CN215838742U - Cleaning robot - Google Patents

Abstract

The embodiment of the application provides a cleaning robot. The cleaning robot comprises a host, a space sensing module and an obstacle avoidance sensing module, wherein the space sensing module and the obstacle avoidance sensing module are arranged on a panel of the host, the space sensing module can identify the space size of a current scene in a working environment to judge whether the host can advance in the space, the obstacle avoidance sensing module can provide detection of a first visual angle sensing range and a second visual angle sensing range to judge whether an obstacle exists, a visual field blind area of the first visual angle sensing range is eliminated, the host can execute a cleaning task without dead angles and obstacles, uncertainty in task execution is eliminated, and user requirements are met.

Description

Cleaning robot

Technical Field

The application relates to the field of self-moving robots, in particular to a cleaning robot.

Background

With the progress of science and technology and the continuous improvement of living standard, intelligent cleaning tools are more and more popular. Such as a sweeper, scrubber or scrubber having a self-moving cruise function. In some working scenarios with complex environments and large space ranges, such as different homes, apartments and other household indoor scenarios or business super-areas, commodity building elevator rooms and other open areas of a business environment, the cleaning robot must realize automatic cleaning capability in these complex scenarios. However, the existing cleaning robots have a single way of identifying or sensing obstacles in the working environment, and often have a lot of uncertainty as to whether their cleaning tasks can be actually performed.

Disclosure of Invention

Aspects of the present disclosure provide a cleaning robot that allows the cleaning robot to recognize the presence of obstacles in different sensing ranges and recognize or detect the shape of the obstacles to maintain or correct a cruising path of a cleaning procedure by using a plurality of sensor modules configured on the cleaning robot, thereby eliminating uncertainty in task execution.

An embodiment of the present application provides a cleaning robot, includes: the host is suitable for walking on a working surface of a working environment; the space sensing module is arranged on the host and used for identifying the space size of the current scene in the working environment; and the obstacle avoidance sensing module is arranged on the host and used for detecting whether an obstacle exists in the current scene or not, and the obstacle avoidance sensing module is provided with a first visual angle sensing range and a second visual angle sensing range of the current scene, wherein the second visual angle sensing range comprises a visual field blind area between the first visual angle sensing range and the working surface.

Preferably, the obstacle avoidance sensing module includes a first sensing module and a second sensing module that are arranged at an interval, the first sensing module has the first viewing angle sensing range, the second sensing module has the second viewing angle sensing range, and the second sensing module is further configured to detect three-dimensional data of an obstacle within the second viewing angle sensing range.

Preferably, the first sensing module is a distance sensor, and the second sensing module is a structural light module, a binocular structural light module or a time-of-flight sensor.

Preferably, the cleaning robot further includes an environment sensing module disposed at the top of the host machine for recognizing a spatial scene of the working environment in a surrounding manner.

Preferably, the environment sensing module includes a laser sensor, and the space sensing module includes a camera module.

Preferably, the cleaning robot further comprises a forward-looking buffer module, which comprises a lens, a buffer plate and a sensor group, wherein the buffer plate is arranged below the host, the sensor group is arranged on the buffer plate, and the lens covers one side of the buffer plate far away from the host.

Preferably, the forward-looking buffer module further comprises an anti-collision plate movably arranged below the main machine and capable of reciprocating relative to the main machine body, wherein the buffer plate is arranged on the anti-collision plate, and the sensor group is arranged between the buffer plate and the lens.

Preferably, the anti-collision plate comprises a plate body, a triggering mechanism and a buffering mechanism, wherein the plate body is movably arranged on the host machine and is provided with a first stroke and a second stroke which are close to each other towards the body; the trigger mechanism is configured to trigger a stop motion signal when the plate body is subjected to external force to generate displacement of the first stroke; the buffering mechanism is configured to elastically buffer the plate body when the plate body generates the displacement of the second stroke.

Preferably, the cleaning robot further includes one or more ranging modules, disposed on the main machine, for detecting a distance between a side surface of the main machine and a corresponding side of the working environment or detecting whether the obstacle exists within the distance.

The present application also provides a cleaning robot, including: the host is suitable for walking on a working surface of a working environment; and the obstacle avoidance sensing module is arranged on the host and used for detecting whether a forward path of the host is blocked by an obstacle or not, wherein the obstacle avoidance sensing module is provided with a first visual angle sensing range and a second visual angle sensing range of a current scene in the working environment, and the second visual angle sensing range comprises a visual field blind area between the first visual angle sensing range and the working surface.

Preferably, the second sensing range is located below the first sensing range, and the obstacle avoidance sensing module is further configured to detect three-dimensional data of an obstacle within the second viewing angle sensing range.

Preferably, the cleaning robot further includes a space sensing module and an environment sensing module, which are respectively disposed on the host, the space sensing module is configured to identify a space size of the current scene, and the environment sensing module is configured to identify a space scene of the working environment in a surrounding environment.

In the embodiment of the application, the space sensing module is used for identifying the space size of a current scene in a working environment, the host is provided for judging whether the current scene can travel in the space, the obstacle avoidance sensing module is used for detecting whether an obstacle exists in a first visual angle sensing range and a second visual angle sensing range of the current scene, wherein the second visual angle sensing range comprises a visual field blind area of the first visual angle sensing range, so that the second visual angle sensing range is complementary to the first visual angle sensing range, the obstacle can be detected more widely, the host can modify a forward path to avoid the obstacle, and uncertainty in the process of executing a cleaning task is eliminated. In addition, in the embodiment configured with the environment sensing module, the spatial scene of the working environment is identified through the environment sensing module, so that the autonomous image construction and obstacle avoidance of the cleaning robot are realized, the cleaning efficiency of the cleaning robot is improved, and the requirements of customers are met.

Drawings

The accompanying drawings, which are included to provide a further understanding of the application and are incorporated in and constitute a part of this application, illustrate embodiment(s) of the application and together with the description serve to explain the application and not to limit the application. In the drawings:

fig. 1 is a perspective view of a cleaning robot according to an embodiment of the present application.

Fig. 2 is a schematic view of a sensing range of the obstacle avoidance sensing module according to the embodiment of the present application.

Fig. 3 is a flowchart of an obstacle avoidance method of the cleaning robot according to the embodiment of the present application.

Fig. 4 is a perspective view of a cleaning robot according to another embodiment of the present application.

Fig. 5 is a flowchart of an obstacle avoidance method of a cleaning robot according to another embodiment of the present disclosure.

Fig. 6 is a block diagram of a cleaning robot according to another embodiment of the present application.

Fig. 7 is a perspective view of a cleaning robot according to another embodiment of the present application.

Fig. 8 is a partially exploded view of a cleaning robot according to other embodiments of the present application.

Fig. 9 is a flowchart of an obstacle avoidance method of a cleaning robot according to another embodiment of the present disclosure.

Fig. 10 is a perspective view of another perspective view of a cleaning robot according to another embodiment of the present application.

Detailed Description

In order to make the objects, technical solutions and advantages of the present application more apparent, the technical solutions of the present application will be described in detail and completely with reference to the following specific embodiments of the present application and the accompanying drawings. It should be apparent that the described embodiments are only some of the embodiments of the present application, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present application.

It should also be noted that the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation, an element defined by the phrase "comprising an … …" does not exclude the presence of other like elements in a process, method, article, or apparatus that comprises the element.

The cleaning robot disclosed in the embodiment of the present application is a self-moving robot with an auto-cruising function, such as a sweeper, a scrubber, a floor scrubber or a multifunctional compound machine, and may be a household cleaning robot suitable for performing cleaning tasks in a home or apartment environment, or a commercial cleaning robot suitable for performing cleaning tasks in a commercial environment such as a business super region or a commercial building elevator room. This type of cleaning device is usually equipped with a base station (charging station) for the host of the cleaning robot to stop and to be connected to the base station for charging by a charging device. For convenience of description, in the following embodiments of the present application, the cleaning robot is an exemplary sweeper, and is not intended to limit the technical scope of the present application.

Referring to fig. 1 and 2, a cleaning robot 1 according to an embodiment of the present disclosure includes a main body 10 and an obstacle avoidance sensing module 20. The host 10 has opposite top 110 and bottom 120, a front panel 130 facing the forward direction of the host 10 and a back panel 140 facing the backward direction of the host 10, wherein the forward direction and the backward direction are opposite. The bottom 120 of the main frame 10 is provided with a driving wheel electrically connected to the control module inside the main frame 10 and driven by the control module to drive the main frame 10 to walk on a working surface of a working environment, for example, on the ground, on a table top or a table top in a space scene in an apartment room, or to walk on a wall surface or a glass surface by being adsorbed by an adsorption module. Further, a roll brush and an edge brush 121 as cleaning tools are provided on the side of the bottom 120 of the main body 10 adjacent to the panel 130. The edge brush 121 is positioned adjacent to the edge of the main body side 150 and partially extends beyond the side 150 during operation to provide a main body side-to-side cleaning range.

The obstacle avoidance sensing module 20 is disposed on the panel 130 of the host 10, and includes a first sensing module 210 and a second sensing module 220. The first and second sensing modules 210 and 220 may be arranged in a horizontal direction of the panel 130 or in a vertical direction of the panel 130. In the present embodiment, the first sensing module 210 and the second sensing module 220 are disposed vertically along the vertical direction of the panel 130 for illustration, but not limited thereto. The first sensing module 210 includes a distance sensor, such as an ultrasonic sensor, a photoelectric sensor, a displacement sensor, a radar sensor, or a LiDAR sensor, for detecting whether an obstacle exists in a current scene corresponding to a forward path of the host 10 in a spatial scene, and the second sensing module 220 may be a structural Light module, a binocular structural Light module, or a time-of-flight sensor, and may detect three-dimensional data of the obstacle in addition to detecting whether the obstacle exists in the current scene, and provide a control module to establish a three-dimensional shape of the obstacle and determine a specific type of the obstacle, for example, determine whether the obstacle is a slipper, a toy, a box, or the like according to the three-dimensional data.

As shown in fig. 1 and 2, the first sensing module 210 is disposed on a side of the panel 130 near the top 110 and has a first viewing angle sensing range 211 of the current scene, for example, a sensing range of 7 ° to 120 °. The second sensing module 220 is disposed below the first sensing module 210 on a side close to the bottom 120, and has a second viewing angle sensing range 221 of the current scene, for example, a sensing range of 30 ° to 60 °. The second viewing angle sensing range 221 is complementary to the first viewing angle sensing range 211, for example, the second viewing angle sensing range 221 is partially overlapped with the first viewing angle sensing range 211, or the first viewing angle sensing range 211 is separated from the working surface by a distance to form a blind field of the first viewing angle sensing range 211, and the second viewing angle sensing range 221 includes the blind field. Therefore, the situation of misjudgment caused by the echo interference of the working surface or the object close to the working surface when the first sensing module 210 detects in the current scene can be reduced or avoided. Therefore, the view dead zone can be regarded as a sensing error zone which is likely to cause the first sensing module 210 to perform the erroneous determination. With the aid of the second sensing module 220, it can be more accurately detected whether an obstacle is actually present in the area, and the type of the obstacle. The control module can control the host 10 to continuously move towards the originally planned forward path in the current scene according to the detection and judgment results, or modify the forward path to bypass so as to avoid the blockage of the obstacle.

The application of the cleaning robot of the present embodiment and the obstacle avoidance method when encountering an obstacle are further described below with reference to application scenarios.

Referring to fig. 1 to 3, the main body 10 of the cleaning robot 1 is adapted to walk on the floor in an apartment building, and in this spatial scenario, the main body 10 may detect whether there is an obstacle in the forward path of the main body 10 before and/or during traveling in the forward direction within the first viewing angle sensing range 211 in the current scenario through the first sensing module 210 (S110). In the above steps, the first sensing module 210 may detect an object (e.g., a table or a chair, a locker, etc.) placed on the ground with a high height, and transmit related data to the control module in the main frame 10, so as to determine whether the object appears on the advancing path of the main frame 10 and becomes an obstacle through the control module. If not, the host computer 10 keeps the original path to continuously execute the cleaning task (S111); if yes, the control module modifies the forward path of the host computer 10, so that the host computer 10 deviates from the forward path to avoid the obstacle (S113), and returns to the forward path after bypassing the obstacle to execute the cleaning task, or executes the cleaning task along the modified forward path.

There may be some objects of relatively low height, such as slippers, books, or toys, etc., generally above the ground, which may fall into the blind field of view of the first sensing module 210 and become obstacles in the advancing path of the main body 10. At this time, during the cleaning task continuously performed by the host computer 10 along the forward path, whether an obstacle exists in the forward path is detected within the second viewing angle sensing range 221 located below the first viewing angle sensing range 211 in the current scene by the second sensing module 220 (S130). If not, the host computer 10 keeps the original path to continuously execute the cleaning task (S131); if yes, the three-dimensional data of the obstacle is detected by the second sensing module 220 and transmitted to the control module of the host computer 10 (S133); and establishing a three-dimensional model of the obstacle according to the three-dimensional data through the control module, and judging whether the host 10 can pass the obstacle (S135). If not, the control module modifies the forward path of the host computer 10 to make the host computer 10 deviate from the forward path to avoid the obstacle (S137), and the host computer returns to the forward path after bypassing the obstacle to execute the cleaning task, or the cleaning task is executed along the modified forward path. If so, the host computer 10 continues to advance along the original path and cross the obstacle (S139).

Therefore, when the cleaning robot provided by the embodiment of the application executes a cleaning task, the first sensing module and the second sensing module sense objects with different volume sizes on the forward path of the host machine, and the control module can make a better judgment on whether obstacles exist on the path in a carpet type sensing mode covering a view blind area, so that the cleaning robot can execute the cleaning task in different areas in a space scene more reliably.

As shown in fig. 4 and 5, a cleaning robot according to another embodiment of the present invention is substantially the same as the cleaning robot according to the above-mentioned embodiment, and the difference between the cleaning robot 1 according to the present embodiment includes a space sensing module 30 in addition to the obstacle avoidance sensing module 20, and the space sensing module is disposed on a panel 130 of the main body 10. The space sensing module 30 includes at least a camera, and is disposed on a side of the panel 130 adjacent to the top 110, which may be between the top 110 and the first sensing module 210, or adjacent to a lower edge of the first sensing module 210.

The space sensing module 30 is configured to identify a space size of a current scene corresponding to an advancing path of the host 10 in a working environment of the host 10, so as to determine whether the size of the host 10 is enough to smoothly pass along the advancing path in the space of the current scene without being blocked by an obstacle above or on the left and right sides, where the obstacle may be a door panel, a door frame or a wall surface, a table leg or a chair leg beside a door gap that the host 10 may encounter when performing a task. The space size of the current scene may be a space size when no obstacle exists on the forward path, or may be a space size when an obstacle exists on the forward path. In a scene with an obstacle, the space sensing module 30 may detect the size of the obstacle obstructing the forward direction of the host 10, measure the size of the space left by subtracting the size of the obstacle from the space of the current scene through the control module, and compare the measured size with the size of the host 10 to determine whether the host 10 can pass through smoothly.

Referring to fig. 4 to 5, therefore, when the cleaning robot 1 of the present embodiment performs a cleaning task, in addition to the aforementioned embodiment, the first sensing module 210 can detect whether there is an obstacle in the forward path of the host 10 in the first view angle sensing range of the current scene, and the second sensing module 220 can detect whether there is an obstacle and three-dimensional data of the obstacle in the forward path in the second view angle sensing range of the current scene, the obstacle avoidance method further includes identifying the space size of the current scene through the space sensing module 30 (S210), then identifying whether there is an obstacle in the current scene through the space sensing module 30 (S230), and if so, measuring and calculating the space size between the space size and the obstacle through the control module (S231); and comparing the size of the host with the size of the gap by the control module (S233), and if the size of the host 10 is larger than the size of the gap, the control module modifies the forwarding path or stops the host from moving (S235). On the contrary, if the size of the host computer 10 is smaller than the size of the gap, the host computer 10 performs the cleaning task along the original forward path (S232), so that the cleaning task on the same path is not interrupted.

Based on the above, in an application scenario, when the host computer 10 performs a cleaning task along the forward path, the space sensing module 30 may first detect the space size of the current scene and whether there is an obstacle. When encountering an obstacle, the space sensing module 30 detects a specific profile of the obstacle in front, and then calculates the size of the remaining space after deducting the size of the obstacle to determine whether the host 10 can pass through smoothly. Alternatively, after the first sensing module 210 of the obstacle sensing module 20 detects the first sensing range of the current scene and detects an obstacle, the size of the obstacle is detected by the space sensing module 30, and then the remaining space is calculated. If the remaining space is still suitable for the host computer 10 to pass through, the host computer 10 continues to perform the cleaning task along the forward path. For example, the space sensing module 30 or the first sensing module 210 of the cleaning robot 1 detects the presence of the stools on the proceeding path of the main machine 10. At this time, the space sensing module 30 detects the specific contours of the seat and the legs of the short stool, so as to calculate the size of the space surrounded by the seat, the legs and the ground, and thus, it can be determined whether the size of the host 10 is smaller than the size of the space, if so, the host 10 passes along the original forward path; if not, the advancing path is modified, and the cleaning task is continuously executed after the obstacle is avoided.

Furthermore, in the above-mentioned embodiment or some embodiments of the present application, the top portion 110 of the host 10 is further provided with an environment sensing module 40, which may be, but is not limited to, a laser sensor or a light sensor, etc. Moreover, the environment sensing module 40 may be disposed on the top 110 of the host 10 in a surrounding manner or in a rotatable manner relative to the host 10, so as to identify the spatial scene of the entire working environment in a full angle of 360 °, including the distances between the surrounding boundaries and various objects relative to the host 10, so that the control module can establish a working map and plan an auto-cruise route according to the data. Therefore, in such an embodiment, the host computer 10 identifies the spatial scene of the working environment through the environment sensing module 40 before detecting the current scene through the space sensing module 30, and obtains the current position of the host computer 10 and the default cleaning path after the working map is built. Next, after the current scene of the host forward direction is identified by the space sensing module 30, the space sensing module 30 and the obstacle avoidance sensing module 20 execute the corresponding procedures as in the foregoing embodiments.

Referring to fig. 6 to 10, similarly, a cleaning robot 1 according to another embodiment of the present disclosure includes a main body 10; a space sensing module 20 and an obstacle avoidance sensing module 30 disposed on the host panel; and an environment sensing module 40 disposed on top of the host 10. The host 10 is provided therein with a control module 160, which includes a processor, a memory, and the like, and is used for performing a series of control procedures such as power control, motor control, signal acquisition, and data operation. Therefore, each module is disposed on the host 10 in a hardware manner, and is also electrically connected to the control module 160 of the host 10. The control modules 160 of the host 10 are electrically connected to the control modules 160, respectively, so as to complete application programs corresponding to the host 10 executing automatic cruising and obstacle avoidance, such as establishing a work map, planning a clean path, identifying a space size, identifying an obstacle, controlling a traveling direction of the host 10, and the like, through mutual cooperation. In addition, one or a combination of the forward looking buffer module 50, one or more ranging modules 60, and the charging location module 70 may be optionally disposed on the host 10.

Wherein, the front buffer module 50 can be disposed under the panel 130 of the host 10 adjacent to one side of the second sensing module 220, and can be, but not limited to, integrated with the anti-collision plate 131 under the panel 130. The anti-collision plate 131 comprises a plate body, a trigger mechanism and a buffer mechanism, wherein the plate body is movably arranged below the panel 130 of the host computer 10 and has a first stroke and a second stroke which are close to each other towards the body of the host computer 10; the trigger mechanism is configured to trigger a motion stop signal when the plate body generates vibration or displacement of a first stroke relative to the main body of the host under the action of external force; the buffer mechanism comprises an elastic member such as a compression spring or an elastic sheet, and is configured to perform elastic buffer or elastic return to the initial position on the plate body under the condition that the plate body generates the second stroke displacement. The anti-collision plate 131 is a device with a buffering function, which can be collapsed relative to the main body of the main body 10 by the first stroke and the second stroke when the bottom side of the panel 130 is impacted by an external force, and can be actively restored by the buffering mechanism when the external force disappears. When the plate body is acted by external force, the trigger mechanism triggers a motion stop signal to decelerate and stop the host to avoid the host being extruded and damaged.

Forward looking cushion module 50 includes a lens 510, a cushion plate 520, and a sensor group 530. The buffer plate 520 is disposed on the impact plate 131 and between the impact plate 131 and the lens 510. The sensor group 530 includes one or more sensors, which may be, but are not limited to, one of or a combination of infrared sensors, laser sensors, ultrasonic sensors, and time-of-flight sensors. The sensor group 530 is disposed on the buffer board 520, and the transmitter and the receiver thereof are electrically connected to the control module 160. The lens 510 covers the buffer plate 520, and is used to filter, prevent dust, and protect the sensor group 530, and also used as a transmission medium for the light (e.g., infrared light) emitted by the sensor group 530, so as to expand the detection range.

Therefore, the forward looking bumper module 50 can extend the sensing range in front of and below the host computer 10, better identify the presence of obstacles, their type and specific profile, compensate for dead zones of sensors in other modules, e.g., detect low obstacles, and thus enable the host computer 10 to avoid low objects. In addition, the sensing of the obstacle in the lateral direction of the main unit 10 can also be recognized by the anti-collision plate and the lateral sensor, and fed back to the control module 160 for calculation and avoidance.

One or more of the ranging modules 60, 61, 62 each carry one or a combination of infrared ranging sensors, ultrasonic sensors, or other sensors suitable for sensing distance. In this embodiment, the distance measuring modules 60, 61, 62 including different sensors may be selectively disposed at different positions of the host 10 according to different usage requirements, wherein when the position of the sensor is disposed on the side 150 of the host 10, the sensor is used as a side sensor. For example, the distance measuring module 60 having a sensor (e.g., an infrared sensor) with an extended edge point distance measuring function is disposed on the side 150 of the host 10 adjacent to the bottom 120 and the side of the panel 130, so as to detect the distance between the side 150 and the side corresponding to the side 150 of the host 10 in the working environment. This scenario typically occurs when the host 10 travels along a forward path to the wall-to-floor boundary and must turn and walk appropriately close to the wall to offset to the right or left for cleaning tasks. At this time, the host computer 10 can effectively identify the welting distance between the side surface 150 and the wall surface through the ranging module 60, so that the host computer 10 can more effectively welt (i.e. more effectively close to the boundary between the wall surface and the ground) to clean the boundary area in which dirt is easily accumulated in the work environment.

In the application scenario of the above welt cleaning, the host 10 may encounter obstacles protruding from the wall or protruding from furniture such as a sofa or a low cabinet in some cases, because the host is on the advancing path of the welt cleaning. Therefore, the distance measuring module 61 with the ultrasonic sensor can be selectively arranged on the side 150 of the main machine 10, so that whether an obstacle (especially a transparent obstacle) exists on the right side or not can be identified when the main machine 10 is cleaned on the right side, and the main machine 10 can avoid the obstacle. In this scenario, the avoidance method of the cleaning robot 1 includes: the distance between the side 130 of the host computer 10 and the side corresponding thereto in the working environment is detected by the ranging module 60 (S310), for example, the distance between the side 130 of the host computer 10 and a wall surface is detected. Then, the control module 160 controls the main unit 10 to move closer to or away from the corresponding side according to the distance (S330), so that the cleaning range of the main unit 10 in the lateral direction matches the distance. In some cases, the side 150 of the main body 10 may be too close to the wall surface to cause a collision, or too far from the wall surface to exceed the cleaning range of the side brush 121. Therefore, after the distance between the side surface 150 of the main body 10 and the wall surface is measured, the main body 10 is controlled to be shifted to further adjust the distance within the cleaning range of the side brush 121. Then, when the host computer 10 walks along the side, the distance measuring module 61 detects whether the distance is blocked by an obstacle (S350), and if not, the host computer 10 walks along the side to perform a cleaning task (S351). If so, the control module 160 modifies the forward path (S353) to allow the host computer 10 to avoid.

In addition, a distance measuring module 62 with an infrared sensor may be disposed on the back plate 140 of the host 10, so that when the host 10 needs to be retracted to change a forward path in a narrow space or when a task is completed, a rear spatial distance of the host 10 may be measured to prevent the host 10 from colliding with a wall or other obstacles in the process of being retracted. When the mobile phone returns to the base station (charging dock), if the back panel 140 of the host 10 is provided with a charging location module, the charging location module 70 can be used to detect the relative position of the host 10 when combined with the mating charging dock, so as to perform location charging. The charging positioning module may be disposed on the back plate 140 adjacent to the distance measuring module 62, or may be integrated with the distance measuring module 62.

Although the application scenario of the above embodiment is exemplified by a spatial scenario in an apartment, the cleaning robot provided in the embodiment of the present application can better perform a cleaning task for a commercial environment with a wider space and a more complex environment. The technical solution provided by the embodiment of the present application is briefly described below with reference to a business application scenario.

When the cleaning robot provided by the embodiment of the application is used as a commercial cleaning robot, the cleaning robot can be applied to the ground of an open area or a public area of an exhibition hall, a shopping mall (such as a business super area and a commodity building elevator hall), a bank, a hospital, an office building, a subway station, a hotel and the like to perform cleaning tasks.

For example, a sweeping and mopping integrated cleaning robot works in a shopping mall to clean the floor of the shopping mall. The cleaning robot can be started by a worker in a department of cleaning in a market only by touching a starting control key of the cleaning robot. After the cleaning robot is started, the cleaning robot carries out 360-degree environment recognition on a space scene of a working environment through the environment sensing module, then establishes a working map for recognized data through the control module in the host computer, and judges whether the same working map exists in the database. If the current space scene is the clean space scene, the control module controls the host to execute the cleaning task according to the corresponding clean path, and if the current space scene is not the clean space scene, the control module plans the clean path of the current space scene according to the environment recognition result. And then, controlling the host to execute application programs corresponding to the automatic cruise, obstacle avoidance and the like. At the moment, the cleaning robot can move along the cleaning path, and cleaning procedures such as cleaning, mopping and the like are carried out on the ground in the moving process, so that workers do not need to follow the cleaning procedures.

Compared with a household cleaning robot, the size of the commercial cleaning robot is larger, and the difficulty of avoiding the obstacle by the main machine is invisibly increased. Therefore, in a commercial scene, the cleaning robot provides a more comprehensive obstacle avoidance mode through the synergistic effect of the modules. For example, the obstacle avoidance sensing module can eliminate a detection blind spot in front of the host, and the space sensing module can identify the size of the obstacle, so that the control module can accordingly judge whether the host can freely pass through the original cleaning path. The forward-looking buffer module can make up the detection blind area of the sensors in other modules and can be used for detecting objects and the like which are lower on the ground. Therefore, the cleaning robot provided by the embodiment of the application can reliably execute the cleaning task in a large space with a complex environment, and the use convenience and the cleaning effect brought by the cleaning robot are very obvious.

The above description is only an example of the present application and is not intended to limit the present application. Various modifications and changes may occur to those skilled in the art. Any modification, equivalent replacement, improvement, etc. made within the spirit and principle of the present application should be included in the scope of the claims of the present application.

Claims (14)

1. A cleaning robot, characterized by comprising:

the host is suitable for walking on a working surface of a working environment;

the space sensing module is arranged on the host and used for identifying the space size of the current scene in the working environment; and

the obstacle avoidance sensing module is arranged on the host and used for detecting whether an obstacle exists in the current scene or not, and the obstacle avoidance sensing module is provided with a first visual angle sensing range and a second visual angle sensing range of the current scene, wherein the second visual angle sensing range comprises a visual field blind area between the first visual angle sensing range and the working surface.

2. The cleaning robot as claimed in claim 1, wherein the obstacle avoidance sensing module includes a first sensing module and a second sensing module arranged at an interval, the first sensing module has the first viewing angle sensing range, the second sensing module has the second viewing angle sensing range, and the second sensing module is further configured to detect three-dimensional data of an obstacle within the second viewing angle sensing range.

3. The cleaning robot of claim 2, wherein the first sensing module is a distance sensor and the second sensing module is a structural light module, a binocular structural light module, or a time-of-flight sensor.

4. The cleaning robot of claim 1, further comprising an environment sensing module disposed on the host computer for recognizing a spatial scene of the working environment in a landscape orientation.

5. The cleaning robot of claim 4, wherein the environment sensing module includes a laser sensor and the space sensing module includes a camera.

6. The cleaning robot of claim 1, further comprising a forward looking bumper module including a lens, a bumper plate disposed below the main body, and a sensor set disposed on the bumper plate, the lens overlying a side of the bumper plate away from the main body.

7. The cleaning robot as claimed in claim 6, wherein the forward view bumper module further comprises an impact prevention plate movably disposed below the main body and reciprocally displaceable with respect to the main body, wherein the bumper plate is disposed on the impact prevention plate, and the sensor group is interposed between the bumper plate and the lens.

8. The cleaning robot of claim 7, wherein the bumper plate comprises a plate body, a trigger mechanism and a buffer mechanism, the plate body is movably disposed on the main body and has a first stroke and a second stroke that converge toward the main body; the trigger mechanism is configured to trigger a stop motion signal when the plate body is subjected to external force to generate displacement of the first stroke; the buffering mechanism is configured to elastically buffer the plate body when the plate body generates the displacement of the second stroke.

9. The cleaning robot of claim 1, further comprising one or more ranging modules disposed on the main body for detecting a distance between a side of the main body and a corresponding side of the working environment or detecting whether the obstacle is present within the distance.

10. A cleaning robot, characterized by comprising:

the host is suitable for walking on a working surface of a working environment; and

the obstacle avoidance sensing module is arranged on the host and used for detecting whether a forward path of the host is blocked by an obstacle or not, wherein the obstacle avoidance sensing module is provided with a first visual angle sensing range and a second visual angle sensing range of a current scene in the working environment, and the second visual angle sensing range comprises a visual field blind area between the first visual angle sensing range and the working surface.

11. The cleaning robot as recited in claim 10, wherein the second sensing range is located below the first sensing range, and the obstacle avoidance sensing module is further configured to detect three-dimensional data of obstacles within the second perspective sensing range.

12. The cleaning robot as claimed in claim 10, further comprising a space sensing module and an environment sensing module respectively disposed on the host computer, wherein the space sensing module is configured to identify a space size of the current scene, and the environment sensing module is configured to identify a space scene of the working environment in a surrounding environment.

13. The cleaning robot of claim 10, further comprising a forward looking bumper module including a lens, a bumper plate disposed below the host machine, and a sensor set disposed on the bumper plate, the lens overlying a side of the bumper plate away from the host machine.

14. The cleaning robot as claimed in claim 13, wherein the forward view bumper module further includes an impact plate movably disposed below the main body and reciprocally displaceable with respect to the main body, wherein the bumper plate is disposed on the impact plate, and the sensor group is interposed between the bumper plate and the lens.

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