum cleaner having a rotating brush that suppresses entanglement of hair or the like can be provided.

[Appendix 10-2]
The vacuum cleaner according to appendix 10-1, wherein the nonwoven fabric has a slit extending in a radial direction of the rotating brush.

[Appendix 10-3]
The hair transplant and the non-woven fabric are integrated in a root, and the vacuum cleaner according to appendix 10-1 or 10-2.

[Appendix 11-1]
A vacuum cleaner comprising a side brush having a brush portion rotating around a side brush holder,
An electric vacuum cleaner comprising a base elastic part, which is an elastic body, as a member integrated with the side brush holder between the brush part and the side brush holder.

  According to Supplementary Note 11-1, the durability of the side brush can be improved.

[Appendix 11-2]
The side brush is provided in a lower case of the electric vacuum cleaner,
The length of the base elastic portion is shorter than the length from the floor surface to the lower case when the electric vacuum cleaner is grounded.

  According to appendix 11-2, it can suppress that a base elastic part contacts a floor, bends, and a side brush twists.

[Appendix 11-3]
The root elastic part includes a narrow part provided on the side brush holder side, and a thick part provided on the brush part side which is thicker than the thin part and provided on the brush part side. 2. The vacuum cleaner according to 2.

[Appendix 11-4]
The vacuum cleaner according to appendix 11-2 or 11-3, wherein the narrow portion has a portion that is narrowed on both sides in the rotational direction.

[Appendix 12-1]
A vacuum cleaner having an auxiliary wheel that is driven to rotate,
The auxiliary wheel includes a fixed shaft fixed to the vacuum cleaner, a grounding wheel having the fixed shaft as a rotation shaft, a small disk part adjacent to the grounding wheel, and a disk adjacent to the small disk part. And
The small disk portion is rotatable about the fixed shaft as a rotation axis,
The small disk part is larger in diameter than the fixed shaft and smaller in diameter than the disk part,
The vacuum cleaner, wherein the disk portion has a smaller diameter than the ground ring.

  According to Supplementary Note 12-1, it is possible to prevent hair dust and the like from being entangled with the fixed shaft.

[Appendix 13-1]
A switch sheet having an operation button and a soft part;
A device having a case, a control board, and a support plate,
The support plate is located on one side of the control board;
The soft part is sandwiched between the support plate and the case,
The operation button is exposed from the case.

  According to Supplementary Note 13-1, it is possible to provide a device that can suppress the intrusion of water into the case while improving the design of the operation button. The device is not limited to a self-propelled electric vacuum cleaner, and various known electric devices can be employed.

[Appendix 14-1]
A vacuum cleaner comprising a dust case having a backflow control valve provided in an opening,
The backflow suppression valve is
A main surface capable of closing the opening;
A biasing portion that biases the main surface in a direction to close the opening;
A protrusion that extends in a direction substantially parallel to the main surface and reaches the outside of the opening,
The urging portion can rotate the main surface by urging with the longitudinal direction of the backflow suppression valve as a rotation axis,
The vacuum cleaner
An electric vacuum cleaner comprising a counter-biasing portion that can apply a force in a direction to open the opening by contacting the protrusion to the main surface.

[Appendix 14-2]
The counter biasing portion is a guide step as a step provided in the electric vacuum cleaner,
The vacuum cleaner according to appendix 14-1, wherein the backflow suppression valve is housed in a gap provided above the rotating brush when attached to the vacuum cleaner.

[Appendix 14-3]
The vacuum cleaner according to appendix 14-1 or 14-2, wherein the dust case has an upright portion extending in a vertical direction on the downstream side of the opening.

[Appendix 15-1]
A self-propelled vacuum cleaner that has a lower case and a bumper provided on a side surface and autonomously travels by controlling drive wheels;
A self-propelled vacuum cleaner having a resinous bumper frame located on the outer peripheral side of the bumper on the entire circumference or substantially the entire circumference.

[Appendix 15-2]
The bumper is annular,
The bumper frame is provided on the entire outer periphery of the bumper,
The self-propelled electric vacuum cleaner according to appendix 15-1, wherein the bumper receives a force pressed inward by the bumper frame.

[Appendix 16-1]
A vacuum cleaner having a main accumulation chamber and a duct connected to the main accumulation chamber or one end side of the duct,
An electric vacuum cleaner having a rib provided on an inner surface of the main accumulation chamber above the duct or one end side of the duct.

  According to Supplementary Note 16-1, a vacuum cleaner capable of guiding dust flowing into the main accumulation chamber via a duct or the like can be provided.

[Appendix 16-2]
The duct or one end side of the duct is located below the main accumulation chamber,
The vacuum cleaner according to appendix 16-1, wherein the rib has an inclination that goes upward as it goes from the end side to the center side of the main storage chamber.

DESCRIPTION OF SYMBOLS 1 Self-propelled vacuum cleaner 11 Main body 111 Upper case 112 Lower case 1121 Side brush attaching part 1122 Auxiliary wheel attaching part 1123 Back protrusion 1124 Center front side protrusion 1125 Center rear side protrusion 1126 Exhaust port 1127 Bumper frame 1128 Attachment claw locking part 113 Suction Port 1131 Suction Port 1133 Rotating Brush Motor 114 Drive Mechanism Housing 1141 Arm (Suspension)
1142 Deceleration mechanism 115 Battery housing part 116 Driving wheel 1161 Traveling motor 117 Front lid 118 Airtight member 1181 Bridging part 1182 Swing shaft 1183 Frame part 1184 Removal claw 1185 Energizing part 1186 Driven roller 1187 Inclining part 119 Guide step 1101 Gap 1102 Props Housing 12 Dust sensor unit 121 Frame 122 Light emitting part 1221 Light emitting element 123 Light receiving part 1232 Light receiving element 1239 Transparent resin cap 124 Adhering member 125 Wiring 126 Connector 127 Substrate 13 Scraping brush 14 Rotating brush 141 Shaft part 142 Flocking 143 Nonwoven fabric 1431 Slit 15 Side brush 151 Side brush holder 1511 Mounting claw 1512 Jig insertion hole 152 Side brush motor 153 Root elastic part 1531 Narrow part 1532 Thick part 154 Brush part 155 Mounting claw 1 6 Electric blower 161 Elastic body 17 Auxiliary wheel 171 Grounding part 172 Disk part 173 Fixed shaft 174 Small disk part 18 Bumper 19 Rechargeable battery 2 Control device 21 Control board 210 Sensors (ranging sensor)
211 Sensors (ranging sensors for floors)
22 Switch seat 221 Circular operation button 222 Annular operation button 4 Dust case 41 Main storage chamber 42 Duct 421 Upright portion 43 Handle 431 Holding portion 432 Retaining portion 433 Action point portion 434 Locking portion 44 Backflow control valve 441 Main surface 442 Protruding portion 443 Energizing portion 45 Lid 46 Filter 47 Rib 80 Support plate 90 Center line 91 Arrow 92 Dimensions in the main direction of the dust sensor unit 93 Dimensions on the other end side of the duct (diagonal dimensions)
94 Dimension of one end of duct (vertical dimension)
95 Cleaning brush 951 as an example of props Brush 952 Jig part

Claims (3)

A self-propelled vacuum cleaner having two drive wheels, an electric blower, a rechargeable battery, and a brush having a rotating shaft in the horizontal direction,
The brush have a weight therein,
The brush is a driven rotating brush,
A self-propelled electric vacuum cleaner having another brush driven by a motor . The brush is different from the said another brush, self-propelled vacuum cleaner according to claim 1, characterized in that provided at a position far from the center of the self-propelled vacuum cleaner. The self-propelled electric vacuum cleaner according to claim 1 or 2 , wherein a center of gravity substantially coincides with an axis of the drive wheel .

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