Detailed Description
The following describes embodiments of the present invention in further detail with reference to the accompanying drawings.
As shown in fig. 14, the floor-mopping robot workstation proposed by the present invention includes: the mopping machine comprises a mopping machine workbench 2, a water purification and cleaning device 5 and a sewage recovery device 6; the mopping machine workbench 2 is used for charging the mopping robot, cleaning mop cloth and recycling sewage.
In some embodiments of the present invention, the floor mopping machine workbench 2 has two second metal charging pole pieces at the front end, so as to realize the function of charging the floor mopping robot.
The front end of the chassis of the mopping robot is provided with two rotatable discs, the discs can be adhered with mops, the inside of the mopping robot is provided with disc rotating power by a motor, both ends of a motor rotating shaft are provided with threads, the two discs are driven by gears to synchronously rotate, and the mopping robot realizes the cleaning effect on the ground by rotating the mops. Or the mopping robot has a mopping plate capable of moving back and forth at the front end and the rear end of the chassis, the mopping plate can be adhered with a mop cloth, a motor provides power for the mopping plate to move back and forth inside the mopping robot, a conversion device is fixed at the two ends of a motor shaft, so that the motor shaft is converted to other positions from the center, and the mopping plate can be driven to reciprocate back and forth when the motor rotates by combining a mechanical support, so that the mopping plate can be cleaned by reciprocating back and forth.
As shown in fig. 3, the clean water washing device 5 includes a clean water storage tank 51, a clean water pump 52, a clean water pipe 53, an air inlet hole 54, a nozzle 55, a water level detection device 56, and a clean water storage tank in-place detection device 57.
The purified water storage box 51 is placed in the workstation, an air inlet and a water outlet are reserved, and a cover at the top end of the purified water storage box 51 can be opened, so that a user can add water conveniently; the water outlet of the purified water storage tank 51 corresponds to the water inlet of the purified water pipe 53; the nozzle 55 is installed on the floor-mopping machine table 2, and the clean water pipe 53 is connected to the nozzle 55 by the clean water pump 52.
Two third metal electrode plates are arranged outside the purified water storage box 51 and correspond to the two metal contacts of the workstation to ensure the power supply of the water level detection device 56. The water level detecting device 56 is located at the bottom end of the interior of the purified water storage box 51, and when the water level reaches the water storage position at the bottom of the purified water storage box, the water level detecting device 56 is triggered to perform the water level detecting function.
The clean water storage tank in-place detection device 57 is constituted by a micro switch, and when the clean water storage tank 51 is mounted in place, the micro switch is triggered to indicate that the clean water storage tank 5 is mounted.
When the mopping robot returns to the work station, the cooperative work center 7 controls the water pump 52 to start working when detecting that the clean water storage box 51 is installed based on the state of the clean water storage box on-site detection device 57, so that the clean water in the clean water storage box 51 is sucked to the nozzle 55 through the water pipe 53, and then the water is uniformly sprayed to the mopping cloth.
In some embodiments of the present invention, as shown in fig. 12, a plurality of protrusions 21 are formed on the surface of the floor-mopping machine platform 2 corresponding to the position of the mop cloth of the floor-mopping robot, and after the floor-mopping robot finishes sprinkling water on the floor-mopping robot, the floor-mopping robot controls the mop cloth to rotate or vibrate, and the mop cloth rubs against the surface of the protrusions on the floor-mopping machine platform 2, so that dust and sewage on the mop cloth flow down.
Or, in some embodiments of the present invention, as shown in fig. 13, the floor mopping machine workbench 2 is provided with a rotating device 22 corresponding to the position of the mop cloth of the floor mopping robot, the rotating device comprises two motors, each motor shaft is provided with a rotating disc, and the surface of each rotating disc is provided with a plurality of protrusions 21; when the mop is cleaned, the water pump 52 of the water cleaning device 5 is started to suck the purified water in the purified water storage box 51 into the nozzle 55 through the water pipe 53, then the water is uniformly sprayed onto the mop, the motor of the floor mopping machine platform 2 is controlled by the cooperative control center 7 to be started to drive the two rotating discs to rotate, and the raised surface on the rotating discs rubs with the mop, so that the dust and the sewage on the mop flow down.
Or, in some embodiments of the present invention, a vibration device is disposed on the floor mopping machine workbench 2 corresponding to the mop cloth of the floor mopping robot, and a plurality of protrusions are disposed on the surface of the vibration device, after the water is sprayed on the mop cloth, the vibration device of the floor mopping machine workbench 2 is controlled by the cooperative control center 7 to vibrate, so that the dust and the sewage on the mop cloth flow down.
In some embodiments of the present invention, a water inlet is added to the top of the purified water storage 51, so that the purified water storage can be directly connected to a household faucet through a water pipe, thereby achieving the function of automatic water feeding.
In some embodiments of the present invention, the device for detecting the clean water storage box 51 in place comprises a hall element and a magnet, the magnet is installed in the clean water storage box, the hall element is installed at a position corresponding to the magnet in the workstation, and when the clean water storage box 51 is installed in place, the hall element is triggered to indicate that the clean water storage box is installed.
In some embodiments of the present invention, the wastewater recovery unit 6, as shown in FIG. 4, includes a wastewater storage tank 61, a wastewater recovery pump 66, a wastewater recovery pipe 62, an exhaust hole 63, a water level detection unit 64, and a wastewater storage tank in-place detection unit 65.
The sewage storing box 61 is placed in the workstation, and an exhaust hole and a water inlet are reserved, the top cover of the sewage storing box 61 can be opened, a user can pour out sewage conveniently, the water inlet of the sewage storing box 61 corresponds to the water outlet of the sewage recovery pipe 62, and the sewage recovery pipe 62 is connected to the floor mopping machine workbench 2 through the sewage recovery pump 66.
Two fourth metal electrode plates are arranged outside the sewage storage box 61 and correspond to the two metal contacts of the workstation, so that the power supply of the water level detection device 64 is ensured.
The water level detection device 64 is located at the top end of the interior of the sewage storage tank 61, and when the water level reaches the maximum water storage position of the sewage storage tank 61, the water level sensor 64 is triggered to perform the water level detection function. Or, when the water level reaches the maximum water storage position of the sewage storage tank 61, the buoyancy of the water pushes up the buoyancy ball of the water level detection device 64 to trigger the micro switch, so as to perform the water level detection function.
The sewage storage tank in-place detection device 65 is composed of a microswitch, and when the sewage storage tank 61 is installed in place, the microswitch can be triggered to indicate that the sewage storage tank is installed.
After the mop is cleaned, the sewage recovery pump 66 of the sewage recovery device 6 is started to work, the sewage on the worktable 2 of the mopping machine is sucked into the sewage storage box 61 through the sewage recovery pipe 62, the gas in the sewage storage box 61 is discharged from the exhaust hole 63, and the air pressure in the sewage storage box 61 is kept stable. When the water level detecting means 64 in the sewage storage tank 61 detects that the water has reached the maximum water level, the water level alarm program is triggered.
The sewage recovery device 6 can be added with a drain pipe interface to directly discharge the sewage in the sewage storage 61 to the sewer through the drain pipe.
In some embodiments of the present invention, as shown in fig. 5, a filtering device 67 and a second water level detecting device 68 are added to the sewage collecting device 6, the filtering device 67 is installed at the front end or inside the sewage collecting pipe 62, and may be made of a filter core material such as sponge or ceramic, and the sewage enters the filtering device 67 through the sewage collecting pipe 62 and then enters the sewage storage tank 61.
The water outlet 69 is added at the middle and low position of the side of the sewage storage box 61, and the recycling water pump 66B is connected to the nozzle of the floor mopping machine workbench 2 through the water pipe 70, so that sewage can be reused for cleaning mops after being filtered and precipitated, and the frequency of water adding and pouring of a user is reduced.
The water outlet 69 is arranged at the same height as the reusable water level; the reusable water level indicates: the sewage lower than the reusable water level is not reusable, and the sewage higher than the reusable water level is the sewage which can be reused after precipitation.
The second water level detecting means 68 is located at the same height as the water outlet 69, and when the water level reaches the position of the water outlet 69 of the sewage storage tank 61, the second water level sensor 68 is triggered to indicate the presence of the reuse sewage.
The sewage storage box in-place detection device 65 comprises a Hall element and a magnet, wherein the magnet is arranged in the sewage storage box 61, the Hall element is arranged at the position of the workstation corresponding to the magnet, and when the sewage storage box is arranged in place, the Hall element can be triggered to indicate that the sewage storage box is arranged.
Before describing the steps of cleaning mops based on the floor mopping robot workstation, the invention firstly describes the relevant working processes in the floor mopping robot workstation:
and (3) an alarm process a: and sending alarm information to a user in a mode of voice broadcasting fault content, displaying the fault content on a display screen and/or prompting the fault content through an APP pop-up window of the intelligent terminal.
Mop wetting process i: firstly, detecting whether the purified water storage box 51 is installed in place or not by the purified water storage box in-place detection sensor 57, if not, executing an alarm process a, and stopping working; if the clean water storage tank 51 is mounted in place, the clean water pump 52 of the clean water washing apparatus is operated to pump water from the clean water storage tank 51 to the floor-mopping machine table 2 through the water pipe 53, and then spray water uniformly onto the mop cloth through the spray nozzle 55.
If the water in the clean water storage tank 51 is exhausted during the spraying process, the water level sensor 56 in the clean water storage tank 51 is switched from the trigger state to the non-trigger state, at this time, the clean water pump 52 stops working, and an alarm process a is executed to remind a user that the water in the clean water storage tank is insufficient.
When the operating time of the clean water pump 52 reaches the humidifying time, the clean water pump 52 stops operating, and the nozzle 55 does not spray water any more.
Mop cleaning process j: the mopping robot controls the mop cloth to rotate or vibrate and rubs with the surface of the bulge on the worktable 2 of the mopping machine, so that dust and sewage flow on the mop cloth are left; or controlling the rotation device on the floor mopping machine workbench 2 to rotate, or controlling the vibration device on the floor mopping machine workbench 2 to vibrate, so that the dust and the sewage on the mop cloth flow down.
In combination with the floor mopping robot workstation, the method for cleaning mopping cloth by the floor mopping robot of the present invention, as shown in fig. 10, comprises the following steps:
step S101: and judging whether the sewage level in the sewage storage tank in the sewage recovery device meets the reuse water level or not.
Firstly, whether the sewage storage box 61 is installed in place or not is detected, if not, an alarm process a is triggered, and if the sewage storage box 61 is installed in place, a detection signal of a second water level detection device 68 in the sewage storage box 61 is acquired, and whether the sewage level in the sewage storage box 61 meets the reuse water level or not is judged. The reuse water level here is the lowest water level of the sewage that can be reused after the sewage is filtered and precipitated.
When the sewage level in the sewage storage tank satisfies the reuse water level, step S102: and starting the reuse water pump of the sewage recovery device.
The recycling water pump 66B is connected with the nozzle 55 of the floor mopping machine workbench 2 through a water pipe, and sewage which can be recycled after sedimentation is sprayed on the mop cloth through the nozzle 55 after the recycling water pump 66B is started.
Step S103: the spraying time is timed, and whether the water level in the sewage storage box meets the reuse water level or not is always detected during spraying.
During spraying, the detection data of the second water level detection device 68 is always acquired, and the spraying time is timed.
Step S104: when the spraying time reaches the set spraying time t1And when the reuse water level is always satisfied, the reuse water pump of the sewage recovery device is controlled to stop working.
If the sewage level in the sewage storage tank in the sewage recovery device does not meet the reuse water level, a clean water pump of the clean water cleaning device is directly started to set the spraying time.
Step S105: cleaning the mop sets the cleaning time.
Starting a mop cleaning process j, and setting cleaning time n by starting the rotation or vibration of the mop on the mop robot1Or starting a rotating device or a vibrating device on the floor mopping machine workbench 2 to work for setting the cleaning time n1The sewage and the dust are squeezed down the mop.
Step S106: when the spraying time does not reach the set spraying time t1And when the water level does not meet the reuse water level, controlling the reuse water pump of the sewage recovery device to stop working, and starting the water purification pump of the water purification and cleaning device.
The reuse water pump 66B of the sewage recovery apparatus 6 has an operating time t2When t is2<t1According to the second water detection deviceWhen the detection data of the device 68 judges that the water level in the sewage storage tank 61 has not satisfied the reuse water level, the reuse water pump 66B is controlled to stop operating, that is, when the water level in the sewage storage tank 61 has not satisfied the reuse water level, the operating time of the reuse water pump 66B has not reached the set washing time t1In time, the mop is continuously wetted by using the purified water.
After the clean water storage tank 51 is mounted in place as judged by the detection signal of the in-place sensor 57 of the clean water cleaning device 5, the clean water pump 52 connected to the clean water storage tank 51 is started to draw clean water from the clean water storage tank 51 and clean the mop continuously. If the purified water storage tank 51 is not installed in place, the alarm process a is started.
Step S107: and after a water purifying pump of the water purifying and cleaning device works until the set spraying time is reached, controlling the water purifying pump to stop working.
When the water purifying pump 52 of the water purifying and cleaning device 5 works to meet t1-t2After the time, i.e. the total time reaches the set spraying time, the mop is wetted and the water purifying pump 52 is controlled to stop working.
After step S107 is completed, the process goes to step S105: the cleaning time is set for cleaning the mop, and sewage and dust are squeezed down from the mop.
And (3) executing the mop cleaning process j to set the cleaning time, and starting the alarm process a to send out a water shortage alarm if the water level sensor 56 of the purified water storage box 51 stops triggering.
The mop cleaning mode provided by the invention utilizes the filtered and precipitated sewage for secondary utilization, so that water resources can be saved, and the frequency of adding and pouring water for users is reduced.
In a preferred embodiment of the present invention, the mopping robotic workstation is comprised in a mopping robotic workstation as shown in FIG. 1, the workstation further comprising: the garbage collection and sweeping machine comprises a sweeper workbench 1, a workbench lifting device 3, a garbage recovery device 4, a cooperative control center 7 and a power supply system 8. In the present embodiment, the control of the mop cleaning is performed by a coordinated control center 7.
The floor sweeping machine workbench 1 is used for realizing the charging and garbage recycling of the floor sweeping robot; the floor mopping machine workbench 2 is used for realizing the charging of the floor mopping robot, the cleaning of mop cloth and the recovery of sewage; the floor sweeping machine workbench 1 is arranged at the upper part of the workbench lifting device 3, and the floor mopping machine workbench 2 is arranged at the lower part of the workbench lifting device 3; the workbench lifting device 3 is used for controlling the lifting or descending of the workbench 1 of the sweeper.
In some embodiments of the invention, the sweeping machine workbench 1 has two first metal charging pole pieces at the front end, so as to realize a function of charging the sweeping robot.
A dust outlet is reserved in the position of the dust box of the sweeping robot, the dust outlet corresponds to a dust inlet on the worktable 1 of the sweeping machine, the outside of the dust outlet of the dust box of the sweeping robot is shielded by a silica gel pad, and one end of the silica gel pad is fixed with the dust box. When the sweeping robot leaves the workstation to clean, the fan inside the sweeping robot works to suck the silica gel pad outside the dust outlet, so that the sealing effect is achieved, and meanwhile, the garbage on the ground is sucked to the dust box.
When the sweeping robot returns to the workstation, the fan of the garbage recycling device 4 works, the silica gel pad outside the dust outlet of the dust box of the sweeping robot is sucked away, the garbage in the dust box is sucked out of the dust box, and the garbage is sucked into the garbage bag in the garbage storage area through the garbage recycling channel, so that the garbage recycling function is realized.
An infrared signal transmitting device is arranged on the floor mopping machine workbench 2, so that the recharging alignment function of the floor mopping robot and the sweeping robot is realized.
In some embodiments of the invention, the workbench lifting device 3 drives the screw to rotate through the servo motor to realize the lifting or descending of the workbench 1 of the sweeper; or the motor on the worktable 1 of the sweeper drives the gear to rotate, so that the worktable 1 of the sweeper ascends or descends on the sawtooth-shaped belt and the like.
The floor sweeping machine workbench 1 and the floor mopping machine workbench 2 are respectively provided with a limiting device, such as a proximity sensor, when the floor sweeping machine workbench 1 rises to the top end, the first limiting device on the floor sweeping machine workbench 1 is triggered, and the workbench lifting device 3 stops working, so that the rising limitation is realized. When the floor sweeping machine workbench 1 descends to the bottom end, the second limiting device on the floor sweeping machine workbench 2 is triggered, the workbench lifting device 3 stops working, and descending limiting is achieved.
When the mopping robot is positioned on the mopping machine workbench 2 or other articles are on the mopping machine workbench 2, the limiting device on the mopping machine workbench 2 can be triggered to stop the workbench lifting device from working, so that the mopping robot is prevented from being extruded or other articles are prevented from being extruded.
The electric telescopic rod is arranged in the workbench lifting device 3, when the floor sweeping machine workbench 1 is lifted to the top end, the electric telescopic rod extends out to support the floor sweeping machine workbench 1, and the situation that the floor sweeping machine workbench 1 falls down due to power failure or damage to the workbench lifting device 3 is avoided.
The garbage collection device 4, as shown in fig. 2, includes a garbage collection passage 41, a garbage storage area 42, a garbage bag 43 disposed in the garbage storage area 42, and a blower 44; the worktable 1 of the sweeping machine is provided with a dust inlet 11, the inlet end of the garbage recycling channel 41 is connected with a dust outlet of a dust box of the sweeping robot through the dust inlet 11, and the outlet of the other end is connected with a garbage storage area 42.
The waste bag 43 is mounted in the waste storage area 42 by a mounting plate 45. a dust opening 46 is formed in the mounting plate 45. the dust opening 46 is connected to the outlet end of the waste recovery channel 41 by a snap fit, screw or other docking means. The main body of the garbage bag 43 is made of a paper material or a nonwoven fabric material which is air-permeable and dust-proof, and is preferably made into a disposable garbage bag.
The fan 44 is arranged at an air outlet 47 of the garbage storage area 42; after the sweeping robot returns to the sweeping machine workbench 1 after sweeping, the fan 44 is started to suck the garbage out of the dust outlet of the sweeping robot from the dust box of the sweeping robot, the garbage is sucked into the garbage bag 43 through the dust inlet 11 of the sweeping machine workbench 1 and the garbage recycling channel 41, and the air is blown out from the air outlet 47 through the garbage bag 43.
The garbage bag 43 is provided with an in-place detection device 48, such as a microswitch, which is triggered when the fixing plate 45 is installed in place to indicate that the garbage bag 43 is installed in place, and when the sweeping robot finishes sweeping and returns to the floor sweeping machine workbench 1, whether the microswitch is triggered is firstly detected, and after the microswitch is triggered to ensure that the garbage bag 43 is installed in place, the fan 44 is started.
Aiming at the garbage recycling device 4, the invention provides a garbage recycling method of a sweeping robot, which comprises the following steps as shown in fig. 11:
step S111: recording the cleaning time t of the current cleaning task of the sweeping robotSweeping machine. And, step S112: calculating the time interval T between the last cleaning task and the current cleaning task of the sweeping robotSweeping machine。
Acquiring the last cleaning task time and the current cleaning task time of the sweeping robot, and calculating the time interval T between the last cleaning task time and the current cleaning task timeSweeping machine。
Step S113: time-based1=a1×TSweeping machine+a2×tSweeping machineAnd calculating the working time of the fan of the garbage recycling device.
In the embodiment of the present invention, the working time of the fan 44 of the garbage recycling device 4 is limited by the time interval between two cleaning tasks and the time of the current cleaning task, a1And a2The weight selection of the two times can be regarded as being completed through user setting, and the user can select the weight with the time interval heavier than the two cleaning tasks or the weight with the time interval heavier for each cleaning task according to the actual indoor situation, for example, when the user frequently cleans at home, the weight of the time interval of the current cleaning task can be set to be larger, and if the cleaning frequency of the user at home is lower, the weight of the time interval of the two cleaning tasks can be set to be larger.
Step S114: after the cleaning task is finished, starting the working time of the fan of the garbage recycling device1Time.
According to the embodiment of the invention, the time interval T between the current cleaning task and the last cleaning task of the sweeping robot is usedSweeping machineAnd the time t required for the current cleaning taskSweeping machineThe running time of a fan of the garbage recycling device is dynamically adjusted, so that the garbage recycling time can be reduced when the sweeping is frequent or the garbage is small, and the electric energy is saved; the garbage recycling time is prolonged when the sweeping time interval is long or the sweeping time is long, and the recycling capability is enhanced.
The cooperative control center 7 is responsible for charging and cooperative control of the floor sweeping robot and the floor mopping robot, garbage recycling, mop cleaning control and the like, and comprises a display module, a key input module, an operation processing module, a communication module and a control module.
The cooperative control center 7 can issue an instruction to the sweeping robot and the mopping robot through a first wireless communication module such as a 2.4G wireless module, a Bluetooth module or a zigbee wireless module, and receive information such as states, cleaning data and map data returned by the sweeping robot and the mopping robot through the first wireless communication module such as the 2.4G wireless module, the Bluetooth module or the zigbee wireless module; the information is transmitted to an operation processing module, and the operation processing module transmits part of state information to a display module after processing and converting the information and displays the state information on a display screen; after partial information is calculated and processed, the next step of instruction information is obtained, and then the next step of instruction information is transmitted to the floor sweeping robot or the floor mopping robot through the first wireless communication module such as the 2.4G wireless module, the Bluetooth module or the zigbee wireless module, so that the cooperative work is realized.
The user can transmit the control instruction to the operation processing module through the key input module, and then the control instruction is issued to the floor sweeping robot and the floor mopping robot through the first wireless communication module such as the 2.4G wireless module, the Bluetooth module or the zigbee wireless module.
The cooperative control center 7 can access the workstation to the internet through a Wi-Fi communication module, a 4G communication module or a 5G communication module and other second wireless communication modules, and a user can issue an instruction to the workstation through an intelligent terminal APP, so that the floor sweeping robot and the floor mopping robot are controlled; meanwhile, the workstation can transmit information such as states of the workstation, the floor sweeping robot, the floor mopping robot and map data to the background server and the intelligent terminal APP through the Wi-Fi communication module, the 4G communication module or the 5G communication module and other second wireless communication modules.
The key input module may be replaced with a touch screen of the display module.
The cooperative work station can increase WLAN interface, and the user can directly connect through network cable, so that the work station can be accessed into local area network.
The power supply system 8 is responsible for supplying power to each module of the whole cooperative workstation through internal circuits and the above-mentioned various external contact points, electrodes and the like.
Before a detailed description is made of a cooperative work control method of a sweeping and mopping robot cooperative workstation, the following description is made of a relevant work process in the cooperative workstation in the embodiment of the present invention:
b, descending process of a worktable of the sweeper: the electric telescopic rod of the workbench lifting device 3 is retracted, the motor starts to work to drive the floor sweeping machine workbench 1 to descend, when the second limiting device (the proximity sensor 2) on the floor sweeping machine workbench 2 is approached, the second limiting device on the floor sweeping machine workbench 2 is triggered, the motor of the workbench lifting device 3 stops, the floor sweeping machine workbench 1 stops descending, and the floor sweeping robot exits from the workstation.
C, ascending process of a floor sweeping machine workbench: the motor of the workbench lifting device 3 starts to work, the workbench 1 of the floor sweeping machine rises, when the first limiting device (the proximity sensor 1) of the workbench 1 of the floor sweeping machine is triggered, the motor of the workbench lifting device 3 stops, the workbench 1 of the floor sweeping machine stops rising, and meanwhile, the electric telescopic rod of the workbench lifting device 3 extends out to support the workbench 1 of the floor sweeping machine.
The mopping robot avoiding process I: the mopping robot exits the mopping machine workbench 2 and runs to a position where the floor sweeping robot is not obstructed to exit.
The outbound process e of the sweeper: judging whether a mopping machine or other objects exist on the floor mopping machine workbench 2 by judging whether a second limiting device (a proximity sensor 2) on the floor mopping machine workbench 2 is triggered; if the second limiting device on the floor mopping machine workbench 2 is triggered, whether the floor mopping robot is charged or not is judged, if the floor mopping robot is not charged, other objects on the floor mopping machine workbench 2 are considered to prevent the floor sweeping machine workbench 1 from descending, and an alarm process a is triggered.
And if the mopping robot is in the charging process, executing a mopping robot avoiding process d, and then starting a floor sweeping machine workbench descending process b and a floor sweeping machine workbench ascending process c.
The recharging process f of the sweeping robot is as follows: judging whether a mopping machine or other objects exist on the floor mopping machine workbench 2 by judging whether a second limiting device (a proximity sensor 2) on the floor mopping machine workbench 2 is triggered; if the second limiting device on the floor mopping machine workbench 2 is triggered, judging whether the floor mopping robot is charged, if the floor mopping robot is not charged, considering that other objects on the floor mopping machine workbench 2 prevent the floor sweeping machine workbench from descending, and triggering an alarm process a; if the mopping robot is in charging, the execution of the mopping robot is controlled to avoid the process a, then the descending process b of the worktable of the sweeping machine is executed, then the sweeping robot is aligned with the infrared signal transmitting device on the worktable 2 of the mopping machine through the infrared receiving sensor on the machine body, enters the workstation to start charging, and after the mopping robot is charged, the ascending process c of the worktable of the sweeping machine is executed.
And a floor mopping robot recharging process g: firstly, judging whether other objects exist on the floor mopping machine workbench 2 by judging whether a second limiting device (a proximity sensor 2) on the floor mopping machine workbench 2 is triggered; if the second limiting device on the floor mopping machine workbench 2 is triggered, it is considered that other objects on the floor mopping machine workbench 2 prevent the floor mopping robot from recharging, and an alarm process a is triggered; if the second limiting device on the floor mopping machine workbench 2 is not triggered, the floor mopping robot enters the workstation to start charging through the alignment of the infrared receiving sensor on the machine body and the infrared signal transmitting device on the floor mopping machine workbench 2.
And (4) avoiding the process of the mopping machine for two hours: and controlling the floor mopping robot to stand by on the spot.
And (5) sewage recovery process k: it is detected whether the sewage storage tank 61 is mounted in place, and if not, an alarm process a is triggered, and if so, the sewage recovery pump 66 of the sewage recovery apparatus 6 starts to operate. If the water level detection means 64 of the sewage storage tank 61 is triggered, indicating that the water level of the sewage storage tank 61 has reached the maximum, the sewage recovery pump 66 of the sewage recovery apparatus 6 stops operating, and the alarm process a is triggered. If the water level detection means 64 of the sewage storage tank 61 has not been triggered, it is judged whether the operation time of the sewage recovery pump 66 of the sewage recovery device 6 reaches the sewage recovery time, and if so, the operation of the sewage recovery pump 66 is stopped to complete the sewage recovery operation.
And (3) garbage recycling process l: firstly, the methodDetecting whether the garbage bag 43 is installed in place by an in-place detection device 48 of the garbage recycling device 4, and starting an alarm process a if the garbage bag 43 is not installed in place; if the garbage recycling device is installed in place, the fan 44 of the garbage recycling device 4 is started to control the garbage recycling device to meet the working time of the fan1And the garbage can be recycled.
As shown in fig. 6, the method for building a map provided by the above-mentioned coordinated workstation of the sweeping and mopping robot of the present invention is implemented by the coordinated control center 7 of the coordinated workstation, and includes the following steps:
step S61: and controlling the sweeping robot to go out of the station.
After the floor sweeping robot cooperative workstation is started for the first time or a map building instruction is received, the cooperative control center 7 firstly controls the floor sweeping robot to execute a floor sweeping robot outbound process e.
Step S62: and starting a scanning device of the sweeping robot to build a picture.
After the sweeping robot finishes leaving the station, the sweeping robot firstly runs to a random position, and then starts a scanning device to scan, for example, a laser radar is provided with a transmitting end and a receiving end, and the distance between an obstacle and the radar can be determined by calculating the wind distance of light according to the time difference between the transmitting end and the receiving end; and when the image created by the scanning of the radar is not a completely closed map, the sweeping robot is controlled to operate to other positions where the obstacle is not scanned and continue to create the image until the obstacle is completely closed, and then the scanning is finished.
The scanning and map building process here only needs to adopt the existing map scanning mode, and the embodiment of the invention is not particularly limited.
Step S63: and after the map building is completed, the sweeping robot sends the map building data to the cooperative workstation.
When a complete map is established through scanning of the laser radar, the sweeping robot uploads information such as map data to the cooperative control center 7 of the cooperative workstation through the 2.4G wireless communication module, the Bluetooth module or the zigbee wireless module.
Step S64: and controlling the sweeping robot to return to the station.
And executing a recharging process f of the sweeping robot.
And after the floor sweeping robot finishes the recharging process f, executing a recharging process g of the floor mopping robot.
Step S65: and planning a cleaning route and a mopping route based on the mapping data.
And after receiving the map data sent back by the sweeping robot, the cooperative control center 7 plans a sweeping route of the sweeping robot and a floor mopping route of the floor mopping robot. The embodiment of the present invention is not particularly limited.
After the cooperative control center 7 plans the cleaning route and the mopping route, the cooperative work control method of the sweeping robot provided by the invention is executed, so that the cooperative work of the sweeping robot and the mopping robot is realized.
Specifically, as shown in fig. 7A, the method includes the following steps:
step S70: and after receiving the task instruction, controlling the sweeping robot to go out of the station.
After receiving a task instruction sent by a user through an APP, a remote controller or other control terminals, the workstation firstly executes a subprogram of the floor sweeping robot leaving station.
Step S71: and controlling the sweeping robot to execute a sweeping task according to the planned sweeping route.
After the sweeping robot leaves the station, the cooperative control center 7 controls the sweeping robot to start to execute a sweeping task according to the planned sweeping route.
The task instruction is a combined instruction comprising a cleaning task and a mopping task; based on the sweeping and mopping robot cooperative workstation provided by the invention, a user can also independently execute a sweeping task or a mopping task according to actual requirements, and the following contents are explained.
Step S72: and judging whether the area of the cleaned area of the sweeping robot reaches a set threshold value or not.
In the process of executing cleaning, the sweeping robot continuously feeds back cleaning data to the cooperative work center 7, the cooperative work center 7 judges the area of a cleaning completion area according to the returned cleaning data, if the area does not reach a set threshold value, the sweeping robot continues to execute cleaning according to a planned cleaning route, and the mopping robot executes a mopping robot avoiding process for two hours.
If the cleaned area does not meet the set threshold, cleaning is continuously carried out according to the planned cleaning route; if the cleaned area reaches the set threshold, step S73 is executed: controlling the water purifying and cleaning device to start, and wetting the mop of the mopping robot.
In this step, a mop wetting process i is performed.
In some embodiments of the invention, the process of wetting the mopping robot mop proposes a method of controlling the wetness of the mopping robot mop, as shown in fig. 8, comprising the steps of:
when the area of a cleaning area of the floor sweeping robot reaches a set threshold value, the cooperative work center 7 starts the water purifying and cleaning device 5 to spray water and wet the mop of the floor sweeping robot, counts the working time of the water purifying pump 52, and controls the water purifying pump to stop working after the wetting time is reached, so that the mop wetting process i is finished.
Step S81: and determining the humidity level set by the user.
In the embodiment of the invention, a user can set the mop humidity of the mopping robot through the intelligent terminal APP, the remote controller or other control terminals according to the floor pollution degree, namely, set a humidity gear, and after the water purification and cleaning device 5 is started to perform a mop wetting process on mopping, the mopping is considered to be completely wetted, and then the cooperative work center 7 reads the humidity gear set by the user, and performs humidity control on the mopping according to the humidity gear: and rotating or vibrating the mop for dehumidification according to the humidity corresponding to the humidity gear, so that the humidity of the mop meets the requirement of a user.
Step S82: rotating the mop cloth or vibrating the mop cloth according to the set time of the humidity gear.
If the humidity gear set by the user is a middle gear, the mop on the mopping robot starts to rotate or vibrate for a time corresponding to the humidity of the middle gear; or, the rotating device or the vibrating device on the floor-mopping machine table 2 starts to rotate or vibrate for a time corresponding to the middle-grade humidity.
Similarly, a user can set any gear, and each humidity gear is correspondingly set with corresponding time; the lower the gear, the longer the rotation or vibration time, the lower the humidity of the mop cloth, the higher the gear, the shorter the rotation or vibration time, the higher the humidity of the mop cloth.
Step S83: when the set time of the humidity gear is reached, the mop is controlled to stop rotating or vibrate.
The mop achieves the humidity required by the humidity gear.
After the mop is wetted, the cooperative control center 7 continues the cooperative control step S74: and controlling the floor mopping robot to go out of the station.
After the mop of the mopping robot is wetted, the mopping robot is controlled to go out of the station.
Step S75: and controlling the mopping robot to execute the mopping task based on the planned mopping route.
After the floor-mopping robot leaves the station, the cooperative control center 7 controls the floor-mopping robot to execute a floor-mopping task according to the planned floor-mopping route, and receives floor-mopping data returned by the floor-mopping robot in the period.
In the embodiment of the invention, the floor mopping routes of the floor mopping robot are uniformly controlled by the cooperative control center 7, and the map building is completed by the sweeping robot, so that a floor mopping robot body does not need to be provided with a scanning module and the like related to the map building, the design cost of the floor mopping robot is reduced, the height of the floor mopping robot can be reduced, and the floor mopping robot can penetrate through more household bottoms to thoroughly clean indoor floors.
In some embodiments of the invention, during the period that the mopping robot goes out of the station to perform the mopping task, the cooperative control center further performs the following steps based on the cleaning data and the mopping data returned by the mopping robot, as shown in fig. 7B, so as to further avoid work conflict between the two, and improve the cleaning effect.
Step S76: and judging whether the floor sweeping robot and the floor mopping robot have task conflicts or not.
In the embodiment of the invention, the task conflict is judged according to the following two ways:
1. judging whether the floor sweeping robot and the floor mopping robot collide or not: the cooperative control center 7 combines the floor sweeping data and the floor mopping data to judge whether a route to be swept by the floor sweeping robot and a route to be cleaned by the floor mopping robot are crossed or not after the planned routes are set, namely whether the planned routes are collided or not after the set time, and if the planned routes are collided, the routes are collided.
2. Judging whether the area to be cleaned by the mopping robot is swept by the sweeping robot: the cooperative control center 7 combines the sweeping data and the mopping data to judge whether the area to be cleaned by the mopping robot is already swept by the sweeping robot or not, and if not, a conflict exists.
Step S77: and when the conflict exists, controlling the floor mopping robot to stop until the conflict is relieved and then starting.
If the collision possibility exists between the floor mopping robot and the floor cleaning robot, the floor mopping robot is controlled to execute a floor mopping robot avoiding process for two hours, and after the floor sweeping robot cleans the intersection route, the floor mopping robot is started to continue to clean according to the planned route
And if the area to be cleaned by the floor mopping robot is not cleaned, controlling the floor mopping robot to execute a floor mopping robot avoiding process for two hours, and starting the floor mopping robot to clean according to the planned path after the floor mopping robot cleans the area.
And if the conflict does not exist, the sweeping robot executes the sweeping task according to the sweeping route, and the mopping robot executes the mopping task according to the mopping route until the sweeping robot and the mopping robot complete the tasks.
In the cleaning process of the mopping robot, the invention provides a mopping cloth cleaning method of the mopping robot, which realizes the control of the cleaning period of the mopping robot by detecting the cleaning time of the mopping robot through a cooperative control center 7, and concretely, as shown in fig. 9, the method comprises the following steps:
step S91: and calculating the time interval between the last floor mopping task and the current floor mopping task.
During cleaning of the mopping robot, the cooperative workstation acquires the time record of the last mopping task, and calculates the time interval period T1 from the current working time.
Step S92: calculating the time for cleaning mop by n5- (T1 coefficient 3)2。
By time2=n5-a3×T1Calculating the cleaning time of the mop, and reaching the time at the current cleaning time2When the mopping reaches the time, step S932And controlling the floor mopping robot to return to the station during time.
And executing a floor mopping robot recharging process g.
Wherein n is5And a3For the experience setting value, if the current floor mopping task is away from the time interval T of the last floor mopping task1When the time is longer, the dust on the floor is more, which indicates that the user does not clean the floor for a long time, and the time is longer2The mop is short, and the mop needs to be cleaned in time; if the time interval T1 between the current mopping task and the last mopping task is shorter, which indicates that the user cleans the floor more timely, the dust on the floor is less, and the time is shorter2I.e. longer, the mop cleaning can be late.
T1With a limited range when the user first uses the mopping task or the interval period T1 exceeds the set maximum value TmaxTo set the maximum value TmaxAnd (6) performing calculation.
When the current outbound mopping time of the mopping robot reaches the mop cleaning time interval2And starting a recharging process g of the mopping robot.
Step S94: and after the mopping robot returns to the station, cleaning the mop.
After the mopping robot finishes mop cleaning, the cooperative workstation starts a sewage recovery process k.
And after the sewage recovery work is finished, if the floor mopping task is not finished, controlling the floor mopping robot to continuously leave the station and continuously perform cleaning according to the planned path until the current task is finished and then returning to the cooperative workstation.
And when the cooperative control center 7 finishes the floor mopping task, starting a floor mopping robot recharging process g. And when the mopping robot recharges successfully, executing a mop wetting process, a mop cleaning process and a sewage recycling process.
Meanwhile, after the sweeping robot finishes the sweeping task, the cooperative control center 7 starts the sweeping robot to rechargeAnd f, after the sweeping robot is recharged to the right position, determining the working time of the fan based on the garbage recycling method of the sweeping robot1And starting a garbage recycling process l.
It should be noted that the above description is not intended to limit the present invention, and the present invention is not limited to the above examples, and those skilled in the art should also make changes, modifications, additions or substitutions within the spirit and scope of the present invention.