This application claims priority of No. 105118692 and filed in Taiwan R.O.C. on 2016 Jun. 15 and No. 105123054 and filed in Taiwan R.O.C. on 2016 Jul. 21 under 35 USC 119, the entire content of which is hereby incorporated by reference.
Field of the Invention
The present invention relates to an automatic cleaning machine, and more particularly to an automatic cleaning machine having a reciprocately wiping mechanism.
Related Art
Currently, a commercially available sweeping cleaning robot is mainly to remove dust. It usually includes a side brush and a vacuum suction port, and may further include a center brush or a cleaning cloth for mopping. However, since the cleaning cloth is just pulled by the robot, the effect of cleaning stain marks, footprints and fine particles is limited.
A commercially available washing robot (such as iRobot Scooba) is developed which sprays water onto a floor, which brushes the floor by a center brush and then recycles the water by a rubber scraper. Its disadvantage is that the water will be left on the floor when the floor is not even. The robot cannot be effectively used if the floor has slots.
A commercially available mopping robot (such as Mint's floor cleaner) is developed which pulls a cleaning cloth and moves back and forth to mop the floor. Its disadvantage is that the dust will be accumulated in front of the cleaning cloth and cannot be collected in the robot. Its cleaning effect is limited since the wipe frequency is low.
There is a need to develop an improved cleaning robot which can improve the above disadvantages of conventional robots.
It is an objective of an embodiment of the present invention to provide an automatic cleaning machine comprising a reciprocately wiping mechanism for reciprocately wiping a floor; a travelling device for moving the machine; and a control system and a plurality of sensors for detecting an obstacle and detecting the distance from the surrounding environment, so as to establish a map for planning a cleaning path. In an embodiment, the automatic cleaning machine further comprises a vacuum device used for sucking the dust in front of the cleaning cloth on the floor. In an embodiment, the automatic cleaning machine further comprises a spray device used for spraying water on the floor.
According to an embodiment of the present invention, an automatic cleaning machine comprises a reciprocately wiping mechanism, a travelling device and a control system. The reciprocately wiping mechanism comprises the at least one cleaning device and the at least one reciprocating device. The at least one cleaning device is used for being in contact with a floor. The at least one reciprocating device is connected to the at least one cleaning device and makes the at least one cleaning device reciprocately wipe the floor. The travelling device is used to make the automatic cleaning machine travel on the floor. The control system is coupled to the reciprocately wiping mechanism and the travelling device and is used to control the reciprocately wiping mechanism and the travelling device.
In an embodiment, the at least one cleaning device comprises a first cleaning device and a second cleaning device. The at least one reciprocating device is used to make the first cleaning device move in a first direction and make the second cleaning device move in a second direction opposite to the first direction.
In an embodiment, the automatic cleaning machine further comprises an housing. The housing is used for accommodating the at least one reciprocating device of the reciprocately wiping mechanism, the control system and the travelling device. The at least one cleaning device comprises a brush plate, a roller and a cleaning cloth. The brush plate is disposed below a base of the housing. The roller is located between the brush plate and the housing, and rotates on the brush plat or the base, so as to reduce the frictional resistance to the relative motion of the brush plate and the base. The cleaning cloth is disposed at the brush plate and used to be in contact with the floor.
In an embodiment, the automatic cleaning machine further comprises a housing and an elastic element. The housing is used for accommodating the at least one reciprocating device of the reciprocately wiping mechanism, the control system and the travelling device. The elastic element is disposed between the travelling device and the housing, so that the elastic element is capable of pushing the travelling device in a direction away from the automatic cleaning machine.
In an embodiment, the automatic cleaning machine further comprises a vacuum device. The vacuum device comprises an inlet. The dust on the floor is sucked into the inlet by an air flow. The at least one cleaning device comprises a first cleaning device. The inlet is disposed in front of the first cleaning device within a predetermined distance from the first cleaning device, wherein within the predetermined distance, the dust is not accumulated.
In an embodiment, the automatic cleaning machine further comprises a spray device used for spraying water on the floor.
In an embodiment, the travelling device comprises a moving wheel module and a case. The case accommodates the moving wheel module and includes a sleeve. The housing comprises a base, a fixing column, a ring stop and a fixing screw. The fixing column is disposed on the base and projects from the base. The sleeve is sleeved on the outer circumferential surface of the fixing column. The ring stop is disposed at a top side of the fixing column. The fixing screw is screwed into the fixing column, so that the ring stop is fixed at the top side of the fixing column. The end of the elastic element is abutted against the ring stop, and another end of the elastic element is abutted against a portion of the case of the travelling device.
In an embodiment, the at least one reciprocating device comprises a motor, a crankshaft, at least one crank. The crankshaft is driven by the motor to rotate. An end of the at least one crank is connected to the crankshaft, and another end of the at least one crank is connected to a brush plate of the at least one cleaning device and then reciprocately moves as the crankshaft rotates.
In an embodiment, the inlet of the vacuum device is disposed at the brush plate of the first cleaning device.
In an embodiment, the automatic cleaning machine further comprises an electric brush. The inlet of the vacuum device is disposed at the base of the housing. The electric brush is disposed at the base and sweeps the dust into the inlet.
In an embodiment, the automatic cleaning machine further comprises at least one sensor disposed at the front or bottom side of the housing and used for detecting an obstacle or a stair.
In an embodiment, the automatic cleaning machine further comprises a bumper and a limit switch. The bumper is disposed at the outer side of the automatic cleaning machine. The limit switch is used to be pushed by the bumper after the bumper hits an obstacle.
In an embodiment, the automatic cleaning machine further comprises a distance measuring sensor used for measuring the distance from the surrounding environment, so as to establish a map for planning a cleaning path.
The various embodiments of the present invention can achieve the following technical improvements. In an embodiment, the automatic cleaning machine comprises a reciprocating wiping mechanism. The wiping frequency of the cleaning cloth is increased, so that a high-efficiency cleaning machine can be obtained. In an embodiment, the automatic cleaning machine comprises a vacuum device, which is capable of sucking up dust and dirt accumulated in front of the cleaning cloth. In an embodiment, the automatic cleaning machine comprises a spray device. The spray device intelligently sprays water to keep the cleaning cloth optimally moisturized, so that a better cleaning effect can be achieved. In an embodiment, the automatic cleaning machine integrates all of the aforementioned devices and is embodied with an artificial intelligence program to enable the machine to clean the floor of the entire room.
The foregoing features, aspects, and advantages of the present disclosure will now be described with reference to the drawings of preferred embodiments that are intended to illustrate and not to limit the disclosure.
These and other embodiments of the present disclosure will also become readily apparent to those skilled in the art from the following detailed description of preferred embodiments having reference to the attached figures; however, the disclosure is not limited to any particular embodiment(s) disclosed herein. Accordingly, the scope of the present disclosure is intended to be defined only by reference to the appended claims.
According to a conventional robot, the floor is wiped by a cleaning cloth pulled by the robot which moves back and forth, so that the number of times that the robot walks through the floor is the number of times that the floor is wiped. According to another conventional robot, the robot only sweeps the floor without spraying water. Accordingly, the conventional robots cannot effectively clean water stain marks, footprints and fine particles. According to an embodiment of the present invention, an automatic cleaning machine is provided which comprises a reciprocately wiping mechanism reciprocately wiping the floor at high speed; and a pair of travel wheels for moving the machine. In an embodiment, the machine further comprises a spray device used for spraying water on a floor. In an embodiment, the machine may further comprise a microprocessor control system and a variety of sensors which detect obstacles and the outline of the environment and plan a cleaning path. The specific structure will be described in detail below.
Regarding to the reciprocately wiping mechanism. As shown in
Please refer to
The front and rear brush plates 220 and 250 appear to be moving in the opposite directions, so that the reaction force can offset each other, and then the automatic cleaning machine 100 can be stably operated. Please refer to
The rear cleaning device further comprises at least one roller 280, and the rear brush plate 250 has two rails. The automatic cleaning machine 100 has a housing 320. The rollers 280 are fixed to the rear brush plate 250 and are located between the top surface of the rear brush plate 250 and the bottom surface of the base 310 of the housing 320. When the rear brush plate 250 reciprocately moves back and forth, the roller 280 rotate on the surface of the base 310 or the rear brush plate 250 so as to reduce the frictional resistance to the relative motion of the rear brush plate 250 and the base 310. In an embodiment, a chute 281 is formed on the upper side of the base 310, and a part of the rear brush plate 250 is placed in the chute 281. Accordingly, the rear brush plate 250 will not fall down since it is restrained by the chute 281 located above it.
The rotational speed of motor 110 can determine the wiping speed of the cleaning cloth 230 and 260 moving back and forth. Preferably, their wiping speed is 100 to 2000 times per minute, which is a high-performance wiping mechanism.
As above, although a reciprocating wiping mechanism in an embodiment is described in detail. However, the present invention is not limited to the aforementioned structure. The reciprocating wiping mechanism can be any structure as long as the structure can convert rotation motion to linear motion. For example, the reciprocating wiping mechanism in an embodiment may comprise a cam and a lever (not shown). The lever abuts on the cam. The cam has a non-circular shape which may be elliptical; or have an end being semi-elliptical and another end being semicircular. When the cam rotates, the lever can move reciprocately and linearly.
Regarding to the vacuum device. Although the floor can be cleaned by the linear reciprocating motions of the front and rear brush plates 220 and 250, the dust will be accumulated in front of cleaning cloth 230, that is, at the place near to the movable inlet 611 of the vacuum device in
The movable inlet 611 of the vacuum device is located in front of the front edge of the front clean cloth 230. During the operation of the automatic cleaning machine 100, its travelling device moves along a forward direction. The vacuum device sucks dust particles in advance, and then the front clean cloth 230 wipes the portion of the floor where the dust particles located. The movable inlet 611 is located in front of the front edge of the front clean cloth 230 within a predetermined distance. Note that, the vacuum device is capable of sucking up the dust and dirt accumulated in front of the cleaning cloth 230 by use of the air flow 20a, so that the dust and dirt cannot be accumulated in front of the cleaning cloth 230. To achieve the objective of not accumulating the dust and dirt, the person having ordinary skill in the art can decide the above-mentioned determined distance on the basis of experiments carried out under different conditions, such as the different efficiencies of the vacuum devices and the different sizes of the movable inlet 611. The determined distance depends on the efficiency of the vacuum device and the size of the movable inlet 611. The higher the efficiency of the vacuum device is, the larger the determined distance is. As shown in
Regarding to the travelling device. Please refer to
Regarding to the pressure control structure for the tracked wheel. There are two portions of the automatic cleaning machine 100 that are in contact with the floor; one is the cleaning cloth 230 and the other one is the track belt 420. When the pressure applied to the two above-mentioned portions are not uniform, the automatic cleaning machine 100 cannot normally operate. If the pressure applied to the cleaning cloths 230 and 260 is too large, the pressure applied to the track belt 420 is insufficient and then the track belt 420 will slip and fail to move the machine. On the other hand, if the pressure applied to the track belt 420 is too large, the pressure applied to the cleaning cloths 230 and 260 is insufficient and then the floor cannot be cleaned well. As a result, there is a need to design a pressure control structure which can provide a pressure distribution having a fixed or predetermined proportion, so that the machine can travel properly and wipe the floor cleanly.
As shown in
The top end of the spring 440 is abutted against the ring stop 441. The bottom end of the spring 440 is abutted against a portion of the case 402 of the travelling device. Specifically, as shown in
Regarding to the spray device. According to the conventional art, since a robot dryly wipes the floor, it cannot effectively clean water stain marks, footprints and fine particles. According to an embodiment of the present invention, an automatic cleaning machine 100 further comprises a spray device used for spraying water, so that the stain marks can be cleaned easily. As shown in
Regarding to the control system.
As shown in
As shown in
In an embodiment, the automatic cleaning machine 100 further includes a distance measuring sensor 840. Accordingly, it can have the function of using laser to measure the distance between it and the obstacle; or the distance between it and the surrounding environment, so as to establish a map for planning a cleaning path.
The program built into the processor 510 of the control system 500 can automatically control all motors, perform obstacle detection, or plan a clean path to clean the entire room.
The control system 500 includes a remote control receiver 910 and a remote control transmitter 900, which may transmit signals by use of wireless technology, such as infrared radiation (IR) or WIFI, or may be other receivers and transmitters currently available or future developed.
It should be understood that the invention is not limited to the shape of the automatic the cleaner 100.
According to an embodiment of the present invention, the automatic cleaning machine 100 comprises a high-speed reciprocating wiping mechanism. The wiping frequency of the cleaning cloth 230 can be more than 200 times per minute, so that a high-efficiency cleaning machine can be obtained. In an embodiment, the automatic cleaning machine 100 comprises a vacuum device, which is capable of sucking up the dust and dirt accumulated in front of the cleaning cloth 230. In an embodiment, the automatic cleaning machine 100 comprises a spray device. The spray device intelligently sprays water to keep the cleaning cloth 230 optimally moisturized, so that a better cleaning effect can be achieved. According to an embodiment of the present invention, the automatic cleaning machine 100 integrates all of the aforementioned devices and is embodied with an artificial intelligence program to enable the machine to clean the floor of the entire room.
These and other embodiments of the present disclosure become readily apparent to those skilled in the art from the above detailed description of preferred embodiments having reference to the attached figures; however, the disclosure is not limited to any particular embodiment(s) disclosed herein. These and other modifications of this invention, which would be obvious to those skilled in the art, are included within the scope of this invention and the terms of the following claims.
Number | Date | Country | Kind |
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105118692 A | Jun 2016 | TW | national |
105123054 A | Jul 2016 | TW | national |
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Number | Date | Country | |
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20170360269 A1 | Dec 2017 | US |