CN115429180A - Cleaning bucket and cleaning tool - Google Patents

Abstract

The cleaning barrel and the cleaning tool comprise a cleaning barrel and a water inlet control mechanism and/or a sewage pump and/or a visual window, wherein the water inlet control mechanism is arranged on the cleaning barrel, and when the mop enters the cleaning cavity from the cleaning port, the water inlet control mechanism controls the cleaning barrel to be automatically switched from a closed state to a flow-through state, so that clean water in the cleaning cavity can flow into the cleaning cavity. The sewage pump can with the sewage pump of the clean intracavity of the dirty formula of pump is gone into the dirty sewage intracavity of washing the bucket of pump is avoided wash the intracavity and remain sewage and pollute the clear water of newly adding, be favorable to the guarantee the cleanliness factor of the water of clean intracavity improves the clean effect that the dirty formula of pump is used for wasing a mop can be observed through visual window the water yield in the clean bucket.

Description

Cleaning bucket and cleaning tool

Technical Field

The invention relates to the field of cleaning tools, in particular to an automatic cleaning barrel and a cleaning tool.

Background

The flat mop not only is convenient for cleaning the ground, but also can be used for cleaning window glass and the like, has large cleaning area and high cleaning efficiency, and is favored by many consumers. In order to meet the hand-free requirement of users, cleaning buckets specially used for cleaning flat mops appear on the market.

Specifically, the cleaning tub includes a tub main body having a cleaning region and a dewatering region, wherein the cleaning region and the dewatering region are independent of each other, and a squeezing device including a sludge scraping squeezing part having a sludge scraping port and a dewatering squeezing part integrally extending outward from the sludge scraping squeezing part, wherein the dewatering squeezing part having a dewatering port, wherein the squeezing device is installed above the tub main body in such a manner that the sludge scraping port and the dewatering port are communicated with the cleaning region and the dewatering region, respectively. Clean bucket clean water splendid attire in the clean district, with the mop certainly scrape dirty mouthful and insert the washing district reciprocates repeatedly the mop, scrape dirty extrusion portion can will adhere to in the dirt of mop is scraped in the clean district. And after the cleaned mop is taken out from the dirt scraping port, the dewatering port of the dewatering squeezing part is inserted into the dewatering area, the dewatering squeezing part squeezes the mop, and squeezes the sewage on the mop to the cleaning area, so that the cleaning and dewatering of the mop are completed.

However, the clean water in the clean water area of the existing cleaning bucket becomes turbid after the mop is cleaned once, and can only be cleaned by the sewage in the cleaning bucket when the mop is cleaned next time, and the water in the cleaning bucket becomes more dirty along with the increase of the cleaning times, which is not beneficial to ensuring the cleanliness of the mop. Or, the user needs to frequently replace the water in the cleaning barrel to ensure that the mop can be cleaned, so that the operation is complex and labor-consuming, and water waste is caused.

On the other hand, the inability to observe the wastewater level is also a problem. Before the mop is cleaned, a user can only observe the water level in the decontamination chamber through the dirt scraping opening of the cleaning device, but the water level in the decontamination chamber cannot be accurately observed due to the narrow dirt scraping opening, and water is usually filled into the decontamination chamber by feeling and experience. However, if the water level in the decontamination chamber is too high, after the flat mop is inserted into the decontamination chamber, the water in the decontamination chamber overflows to the use area, or the flat mop is easy to drain the water in the decontamination chamber to the use area in the process of moving up and down relative to the cleaning bucket. The user has to observe the water level inside the decontamination chamber from the upper opening of the receiving means by detaching the cleaning means and the receiving means, but even then the water level entering the decontamination chamber cannot be accurately grasped.

Disclosure of Invention

Accordingly, the present invention has been made to solve the above-mentioned problems occurring in the prior art, and it is an object of the present invention to provide an automatic cleaning bucket and a cleaning tool, wherein the automatic cleaning bucket is automatically switched from a closed state to an open state when receiving a mop, and a clean water chamber and a cleaning chamber of the automatic cleaning bucket are connected, and clean water in the clean water chamber automatically flows into the cleaning chamber without a user actively controlling the flow of clean water.

Still another object of the present invention is to provide a dirty-pumping type cleaning barrel and a cleaning tool, wherein the dirty-pumping type cleaning barrel provides a sewage pump, and the sewage pump can pump the sewage in a cleaning cavity of the dirty-pumping type cleaning barrel into a sewage cavity of the dirty-pumping type cleaning barrel, so as to prevent the residual sewage in the cleaning cavity from polluting newly added clean water, thereby being beneficial to ensuring the cleanliness of the water in the cleaning cavity and improving the cleaning effect of the dirty-pumping type cleaning barrel for cleaning a mop.

It is a further object of the present invention to provide a visual cleaning barrel and a cleaning tool, wherein the visual cleaning barrel includes a cleaning window through which the water level in a cleaning chamber of the visual cleaning barrel can be clearly observed, so as to facilitate accurate control of the water amount entering the cleaning chamber and avoid excessive or insufficient water amount in the cleaning chamber.

In accordance with one aspect of the present invention, there is provided an automatic cleaning bucket for cleaning a mop, the automatic cleaning bucket comprising:

a cleaning bucket, wherein the cleaning bucket comprises a bucket body and a cleaning device, wherein the bucket body is provided with a clean water cavity, a cleaning cavity, a sewage cavity and a water inlet channel which can be communicated with the clean water cavity and the cleaning cavity, the water inlet channel is formed at the lower part of the bucket body, wherein the cleaning device is provided with a water filling opening, a cleaning opening and a sewage opening, and the cleaning device is kept above the cleaning bucket in a way that the water filling opening, the cleaning opening and the sewage opening respectively correspond to the clean water cavity, the cleaning cavity and the sewage cavity; and

a water inlet control mechanism, wherein the water inlet control mechanism is arranged on the cleaning barrel, when the mop enters the cleaning cavity from the cleaning port, the water inlet control mechanism controls the cleaning barrel to be automatically switched from a closed state to a circulating state, the water inlet channel of the cleaning barrel in the circulating state is communicated with the clean water cavity and the cleaning cavity, and the clean water cavity and the cleaning cavity of the cleaning barrel in the closed state are blocked.

According to an embodiment of the present invention, the water inlet control mechanism comprises an electrically controlled water inlet valve, a control element and a detection element, wherein the electrically controlled water inlet valve is communicatively connected to the control element, the control element is communicatively connected to the electrically controlled water inlet valve, the electrically controlled water inlet valve is arranged on the water inlet channel, the detection element is arranged on the cleaning device, and when the detection element detects that the mop enters the cleaning chamber, the control element controls the electrically controlled water inlet valve to open, and the water inlet channel is communicated with the clean water chamber and the cleaning chamber.

According to one embodiment of the invention, the electrically controlled water inlet valve and the control element are integrated into a solenoid valve.

According to an embodiment of the invention, the control element is implemented as an electrically operated telescopic rod, the electrically controlled water inlet valve being arranged at an end of the electrically operated telescopic rod, the control element moving the electrically controlled water inlet valve in an electrically telescopic manner such that the cleaning bucket is switchable between the closed state and the flow-through state.

According to one embodiment of the invention, the water inlet control mechanism is movably held in the cleaning cavity, and the mop can drive the water inlet control mechanism to move relative to the cleaning barrel and mechanically open or close the water inlet channel.

According to an embodiment of the present invention, the cleaning bucket comprises a containing body, a water inlet partition board and a water outlet partition board, wherein the containing body has a containing space, the water inlet partition board and the sewage partition board are arranged at intervals in the containing space of the containing body, the clean water cavity is formed between the containing body and the water inlet partition board, the clean water cavity is formed between the water inlet partition board and the sewage partition board, and the sewage is formed between the containing body and the sewage partition board, the water inlet channel is formed in the water inlet partition board, and the water inlet control mechanism is movably arranged in the water inlet partition board.

According to an embodiment of the present invention, the water inlet control mechanism includes a trigger, an elastic restoring member, a linking member, a retaining member, an extending member, and a water blocking plug, wherein the trigger and the extending member are respectively disposed at an upper end portion and a lower end portion of the linking member, the linking member is obliquely retained in the cleaning chamber, the trigger and the extending member are located at both sides of the linking member, the water blocking plug is fixed at an end portion of the extending member, the retaining member is fixed at the container body, a middle portion of the linking member is rotatably mounted at the retaining member, the elastic restoring member is retained between the trigger and the water inlet partition plate, and the water blocking plug is movably mounted at the water inlet passage.

According to one embodiment of the invention, the width of the cleaning chamber and the cleaning opening is larger than the width of the mop, and the water inlet control mechanism is held in the cleaning chamber in such a way that the trigger is close to the end of the cleaning opening.

According to an embodiment of the present invention, the cleaning device includes a water supply portion, a cleaning portion, and a water discharge portion, wherein the water supply port, the cleaning port, and the sewage port are formed in the water supply portion, the cleaning portion, and the water discharge portion, respectively, the cleaning portion includes a holding portion and a dirt scraping portion opposite to the holding portion, the dirt scraping portion connects the holding portion and the water discharge portion, the dirt scraping portion and the water discharge portion are located between the cleaning port and the sewage port, and an upper surface of the water discharge portion is an inclined surface inclined downward.

According to one embodiment of the invention, the cleaning opening of the cleaning bucket is in a shape of a letter "convex".

According to an embodiment of the present invention, the cleaning bucket further comprises a dirt filtering device, wherein the dirt filtering member has a dirt inlet, a dirt containing space and a filtering opening, wherein the dirt containing space is communicated with the dirt inlet and the filtering opening, the dirt filtering device is held below the dirt scraping part of the cleaning device, and the dirt inlet and the filtering opening of the dirt filtering device are respectively communicated with the cleaning cavity and the sewage cavity.

According to an embodiment of the present invention, the dirt filtering device includes a dirt-scraping plate, a dirt accommodating case, and a filter member, wherein the dirt-scraping plate and the filter member are respectively provided to the dirt accommodating case, the filter member is held at the filter port, the dirt inlet port and the content space are formed between the dirt-scraping plate and the dirt accommodating case, and the dirt-scraping plate is held at an interval below the dirt-scraping portion of the cleaning portion in a manner protruding forward.

According to one embodiment of the invention, the dirt rubbing plate is obliquely arranged on the dirt containing box.

In accordance with one aspect of the present invention, there is provided a pump-dirt cleaning bucket adapted for cleaning a mop, the pump-dirt cleaning bucket comprising:

a cleaning bucket, wherein the cleaning bucket comprises a holding device and a cleaning device, wherein the holding device is provided with a clean water cavity, a cleaning cavity and a sewage cavity, wherein the cleaning device is provided with a water filling opening, a cleaning opening and a sewage opening, and the cleaning device is held above the cleaning bucket in a manner that the water filling opening, the cleaning opening and the sewage opening respectively correspond to the clean water cavity, the cleaning cavity and the sewage cavity; and

and the sewage pump is provided with a sewage suction port and a sewage discharge port, and the sewage pump is arranged in the cleaning barrel in a mode that the sewage suction port and the sewage discharge port are respectively communicated with the cleaning cavity and the sewage cavity.

According to an embodiment of the present invention, the container includes a container body, a water inlet partition and a sewage partition, wherein the container body has a container space, wherein the water inlet partition and the sewage partition are disposed at intervals in the container space of the container body, and the clean water chamber is formed between the container body and the water inlet partition, the clean water chamber is formed between the water inlet partition and the sewage partition, and the sewage chamber is formed between the container body and the sewage partition, the sewage partition has a fitting opening formed at a bottom of the sewage partition, and the sewage pump is sealingly mounted to the fitting opening in such a manner that the sewage suction opening and the sewage discharge opening are communicated with the clean chamber and the sewage discharge opening, respectively.

According to an embodiment of the present invention, the sewage pump includes a pump main body, a sewage suction pipe and a sewage discharge pipe, wherein the sewage suction pipe and the sewage discharge pipe are respectively communicated with both ends of the pump main body, the sewage suction port and the sewage discharge port are respectively formed in the sewage suction pipe and the sewage discharge pipe, the pump main body is held at an upper portion of the cleaning tub in such a manner that the sewage suction pipe and the sewage discharge pipe are respectively located in the cleaning chamber and the sewage chamber, and the sewage suction pipe extends from the pump main body to a bottom of the cleaning chamber.

According to an embodiment of the present invention, the sewage pump further includes a quick release mechanism, wherein the quick release mechanism includes a first quick release member and a second quick release member, wherein the first quick release member and the second quick release member are respectively provided to the cleaning bucket and the pump body, and the first quick release member is detachably mounted to the second quick release member.

According to one embodiment of the invention, the first quick release member and the second quick release member are connected in a manner selected from the group consisting of: a threaded connection, a snap connection, a magnetic connection, and a clearance fit connection.

According to an embodiment of the present invention, the pump-dirt type cleaning bucket further comprises at least one transparent cleaning visual window, wherein the cleaning visual window is disposed on the containing device, and the cleaning visual window corresponds to the cleaning cavity, and water in the cleaning cavity can be seen through the cleaning visual window.

According to an embodiment of the present invention, the pump-dirt cleaning bucket further comprises a detection device, wherein the detection device is mounted to the cleaning bucket, the detection device is communicatively connected to the sewage pump, and the detection device controls the sewage pump to maintain an on state after the detection device detects that the mop in the cleaning cavity leaves the cleaning cavity.

According to an embodiment of the present invention, the pump-dirt type cleaning bucket further comprises a detection device and a water level detection device, wherein the detection device is installed on the cleaning bucket, the water level detection device is retained in the cleaning cavity, the water level detection device is communicably connected to the detection device and the sewage pump, and the sewage pump is switched to an open state when the detection device detects that the flat mop leaves the cleaning cavity and the water level detection device detects that residual sewage is in the cleaning cavity.

According to an embodiment of the present invention, the pump-dirt type cleaning barrel further comprises a water inlet control mechanism, wherein the container has a water inlet channel, wherein the water inlet channel is formed at a lower portion of the container, wherein the water inlet control mechanism is movably disposed on the cleaning barrel, the water inlet control mechanism controls the cleaning barrel to switch between a flow-through state and a closed state, the water inlet channel of the cleaning barrel in the flow-through state communicates with the clean water cavity and the clean cavity, and the clean water cavity and the clean cavity of the cleaning barrel in the closed state are blocked.

According to an embodiment of the present invention, the water inlet control mechanism includes an operation member and a limiting member, the operation member includes an operation element, an extension rod and a movable valve, the limiting member has a longitudinal assembly cavity and a transverse flow passage communicating with the longitudinal assembly cavity, the operation element and the movable valve are respectively disposed at an upper end and a lower end of the extension rod, the movable valve has a flow passage, the cleaning device has a holding hole, the limiting member is disposed at the containing device in a manner that the transverse flow passage can be communicated with the water inlet passage, the operation element is held above the cleaning device in a manner that the extension rod is rotatably mounted at the holding hole, and the movable valve is rotatably held at the longitudinal assembly cavity of the limiting member.

According to an embodiment of the present invention, there is provided a visual cleaning bucket, including:

a cleaning bucket, wherein the cleaning bucket comprises a bucket body and a cleaning device, wherein the bucket body is provided with a clean water cavity, a cleaning cavity and a sewage cavity, wherein the cleaning device is provided with a water filling opening, a cleaning opening and a sewage opening, and wherein the cleaning device is held above the cleaning bucket in a manner that the water filling opening, the cleaning opening and the sewage opening respectively correspond to the clean water cavity, the cleaning cavity and the sewage cavity; and

a visual window, wherein the visual window comprises at least one transparent cleaning visual window, wherein the cleaning visual window is arranged on the barrel body, the cleaning visual window corresponds to the cleaning cavity, and water in the cleaning cavity can be seen through the cleaning visual window.

According to an embodiment of the present invention, the visible window includes at least one transparent clear water visible window, wherein the clear water visible window is disposed on the barrel body, and the clear water visible window corresponds to the clear water chamber, through which water in the clear water chamber can be seen.

According to an embodiment of the present invention, the visible window includes at least one transparent sewage visible window, wherein the sewage visible window is disposed on the tub body, and the sewage visible window corresponds to the sewage chamber, through which water in the clean water chamber can be seen.

According to an embodiment of the present invention, the cleaning view window integrally extends from the clear water view window to the sewage view window.

According to an embodiment of the present invention, the cleaning visible window, the fresh water visible window, and the sewage visible window are disposed at the tub body to be spaced apart from each other.

According to one embodiment of the present invention, the visual cleaning bucket further comprises at least one set of scales, wherein at least one set of scales is provided on the bucket body and corresponds to the water level in the cleaning cavity.

According to an embodiment of the present invention, the visual cleaning barrel further comprises at least one set of scales, wherein at least one set of scales is disposed on the barrel body and corresponds to the water level in the clean water chamber.

According to an embodiment of the present invention, the visual cleaning bucket further comprises at least one set of scales, wherein at least one set of scales is provided on the bucket body, and the scales correspond to the water level in the sewage chamber.

According to an embodiment of the present invention, the visible cleaning bucket further comprises a water inlet control mechanism, wherein the bucket body has a water inlet channel, wherein the water inlet channel is formed at a lower portion of the bucket body, wherein the water inlet control mechanism is movably disposed on the cleaning bucket, the water inlet control mechanism controls the cleaning bucket to switch between a flow-through state and a closed state, the water inlet channel of the cleaning bucket in the flow-through state communicates the clean water cavity and the cleaning cavity, and the clean water cavity and the cleaning cavity of the cleaning bucket in the closed state are blocked.

According to an embodiment of the present invention, the water inlet control mechanism includes a manual operation member and a limiting member, the manual operation member includes an operation element, an extension rod and a movable valve, the limiting member has a longitudinal assembly cavity and a transverse flow passage communicating with the longitudinal assembly cavity, the operation element and the movable valve are respectively disposed at an upper end and a lower end of the extension rod, the movable valve has a flow passage, the cleaning device has a retaining hole, the limiting member is disposed at the tub body in such a manner that the transverse flow passage can be communicated with the water inlet passage, the operation element is retained above the cleaning device in such a manner that the extension rod is rotatably mounted at the retaining hole, and the movable valve is rotatably retained at the longitudinal assembly cavity of the limiting member.

According to an embodiment of the present invention, the water inlet control mechanism includes a manual operation member, a stopper, and an elastic member, the manual operation member includes an operation element, an extension rod, and a movable valve, the stopper has a longitudinal assembly cavity and a transverse flow passage communicating with the longitudinal assembly cavity, the operation element and the movable valve are respectively disposed at an upper end and a lower end of the extension rod, the movable valve has a flow passage, the cleaning device has a holding hole, the stopper is disposed at the tub body in such a manner that the transverse flow passage can be communicated with the water inlet passage, the operation element is held above the cleaning device in such a manner that the extension rod is vertically movably mounted at the holding hole, and the movable valve is held at the longitudinal assembly cavity of the stopper in such a manner that the movable valve is vertically movable, and the elastic member is disposed below the movable valve.

According to an embodiment of the present invention, the water inlet control mechanism includes a manual wireless switch and a manual solenoid valve, wherein the manual solenoid valve has a fluid passage, wherein the manual wireless switch is communicably connected to the manual solenoid valve, the manual solenoid valve is disposed at the water inlet passage in such a manner that the fluid passage can communicate with the clean water chamber and the cleaning chamber, the manual wireless switch allows the manual solenoid valve to be manually controlled to switch between an open state and a closed state, and enables the cleaning bucket to switch between the circulating state and the closed state.

According to an embodiment of the present invention, the water inlet control mechanism includes a foot-operated wireless switch and a foot-operated solenoid valve, wherein the foot-operated solenoid valve has a water flow passage, wherein the foot-operated wireless switch is communicably connected to the foot-operated solenoid valve, the foot-operated solenoid valve is disposed at the water inlet passage in such a manner that the water flow passage can communicate with the fresh water chamber and the cleaning chamber, and the foot-operated wireless switch allows the foot-operated solenoid valve to be foot-operated to switch between an open state and a closed state, and enables the cleaning bucket to switch between the flow-through state and the closed state.

According to one embodiment of the invention, when the mop enters the cleaning cavity from the cleaning opening, the mop drives the water inlet control mechanism and controls the cleaning bucket to automatically switch from the closed state to the circulation state.

According to an embodiment of the present invention, the water inlet control mechanism comprises an electrically controlled water inlet valve, a control element and a detection element, wherein the electrically controlled water inlet valve is communicatively connected to the control element, the control element is communicatively connected to the electrically controlled water inlet valve, the electrically controlled water inlet valve is arranged on the water inlet channel, the detection element is arranged on the cleaning device, and when the detection element detects that the mop enters the cleaning chamber, the control element controls the electrically controlled water inlet valve to open, and the water inlet channel is communicated with the clean water chamber and the cleaning chamber.

According to an embodiment of the present invention, the barrel body comprises a containing main body, a water inlet partition and a sewage partition, wherein the containing main body has a containing space, the water inlet partition and the sewage partition are arranged at intervals in the containing space of the containing main body, the clean water chamber is formed between the containing main body and the water inlet partition, the clean water chamber is formed between the water inlet partition and the sewage partition, and the sewage chamber is formed between the containing main body and the sewage partition, the water inlet channel is formed in the water inlet partition, and the water inlet control mechanism is movably arranged in the water inlet partition.

According to an embodiment of the present invention, the water inlet control mechanism includes a trigger, an elastic restoring member, a linking member, a retaining member, an extending member, and a water blocking plug, wherein the trigger and the extending member are respectively disposed at an upper end portion and a lower end portion of the linking member, the linking member is obliquely retained in the cleaning chamber, the trigger and the extending member are located at both sides of the linking member, the water blocking plug is fixed at an end portion of the extending member, the retaining member is fixed at the tub body, a middle portion of the linking member is rotatably mounted at the retaining member, the elastic restoring member is retained between the trigger and the water inlet partition, and the water blocking plug is movably mounted at the water inlet passage.

In another aspect, the present invention provides a cleaning implement comprising a mop and an automatic cleaning bucket as described above.

According to the cleaning barrel and the cleaning tool provided by the invention, the automatic cleaning barrel can accurately control the amount of water entering the cleaning cavity from the clear water cavity, so that water is saved under the condition of ensuring sufficient water in the cleaning cavity, and the waste of water is avoided.

According to the cleaning barrel and the cleaning tool provided by the invention, when the water inlet control mechanism of the automatic cleaning barrel detects that the mop enters the cleaning cavity, the channel for communicating the clean water cavity and the cleaning cavity is controlled to be opened, so that the clean water stored in the clean water cavity can automatically enter the cleaning cavity.

According to the cleaning bucket and the cleaning tool provided by the invention, the water inlet mechanism of the automatic cleaning bucket controls the passage for communicating the clean water cavity and the cleaning cavity to be closed after a mop main body of the mop completely enters the cleaning cavity, so that the phenomenon that water in the cleaning cavity overflows to pollute the use environment when the mop is cleaned due to excessive water in the cleaning cavity is avoided.

According to the cleaning barrel and the cleaning tool provided by the invention, the water inlet control mechanism of the automatic cleaning barrel is controlled to only allow the passage for communicating the clean water cavity with the cleaning cavity to be opened once within a preset time period, so that the condition that the clean water cavity is frequently communicated with the cleaning cavity when a user repeatedly moves the mop up and down is avoided, and the mop cannot be dewatered.

According to the cleaning barrel and the cleaning tool provided by the invention, the automatic cleaning barrel is provided with the sewage cavity, the sewage cavity and the cleaning cavity are independent, and when the mop enters the clean water cavity, stains and sewage attached to the mop can be scraped into the sewage cavity, so that the pollution degree of the mop to clean water in the cleaning cavity is reduced, water is saved, and the cleaning efficiency is improved.

According to the cleaning barrel and the cleaning tool provided by the invention, the water inlet control mechanism of the automatic cleaning barrel electronically detects whether a mop enters the cleaning cavity, and when the mop is detected to enter the cleaning cavity, a channel for communicating the cleaning cavity with the cleaning cavity is electrically opened, so that the electrification and automation degree of the automatic cleaning barrel are improved.

According to the cleaning barrel and the cleaning tool provided by the invention, when the mop enters the cleaning cavity, the water inlet control mechanism is driven to mechanically open the channel for communicating the clean water cavity and the cleaning cavity, and a user does not need to bend down to operate.

According to the cleaning barrel and the cleaning tool provided by the invention, the dirt pumping type cleaning barrel is provided with a transparent cleaning visual window, wherein the cleaning visual window corresponds to the cleaning cavity, after the mop leaves the cleaning cavity, whether sewage remains in the cleaning cavity can be seen through the cleaning visual window, and if the sewage remains in the cleaning cavity, the sewage pump can be started to pump the sewage in the cleaning cavity into the sewage cavity.

According to the cleaning bucket and the cleaning tool provided by the invention, the dirt pumping type cleaning bucket is provided with a detection device, wherein the detection device is used for detecting the movement of the mop, and the detection device controls the sewage pump to be started after the detection that the mop leaves the cleaning cavity, so that the sewage pump can automatically pump the sewage in the cleaning cavity into the sewage cavity without the operation of a user.

According to the cleaning barrel and the cleaning tool provided by the invention, the sewage pumping type cleaning barrel is provided with the water level detection device, wherein the water level detection device is used for detecting the water level in the cleaning cavity, when the detection device detects that the mop leaves the cleaning cavity, the water level detection device starts to detect whether residual sewage exists in the cleaning cavity, and when the water level detection device detects that the sewage remains in the cleaning cavity, the sewage pump is started and pumps the sewage in the cleaning cavity into the sewage cavity.

According to the cleaning barrel and the cleaning tool provided by the invention, the visual cleaning barrel comprises the clear water visual window, and the water level in the clear water cavity of the visual cleaning barrel can be clearly observed through the clear water visual window, so that a user can conveniently and timely supplement the water quantity in the clear water cavity.

According to the cleaning barrel and the cleaning tool provided by the invention, the visual cleaning barrel comprises the sewage visual window, and the water level in a sewage cavity of the visual cleaning barrel can be clearly observed through the sewage visual window, so that a user can pour the sewage in the sewage cavity in time.

According to the cleaning barrel and the cleaning tool provided by the invention, the visual cleaning barrel is provided with at least one group of scales, wherein at least one group of scales corresponds to the water level in the cleaning cavity, and the water level scales in the cleaning cavity can be observed through the cleaning visual window, so that the water inflow entering the cleaning cavity is accurately controlled.

According to the cleaning barrel and the cleaning tool provided by the invention, at least one group of scales corresponds to the water level in the clean water cavity, and the water level scales in the clean water cavity can be observed through the clean water visible window, so that the water level height in the clean water cavity can be conveniently mastered.

According to the cleaning barrel and the cleaning tool provided by the invention, at least one group of scales corresponds to the water level in the sewage cavity, and the water level scales in the sewage cavity can be observed through the sewage visual window, so that the phenomenon that the sewage water level in the sewage cavity is overhigh and overflows to cause the pollution of a use area is avoided.

According to the cleaning barrel and the cleaning tool provided by the invention, the channel for communicating the clean water cavity and the cleaning cavity can be controlled to be opened by operating the water inlet control mechanism of the visual cleaning barrel, so that the clean water contained in the clean water cavity automatically enters the cleaning cavity.

Drawings

FIG. 1 is a schematic diagram of a cleaning tool according to a preferred embodiment of the present invention.

FIG. 2 is an exploded view of an automatic cleaning bucket according to the above preferred embodiment of the present invention.

Fig. 3A is a schematic sectional view illustrating the automatic cleaning bucket according to the above preferred embodiment of the present invention.

FIG. 3B is a schematic view of a stage of the automatic cleaning bucket for washing a mop according to the above preferred embodiment of the present invention.

FIG. 3C is a schematic view of a stage of the automatic cleaning bucket for washing the mop according to the above preferred embodiment of the present invention.

Fig. 4 is an exploded view of the automatic cleaning bucket according to another preferred embodiment of the present invention.

Fig. 5 is a sectional view schematically illustrating the automatic cleaning bucket according to the above preferred embodiment of the present invention.

FIG. 6 is an exploded view of the automatic cleaning bucket according to another preferred embodiment of the present invention.

Fig. 7A is a schematic sectional view illustrating the automatic cleaning bucket according to the above preferred embodiment of the present invention.

FIG. 7B is a schematic view of a stage of the automatic cleaning bucket for washing the mop according to the above preferred embodiment of the present invention.

FIG. 7C is a schematic view of a stage of the automatic cleaning bucket for washing the mop according to the above preferred embodiment of the present invention.

Fig. 8 is a perspective view illustrating a pump-type cleaning bucket according to a preferred embodiment of the present invention.

Fig. 9 is an exploded view of the pump-dirt type cleaning barrel according to the above preferred embodiment of the present invention.

Fig. 10A is a schematic view of the pump-dirt type cleaning barrel according to the above preferred embodiment of the invention.

FIG. 10B is a schematic view of the pump-dirt type cleaning barrel according to the above preferred embodiment of the present invention.

FIG. 10C is a schematic view of the pump-dirt type cleaning barrel according to the above preferred embodiment of the present invention.

Fig. 11 is an exploded view schematically illustrating the pump-dirt type cleaning bucket according to another preferred embodiment of the present invention.

FIG. 12 is a schematic view of the pump-dirt type cleaning barrel according to the above preferred embodiment of the present invention.

Fig. 13 is an exploded view of the pump-dirt type cleaning bucket according to another preferred embodiment of the present invention.

Fig. 14 is a schematic view of the pump-dirt type cleaning barrel according to the above preferred embodiment of the invention.

Fig. 15 is a schematic sectional view of the pump-dirt type cleaning bucket according to another preferred embodiment of the present invention.

Fig. 16 is a schematic sectional view illustrating the pump-dirt type cleaning bucket according to another preferred embodiment of the present invention.

FIG. 17A is a schematic diagram of a structure of a visible cleaning barrel according to a preferred embodiment of the invention.

Fig. 17B is a schematic diagram illustrating the structure of the visible cleaning barrel according to the above preferred embodiment of the present invention.

Fig. 18 is an exploded view of the visual cleaning bucket according to a preferred embodiment of the invention.

Fig. 19 is a schematic view illustrating the use of the visual cleaning bucket according to the above preferred embodiment of the present invention.

Fig. 20 is an exploded view of the visual cleaning bucket according to another preferred embodiment of the present invention.

Fig. 21 is a schematic view illustrating the use of the visual cleaning barrel according to the above preferred embodiment of the present invention.

Fig. 22 is an exploded view of the visual cleaning bucket according to another preferred embodiment of the present invention.

Fig. 23 is a schematic view illustrating the use of the visual cleaning barrel according to the above preferred embodiment of the present invention.

Fig. 24 is an exploded view of the visual cleaning bucket according to another preferred embodiment of the present invention.

Fig. 25 is a schematic view illustrating the use of the visual cleaning bucket according to the above preferred embodiment of the present invention.

Fig. 26A is an exploded view of the visual cleaning bucket according to another preferred embodiment of the invention.

Fig. 26B is an exploded view of the visual cleaning barrel according to another preferred embodiment of the invention.

Fig. 27 is a schematic view illustrating the use of the visual cleaning bucket according to the above preferred embodiment of the present invention.

Fig. 28 is an exploded view of the visual cleaning bucket according to another preferred embodiment of the present invention.

Fig. 29 is a schematic view illustrating the use of the visual cleaning barrel according to the above preferred embodiment of the present invention.

Detailed Description

The following description is provided to disclose the invention so as to enable any person skilled in the art to practice the invention. The preferred embodiments in the following description are given by way of example only, and other obvious variations will occur to those skilled in the art. The underlying principles of the invention, as defined in the following description, may be applied to other embodiments, variations, modifications, equivalents, and other technical solutions without departing from the spirit and scope of the invention.

It will be understood by those skilled in the art that in the present disclosure, the terms "longitudinal", "lateral", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", etc., indicate orientations or positional relationships that are based on those shown in the drawings, which are merely for convenience in describing the present disclosure and to simplify the description, and do not indicate or imply that the device or element so referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus the terms above should not be construed as limiting the present disclosure.

It is understood that the terms "a" and "an" should be interpreted as meaning that a number of one element or element is one in one embodiment, while a number of other elements is one in another embodiment, and the terms "a" and "an" should not be interpreted as limiting the number.

Referring to the drawings of fig. 1 to 3C, a cleaning tool 1000 according to a preferred embodiment of the present invention will be described in the following description, wherein the cleaning tool 1000 includes an automatic cleaning bucket 100 and a flat mop 200, wherein the automatic cleaning bucket 100 has a clean water chamber 101, a cleaning chamber 102, and a dirty water chamber 103, wherein the clean water chamber 102 can be communicated with the cleaning chamber 102, and the dirty water chamber 103 and the cleaning chamber 102 are independent from each other. Clear water in the clear water cavity 103 can enter the cleaning cavity 102, the flat mop 200 can be placed in the cleaning cavity 102 for cleaning, and sewage absorbed by the flat mop 200 can be scraped into the sewage cavity 103 in the cleaning process.

The automatic cleaning barrel 100 further has a water inlet passage 104, wherein the water inlet passage 104 is formed at a lower portion of the automatic cleaning barrel 100, and the water inlet passage 104 can be communicated with the clean water chamber 101 and the cleaning chamber 102. And, when the automatic cleaning bucket 100 receives the flat mop 200, the water inlet passage 104 is automatically opened and the cleaning chamber 102 and the clean water chamber 101 are communicated with each other, and the clean water stored in the clean water chamber 101 can automatically flow from the clean water chamber 101 into the cleaning chamber 102 without a user's stooping operation.

In an embodiment of the present invention, the automatic cleaning bucket 100 comprises a cleaning bucket 10 and a water inlet control mechanism 20, wherein the clean water chamber 101, the cleaning chamber 102, the sewage chamber 103 and the water inlet passage 104 are formed in the cleaning bucket 104. The water inlet control mechanism 20 is disposed on the cleaning barrel 10, the water inlet control mechanism 20 allows the cleaning barrel 10 to be switched between a circulation state and a closed state, the water inlet passage 104 of the cleaning barrel 10 in the circulation state is opened, and the water inlet passage 104 communicates the clean water chamber 101 and the cleaning chamber 102. The water inlet channel 104 of the cleaning barrel 10 in the closed state is closed, the clean water chamber 101 and the cleaning chamber 102 are blocked, and the clean water in the clean water chamber 101 cannot flow into the cleaning chamber 102.

The cleaning barrel 10 comprises a barrel body 11 and a cleaning device 12, the cleaning device 12 has a water filling opening 1201, a cleaning opening 1202 and a sewage opening 1203, wherein the water filling opening 1201, the cleaning opening 1202 and the sewage opening 1203 are arranged at intervals, and the cleaning opening 1202 is located between the water filling opening 1201 and the sewage opening 1203. The clear water chamber 101, wash the chamber 102, dirty water chamber 103 and inhalant canal 104 form in bucket body 11, just wash the chamber 102 and be located dirty water chamber 103 with between the clear water chamber 101. The cleaning device 12 is installed above the tub body 11 in such a manner that the filling port 1201, the cleaning port 1202, and the sewage port 1203 correspond to the clean water chamber 101, the wash chamber 102, and the sewage chamber 103 of the tub body 11, respectively.

The barrel body 11 comprises a container body 111, a water inlet partition 112 and a sewage partition 113, wherein the container body 111 has a container space 1101, the water inlet partition 112 and the sewage partition 113 are arranged at intervals in the container body 111 the container space 1101, the inner wall of the container body 111 and the water inlet partition 112 form the clean water chamber 101, the inner wall of the container body 111, the water inlet partition 112 and the sewage partition 113 form the cleaning chamber 102, and the inner wall of the container body 111 and the sewage partition 113 form the sewage chamber 103. The inlet passage 104 is formed in the inlet baffle 112. The cleaning device 12 is installed above the container body 111 such that the filler 1201, the cleaning port 1202, and the sewage port 1203 correspond to the clean water chamber 101, the wash chamber 102, and the sewage chamber 103, respectively.

The mop 200 includes a mop body 210 and a handle bar 220, wherein the mop body 210 includes a mop plate 211 and a cleaning element 212, wherein a cleaning surface 201 of the mop 200 is formed on the cleaning element 212. The cleaning element 212 is mounted to the mop plate 211 with the cleaning surface 201 facing outward. The mop plate 211 of the mop body 210 is attached to the bottom of the grip bar 220, and the mop 200 cleans a work area such as a floor or window glass by attaching the cleaning surface 201 to the work area.

The water filling opening 1201 is communicated with the clean water cavity 101, so that a user can replenish clean water from the water filling opening 1201 to the clean water cavity 101 without disassembling the cleaning device 12, and the operation is convenient. The cleaning port 1202 is communicated with the cleaning chamber 102, and the mop 200 moves up and down in such a manner that the cleaning surface 201 of the mop body 210 faces the sewage port 1203, enters the cleaning chamber 102 from the cleaning port 1202, soaks in the cleaning chamber 102, and decontaminates. The sewage port 1203 is communicated with the sewage chamber 103, the soaked mop 200 moves from top to bottom after moving from bottom to top, and water absorbed by the mop 200 flows into the sewage chamber 103 from the sewage port 1203 under the action of the cleaning device 12.

Specifically, the cleaning device 12 includes a water feeding part 121, a cleaning part 122, and a water draining part 123, wherein the water feeding part 121, the cleaning part 122, and the water draining part 123 are integrally formed. The water inlet 1201, the cleaning port 1202, and the sewage port 1203 are formed in the water inlet 121, the cleaning part 122, and the dewatering part 123, respectively.

The cleaning portion 122 includes a holding portion 1221 and a scraping portion 1222 opposite to the holding portion 1221, wherein the scraping portion 1222 and the holding portion 1221 are integrally formed, and the scraping portion 1222 connects the holding portion 1221 and the dewatering portion 123. The cleaning port 1202 is formed between the holding portion 1221 and the dirt scraping portion 1222, and the mop 200 can enter the cleaning chamber 102 from the cleaning port 1202 by the cleaning surface 201 of the mop body 210 facing the dirt scraping portion 1222. In addition, during the process that the mop 200 enters the cleaning cavity 102, the dirt scraping part 1222 of the cleaning part 122 presses the mop 200, and the dirt scraping part 1222 can scrape off dirt attached to the cleaning surface 201 of the mop 200.

Preferably, the cleaning opening 1202 of the cleaning portion 122 is shaped like a "convex" to guide the user to insert the mop 200 into the cleaning cavity 102 with the cleaning surface 201 facing the scraping portion 1222. Specifically, the holder 1221 includes two carriage holders 12211 and a rod holder 12212, the rod holder 12212 is located between the two carriage holders 12211, the two holder 12211 extends outward from the rod holder 12212, and the cleaning opening 1202 is formed in a shape of a letter "convex" between the two carriage holders, the rod holder 12212, and the dirt scraping portion 1222.

Further, the scraping portion 1222 is located between the cleaning opening 1202 and the sewage opening 1203. The dewatering part 123 includes a drainage part 1231 and a maintaining part 1232, wherein the drainage part 1231 and the maintaining part 1232 are integrally formed, and the sewage port 1203 is formed between the drainage part 1231 and the maintaining part 1232. The drainage portion 1231 is located between the scraping portion 1222 and the maintaining portion 1232 of the cleaning portion 122, and the drainage portion 1231 extends from the scraping portion 1222 to the maintaining portion 1232.

Further, the upper surface of the dewatering part 123 is an inclined downward slope, and the inclined upper surface of the dewatering part 123 extends from the dirt scraping part 1222 of the cleaning part 122 to the edge of the sewage port 1203. After the dirt scraping portion 1222 of the cleaning portion 122 scrapes the dirt and the sewage from the mop 200, the scraped sewage and the dirt are guided to flow from the inclined surface of the dewatering portion 123 to the sewage inlet 1203 of the dewatering portion 123, and enter the sewage chamber 103 of the cleaning bucket 10 from the sewage inlet 1203. Preferably, the upper surface of the dewatering part 123 is a plane inclined downward. Optionally, the upper surface of the dewatering part 123 is a curved surface inclined downward.

Specifically, when the mop 200 enters the cleaning cavity 102 from the cleaning opening 1202 from the top to the bottom for the first time, the holding portion 1221 and the dirt scraping portion 1222 of the cleaning portion 122 press against the mop 200 and scrape off dirt and water from the mop 200, and the scraped-off dirt and water flows to the dirt cavity 103 along the inclined surface of the dewatering portion 123. The sewage cavity 103 and the cleaning cavity 102 are independent from each other, so that the stains and the sewage of the mop main body 210 of the mop 200 are scraped once before the mop main body 210 is firstly contacted with the clean water in the cleaning cavity 102, the cleaning efficiency is improved, the pollution degree of the clean water is reduced, and the water is saved.

Further, after the mop body 210 of the mop 200 enters the cleaning cavity 102, water in the cleaning cavity 102 is absorbed, and the mop 200 in the cleaning cavity 102 is moved from bottom to top to the bottom of the mop body 210 of the mop 200 close to the cleaning opening 1202. Then, the mop 200 is moved from the top to the bottom, the holding part 1221 of the cleaning part 122 and the dirt scraping part 1222 press the mop main body 210 of the mop 200 again, and in the process that the mop main body 210 moves downward, the dirt scraping part 1222 scrapes the water and the dirt adsorbed to the mop main body 210, and the scraped water and the dirt flow to the dewatering opening 123 along the inclined surface of the dewatering part 123 and are accumulated in the dirt chamber 103.

Preferably, the cleaning barrel 10 further comprises a dirt filtering device 13, wherein the dirt filtering device 13 has a dirt inlet 1301, a dirt containing space 1302 and a filtering opening 1303, wherein the dirt containing space 1302 communicates with the dirt inlet 1301 and the filtering opening 1303, and the dirt filtering device 13 is held below the dirt scraping portion 1222 of the cleaning portion 122 of the cleaning device 12. The dirt inlet 1301 and the filter opening 1303 of the dirt filter 13 are respectively communicated with the cleaning chamber 102 and the sewage chamber 103. In the process that the mop main body 210 of the mop 200 enters the cleaning cavity 102, the dirt filtering device 13 extrudes and scrapes the cleaning surface 201 of the mop 200, the sewage and the impurities adsorbed by the cleaning surface 201 are scraped off by the dirt filtering device 13 and enter the object containing space 1302 from the dirt inlet 1301, the sewage enters the sewage cavity 103 from the filtering opening 1303, and the impurities are blocked and then are left in the object containing space 1302.

Specifically, the dirt filtering device 13 includes a dirt rubbing plate 131, a dirt accommodating box 132, and a filter 133, wherein the dirt rubbing plate 131 and the filter 133 are respectively disposed on the dirt accommodating box 132, the filter 133 is retained in the filtering opening 1303, and the dirt inlet 1301 and the dirt accommodating space 1302 are formed between the dirt rubbing plate 131 and the dirt accommodating box 132. The dirt scraping plate 131 is held below the dirt scraping portion 1222 of the cleaning portion 122 in a forward protruding manner at an interval such that the dirt inlet 1301 is communicated with the cleaning opening 1202, and the dirt filtering device 13 is held above the dirt partition 113. Preferably, the dirt scraping plate is obliquely provided to the dirt accommodating box.

When the mop main body 210 of the mop 200 enters the cleaning cavity 102 from the cleaning opening 1202 from top to bottom, the smearing plate 131 can press the cleaning surface 201 of the mop main body 210, scrape off the sewage and the impurities adsorbed by the cleaning surface 201, the scraped sewage and the impurities enter the containing space 1302 from the sewage inlet 1301, the filter element 133 filters the sewage and the impurities in the dirt containing box 132, the filtered sewage and the filtered impurities flow into the sewage cavity 103 from the filtering opening 1303, and the impurities with larger volume are retained in the containing space 1302. For example, but not limiting of, the filter 133 is implemented as a filter net or the like.

Preferably, the dirt filtering device 13 is detachably mounted below the cleaning device 12, so that a user can conveniently remove the impurities in the accommodating space 1302 by detaching the dirt filtering device 13. In a particular embodiment of the invention, the dirt filter means 13 is mounted to the cleaning means 12 in a drawable manner. For example, the cleaning device 12 is provided with two slide rails, the dirt accommodating box 132 of the dirt filtering device 13 is provided with slide grooves corresponding to the slide rails, and the dirt accommodating box 132 is detachably mounted to the cleaning device 12 in such a manner that the slide grooves correspond to the slide rails. Optionally, the dirt filter means 13 is removably mounted to the cleaning means 12 by a snap-fit. Optionally, the dirt filter means 13 is removably mounted to the cleaning means 12 by means of a threaded connection. Optionally, the dirt filter 13 and the cleaning device 12 are integrally formed. It should be understood by those skilled in the art that the embodiment of the dirt container 13 disposed on the cleaning device 12 is only for example and should not be construed as limiting the content and scope of the automatic cleaning bucket 100 of the present invention.

Referring to fig. 1 to 3C, in an embodiment of the present invention, the water inlet control mechanism 20 of the automatic cleaning bucket 100 includes an electrically controlled water inlet valve 21, a control element 22 and a detection element 23, wherein the electrically controlled water inlet valve 21 is disposed in the water inlet channel 104 of the bucket body 11, the electrically controlled water inlet valve 21 is drivingly connected to the control element 22, and the control element 22 can drive the electrically controlled water inlet valve 21 to switch between an open state and a closed state. The control unit 22 is communicatively connected to the detection unit 23, the detection unit 23 detects whether the mop 200 enters the cleaning cavity 102 of the cleaning bucket 10 in real time, and sends a control command to the control unit 23 when the detection unit 23 detects that the mop 200 enters the cleaning cavity 102 of the cleaning bucket 20, and the control unit 23 controls the electrically controlled water inlet valve 21 to switch to the open state when executing the control command. When the electrically controlled water inlet valve 21 is in the open state, the water inlet channel 104 of the cleaning barrel 100 is communicated with the clean water cavity 101, the level of clean water contained in the clean water cavity 101 is higher, and the clean water in the clean water cavity 101 automatically flows into the cleaning cavity 102.

In a specific embodiment of the present invention, the detecting member 23 is installed at the cleaning device 12 of the cleaning bucket 10, and the detecting member 23 is close to the cleaning port 1202, and the control member 23 drives the electrically controlled water inlet valve 21 to be opened when the mop body 210 of the mop 200 passes through the cleaning port 1202.

Preferably, the detecting member 23 is disposed above the cleaning part 122 of the cleaning device 12, the detecting member 23 is located above the cleaning opening 1202, and the detecting member 23 can detect the mop 200 immediately when the mop 200 approaches the upper surface of the cleaning tub 100. Alternatively, the detection element 23 is installed below the cleaning portion 122.

Optionally, the detection element 23 is arranged below the cleaning device 12. For example, but not limited to, the sensing element 23 is mounted on the back of the cleaning device 12, the sensing element 23 is mounted on the inlet partition 112, and the sensing element 23 is mounted on the waste partition 113. It should be understood by those skilled in the art that the specific installation position of the detecting element 23 is only an example and is not intended to limit the content and scope of the automatic cleaning bucket 100 of the present invention.

Preferably, the detecting element 23 is installed on the maintaining portion 1222 of the cleaning portion 122 to emit a detecting beam toward the dirt scraping portion 1221 and receive a reflected beam reflected by the detecting beam, when the mop body 210 of the mop 200 passes by the detecting element 23, the mop body 210 blocks the detecting beam, the reflected beam received by the detecting element 23 changes, the detecting element 23 determines that the mop 200 enters the cleaning cavity 102 of the cleaning bucket 10, and then sends the control command to the control element 23, and the control element 23, when executing the control command, drives the electrically controlled water inlet valve 21 to open, so that the clean water in the clean water cavity 101 can automatically flow into the cleaning cavity 102. The detection element 23 may be attached to the carriage maintaining part 12221 and/or the lever maintaining part 12222 of the maintaining part 1222. Alternatively, the detection element 23 emits the detection beam toward the maintenance part 1222 in such a manner as to be attached to the dirt scraping part 1221 of the cleaning part 122.

It should be noted that the embodiment of the detecting element 23 is not limited, and the detecting element may be implemented as one or more of a laser sensor, a microwave detector or a detecting device known to those skilled in the art, and the embodiment of the detecting element 23 is only an example and is not intended to limit the content and scope of the automatic cleaning bucket 100 of the present invention.

Referring to fig. 1 to 3C, in a specific embodiment of the present invention, the electrically controlled water inlet valve 21 of the water inlet control mechanism 20 and the control element 22 are integrated, for example, the water inlet control mechanism 20 is implemented as a solenoid valve, when the detection element 23 detects that the mop 200 enters the cleaning chamber 102, the solenoid valve is opened, the clean water chamber 101 is communicated with the cleaning chamber 102, and the clean water in the clean water chamber 101 automatically flows into the cleaning chamber 102. Referring to fig. 4 to 5, in an embodiment of the present invention, the electrically controlled water inlet valve 21 and the control element 22 of the water inlet control mechanism 20 are of a split structure, for example, the control element 22 is implemented as an electric telescopic rod, the electrically controlled water inlet valve 21 is a water blocking plug, the water blocking plug is mounted at an end of the electric telescopic rod, and the electric telescopic rod is extended or retracted according to a detection result of the detection element 23, so that the water blocking plug blocks the water inlet passage 104, or allows the clean water chamber 101 and the clean water chamber 102 to communicate.

Preferably, the control element 22 of the inlet control mechanism 20 is preset with an operating rule to accurately control the amount of water in the wash chamber 102. For example, when the detecting element 23 detects that the mop body 210 enters the cleaning cavity 103, the control element 22 drives the electrically controlled water inlet valve 21 to open, and after the control element 22 keeps the electrically controlled water inlet valve 21 in the open state for a predetermined time, the control element 22 automatically controls the electrically controlled water inlet valve 21 to close, so as to avoid that the water in the cleaning cavity is too much, and the water in the cleaning cavity overflows to pollute the using environment when the mop is cleaned. Or, the control element 22 only allows the passage for communicating the clean water chamber 101 and the cleaning chamber to be opened once within a preset time period, so as to prevent the clean water chamber and the cleaning chamber from being frequently communicated when the user repeatedly moves the mop 200 up and down, thereby preventing the mop from being dehydrated. It should be understood by those skilled in the art that the specific embodiment of the operation rule of the control unit 20 is only an example and is not intended to limit the content and scope of the automatic cleaning bucket 100 of the present invention.

Referring to fig. 6-7C, in an embodiment of the present invention, the inlet control mechanism 20 allows the inlet passage 104 to be opened or closed by mechanical control. Specifically, the water inlet control mechanism 20 is movably held in the cleaning chamber 102, when the mop body 210 of the mop 200 enters the cleaning chamber 102 from the cleaning opening 1202, the mop body 210 can drive the water inlet control mechanism 20 to move relative to the containing body 111, and the water inlet passage 104 communicating the clean water chamber 101 and the cleaning chamber 102 is opened, so that the clean water in the clean water chamber 101 can automatically flow into the cleaning chamber 102.

More specifically, the water inlet control mechanism 20 includes a trigger 24, an elastic restoring member 25, a linking member 26, a retaining member 27, an extending member 28 and a water blocking plug 29, wherein the linking member 26 extends downward from the trigger 24, the trigger 24 is disposed at an upper end of the linking member 26, and a lower end of the trigger 24 is connected to the extending member 28. The linkage 26 is obliquely held in the cleaning cavity 102, the trigger 24 and the extension 28 are located at two sides of the linkage 26, and the trigger 24, the linkage 26 and the extension 28 form a "Z" structure. The water blocking plug 29 is fixed at the end of the extending member 28, the holding member 27 is fixed at the tub body 11, the middle of the linkage member 26 is rotatably mounted at the holding member 27, the resilient restoring member 25 is held between the trigger member 24 and the water inlet partition 112 of the tub body 11, and the water blocking plug 29 is movably mounted at the water inlet passage 104.

When the mop body 210 of the mop 200 enters the cleaning cavity 103 from the cleaning opening 1202 in a manner of being attached to the trigger 24 of the water inlet control mechanism 20, the mop body 210 drives the trigger 24 to move backward, presses the elastic restoring member 25, and pushes the linkage 26 to rotate counterclockwise relative to the holder 27, and the extending member 28 and the water-blocking plug 29 disposed at the lower end of the linkage 26 are driven by the linkage 26 and move forward, away from the water inlet partition 112. After the water-isolating plug 29 leaves the water inlet channel 104, the water inlet channel 104 communicates the clean water chamber 101 and the cleaning chamber 102, and the clean water in the clean water chamber 101 automatically flows into the cleaning chamber 102.

After the force of the mop 200 on the trigger 24 of the water inlet control mechanism 20 is removed, the elastic potential energy accumulated by the elastic restoring member 25 is released, the elastic restoring member 25 drives the linkage 26 to rotate clockwise relative to the retainer 27, the trigger 24 restores to the initial position, the extension member 28 and the water-blocking plug 29 arranged at the lower end of the linkage 26 move backwards, approach the water inlet partition 112 and are retained in the water inlet channel 104, the clean water chamber 101 and the cleaning chamber 102 are blocked, and the clean water in the clean water chamber 101 cannot continue to enter the cleaning chamber 102.

Preferably, the width of the cleaning cavity 102 and the cleaning opening 1202 is greater than the width of the mop body 210 of the mop 200, and the water inlet control mechanism 20 is held within the cleaning cavity 102 with the trigger 24 near the end of the cleaning opening 1202 and allows the mop 200 to enter the cleaning cavity 102 from the cleaning opening 1202 without the mop body 210 contacting the trigger 24 and also allows the mop 200 to enter the cleaning cavity 102 from the cleaning opening 1202 with the mop body 210 abutting the trigger 24. Thus, when the mop 200 enters the washing chamber 102 with the trigger 24 abutting the trigger 24, the cleaning bucket 10 can be switched from the closed state to the circulation state, and when the mop 200 enters the washing chamber 102 with the mop body 210 not contacting the trigger 24, the cleaning bucket 10 still maintains the closed state. In this way, the user can control the amount of water in the cleaning chamber 102 according to the use requirement, and the frequent communication between the cleaning chamber 101 and the cleaning chamber 103, which results in the mop 200 being unable to be dewatered, can be avoided.

The cleaning tub 10 further includes a holder 14, wherein the holder 14 is rotatably installed at an upper portion of the tub main body 11, and a user can move the automatic cleaning tub 100 by holding the holder 14.

The cleaning bucket 10 further includes a drain valve 15, the bucket body 11 further has a drain port 105, wherein the drain port 105 is formed at the lower part of the containing body 111, and the drain port 105 can be communicated with the sewage chamber 103, the drain valve 15 is installed at the drain port 105, and the drain valve 15 can be utilized to open the drain port 105 or close the drain port 105. When the water outlet 105 is opened, the sewage in the sewage cavity 103 can be automatically discharged out of the barrel, and a user does not need to pour the sewage.

Referring to fig. 8 to 9 of the specification, a cleaning tool 1000 according to some preferred embodiments of the present invention will be described in the following description, wherein the cleaning tool 1000 includes a pump-sewage type cleaning bucket 100 and a flat mop 200, wherein the pump-sewage type cleaning bucket 100 has a clean water chamber 101, a cleaning chamber 102, a sewage chamber 103, and a water inlet passage 104 for communicating the clean water chamber 101 and the cleaning chamber 102, wherein the clean water chamber 101, the cleaning chamber 102, and the sewage chamber 103 are disposed to be spaced apart from each other. The water inlet channel 104 is formed at the lower part of the pump-dirt type cleaning barrel 100, and after the water inlet channel 104 communicates the clean water chamber 101 and the cleaning chamber 102, the clean water in the clean water chamber 101 automatically flows into the cleaning chamber 102. The flat mop 200 may be placed in the cleaning chamber 102 of the pump-dirt type cleaning bucket 100 for cleaning and decontaminating, and water absorbed by the flat mop 200 after cleaning may be drained into the dirt chamber 103. Further, the sewage in the cleaning cavity 102 can also be pumped into the sewage cavity 103, so that the sewage remaining in the cleaning cavity 102 is prevented from polluting the clean water entering the cleaning cavity 102, the cleanliness of the water in the cleaning cavity 102 is guaranteed, and the cleaning effect of the sewage pumping type cleaning bucket 100 for cleaning the flat mop is improved.

Specifically, the dirty-pumping cleaning tank 100 includes a cleaning tank 10 and at least one sewage pump 50, wherein the cleaning tank 10 includes a container 11 and a cleaning device 12, the cleaning device 12 has a water inlet 1201, a cleaning port 1202 and a sewage port 1203, wherein the water inlet 1201, the cleaning port 1202 and the sewage port 1203 are disposed at a distance from each other, and the cleaning port 1202 is located between the water inlet 1201 and the sewage port 1203. Clear water chamber 101 wash chamber 102 dirty water chamber 103 and inhalant canal 104 form in splendid attire device 11, just wash chamber 102 and be located dirty water chamber 103 with between clear water chamber 101. The cleaning device 12 is installed above the loading device 11 in such a manner that the filling port 1201, the cleaning port 1202, and the sewage port 1203 correspond to the clean water chamber 101, the wash chamber 102, and the sewage chamber 103 of the loading device 11, respectively. The sewage pump 50 has a sewage suction port 501 and a sewage discharge port 502, and the sewage pump 50 is provided in the cleaning bucket 10 in such a manner that the sewage suction port 501 and the sewage discharge port 502 are communicated with the cleaning chamber 102 and the sewage chamber 103, respectively. The sewage pump 50 pumps the sewage in the cleaning chamber 102 in through the sewage suction port 501 and pumps the sewage out of the sewage discharge port 502 into the sewage chamber 103.

The mop 200 includes a mop body 210 and a holding bar 220, wherein the mop body 210 includes a mop plate 211 and a cleaning element 212, wherein the cleaning element 212 has a cleaning surface 2120. The cleaning element 212 is mounted on the carriage 211 with the cleaning surface 2120 facing outward. The mop plate 211 of the mop body 210 is mounted on the bottom of the grip lever 220, and the mop 200 cleans a working area such as a floor or window glass by attaching the cleaning surface 2120 to the working area.

The container 11 includes a container body 111, a water inlet partition 112 and a sewage partition 113, wherein the container body 111 has a container space 1101, the water inlet partition 112 and the sewage partition 113 are disposed at intervals in the container body 111 the container space 1101, the inner wall of the container body 111 and the water inlet partition 112 form the clean water chamber 101, the inner wall of the container body 111, the water inlet partition 112 and the sewage partition 113 form the cleaning chamber 102, and the inner wall of the container body 111 and the sewage partition 113 form the sewage chamber 103. The inlet passage 104 is formed in the inlet baffle 112. The cleaning device 12 is installed above the container body 111 such that the filler 1201, the cleaning port 1202, and the sewage port 1203 correspond to the clean water chamber 101, the wash chamber 102, and the sewage chamber 103, respectively.

The water filling opening 1201 is communicated with the clean water cavity 101, so that a user can replenish clean water from the water filling opening 1201 to the clean water cavity 101 without disassembling the cleaning device 12, and the operation is convenient. The cleaning port 1202 is communicated with the cleaning chamber 102, and the mop 200 moves up and down in such a manner that the cleaning surface 2120 of the mop body 210 faces the sewage port 1203, enters the cleaning chamber 102 from the cleaning port 1202, soaks in the cleaning chamber 102, and decontaminates. The sewage port 1203 is communicated with the sewage chamber 103, the soaked mops 200 move from bottom to top and then from top to bottom, and water absorbed by the mops 200 flows into the sewage chamber 103 from the sewage port 1203 under the action of the cleaning device 12.

Specifically, the cleaning device 12 includes a water feeding part 121, a cleaning part 122, and a water draining part 123, wherein the water feeding part 121, the cleaning part 122, and the water draining part 123 are integrally formed. The water inlet 1201, the cleaning port 1202, and the sewage port 1203 are formed in the water inlet 121, the cleaning part 122, and the dewatering part 123, respectively.

The cleaning portion 122 includes a holding portion 1221 and a scraping portion 1222 opposite to the holding portion 1221, wherein the scraping portion 1222 and the holding portion 1221 are integrally formed, and the scraping portion 1222 connects the holding portion 1221 and the dewatering portion 123. The cleaning port 1202 is formed between the holding portion 1221 and the scraping portion 1222, and the mop 200 can enter the cleaning chamber 102 from the cleaning port 1202 by the cleaning surface 2120 of the mop body 210 facing the scraping portion 1222. In addition, during the process that the mop 200 enters the cleaning cavity 102, the dirt scraping portion 1222 of the cleaning portion 122 presses the mop 200, and the dirt scraping portion 1222 can scrape off dirt attached to the cleaning surface 2120 of the mop 200.

Preferably, the cleaning opening 1202 of the cleaning portion 122 is shaped like a "convex" to guide a user to insert the mop 200 into the cleaning cavity 102 with the cleaning surface 2120 facing the scraping portion 1222. Specifically, the holder 1221 includes two carriage holders 12211 and a rod holder 12212, the rod holder 12212 is located between the two carriage holders 12211, the two holder 12211 extends outward from the rod holder 12212, and the cleaning opening 1202 is formed in a shape of a letter "convex" between the two carriage holders, the rod holder 12212, and the dirt scraping portion 1222.

Further, the scraping portion 1222 is located between the cleaning opening 1202 and the sewage opening 1203. The dewatering part 123 includes a drainage part 1231 and a maintaining part 1232, wherein the drainage part 1231 and the maintaining part 1232 are integrally formed, and the sewage port 1203 is formed between the drainage part 1231 and the maintaining part 1232. The drainage portion 1231 is located between the scraping portion 1222 and the maintaining portion 1232 of the cleaning portion 122, and the drainage portion 1231 extends from the scraping portion 1222 to the maintaining portion 1232.

Further, the upper surface of the dewatering part 123 is an inclined downward slope, and the inclined upper surface of the dewatering part 123 extends from the scraping part 1222 of the cleaning part 122 to the edge of the sewage port 1203. After the dirt and the dirty water on the mop 200 are scraped off by the dirt scraping portion 1222 of the cleaning portion 122, the scraped off dirty water and dirt are guided to flow from the inclined surface of the dewatering portion 123 to the sewage port 1203 of the dewatering portion 123, and enter the sewage chamber 103 of the cleaning tub 10 from the sewage port 1203. Preferably, the upper surface of the dewatering part 123 is a plane inclined downward. Optionally, the upper surface of the dewatering part 123 is a curved surface inclined downward.

Specifically, when the mop 200 enters the cleaning cavity 102 from the cleaning opening 1202 from the top to the bottom for the first time, the holding portion 1221 and the dirt scraping portion 1222 of the cleaning portion 122 press against the mop 200 and scrape off dirt and water from the mop 200, and the scraped-off dirt and water flows to the dirt cavity 103 along the inclined surface of the dewatering portion 123. The sewage cavity 103 and the cleaning cavity 102 are independent from each other, so that the dirt and sewage of the mop main body 210 of the mop 200 are scraped once before the mop main body 210 is contacted with the clean water in the cleaning cavity 102 for the first time, the cleaning efficiency is improved, the pollution degree of the clean water is reduced, and the water is saved.

Further, after the mop main body 210 of the mop 200 enters the cleaning cavity 102, the water in the cleaning cavity 102 is absorbed, and the mop 200 in the cleaning cavity 102 is moved from bottom to top to the bottom of the mop main body 210 of the mop 200 close to the cleaning opening 1202. Then, the mop 200 is moved from the top to the bottom, the holding part 1221 of the cleaning part 122 and the dirt scraping part 1222 press the mop body 210 of the mop 200 again, and the dirt scraping part 1222 scrapes off the water and the dirt adsorbed to the mop body 210 while the mop body 210 moves downward, and the scraped water and the dirt flow to the water removing opening 123 along the inclined surface of the water removing part 123 and are accumulated in the dirt chamber 103.

Preferably, the cleaning barrel 10 further comprises a dirt filtering device 13, wherein the dirt filtering device 13 has a dirt inlet 1301, a dirt containing space 1302 and a filtering opening 1303, wherein the dirt containing space 1302 communicates with the dirt inlet 1301 and the filtering opening 1303, and the dirt filtering device 13 is held below the dirt scraping portion 1222 of the cleaning portion 122 of the cleaning device 12. The dirt inlet 1301 and the filter opening 1303 of the dirt filter 13 are respectively communicated with the cleaning chamber 102 and the sewage chamber 103. In the process that the mop main body 210 of the mop 200 enters the cleaning cavity 102, the dirt filtering device 13 extrudes and scrapes the cleaning surface 2120 of the mop 200, the sewage and the impurities adsorbed by the cleaning surface 2120 are scraped off by the dirt filtering device 13 and enter the object containing space 1302 through the dirt inlet 1301, the sewage enters the sewage cavity 103 through the filtering opening 1303, and the impurities are blocked and then are left in the object containing space 1302.

Specifically, the dirt filtering device 13 includes a dirt rubbing plate 131, a dirt accommodating box 132, and a filter 133, wherein the dirt rubbing plate 131 and the filter 133 are respectively disposed on the dirt accommodating box 132, the filter 133 is retained in the filtering opening 1303, and the dirt inlet 1301 and the dirt accommodating space 1302 are formed between the dirt rubbing plate 131 and the dirt accommodating box 132. The dirt scraping plate 131 is held below the dirt scraping portion 1222 of the cleaning portion 122 in a forward protruding manner at an interval such that the dirt inlet 1301 is communicated with the cleaning opening 1202, and the dirt filtering device 13 is held above the dirt partition 113. Preferably, the dirt scraping plate is obliquely disposed to the dirt accommodating case 132.

When the mop main body 210 of the mop 200 enters the cleaning cavity 102 from the cleaning port 1202 from top to bottom, the dirt rubbing plate 131 can press the cleaning surface 2120 of the mop main body 210 and scrape off the sewage and the impurities adsorbed by the cleaning surface 2120, the scraped sewage and impurities enter the accommodating space 1302 from the dirt inlet 1301, the filter element 133 filters the sewage and the impurities in the dirt accommodating box 132, the filtered sewage and the filtered impurities flow into the sewage cavity 103 from the filter opening 1303, and the impurities with larger volume are retained in the accommodating space 1302. For example, but not limiting of, the filter 133 is implemented as a filter net or the like.

Preferably, the dirt filtering device 13 is detachably mounted below the cleaning device 12, so that a user can conveniently remove the impurities in the accommodating space 1302 by detaching the dirt filtering device 13. In a particular embodiment of the invention, the dirt filter means 13 is mounted to the cleaning means 12 in a drawable manner. For example, the cleaning device 12 is provided with two slide rails, the dirt accommodating box 132 of the dirt filtering device 13 is provided with slide grooves corresponding to the slide rails, and the dirt accommodating box 132 is detachably mounted to the cleaning device 12 in such a manner that the slide grooves correspond to the slide rails. Optionally, the dirt filter means 13 is removably mounted to the cleaning means 12 by a snap-fit. Optionally, the dirt filter 13 is detachably mounted to the cleaning device 12 by means of a screw connection. Optionally, the dirt filter 13 and the cleaning device 12 are integrally formed. It should be understood by those skilled in the art that the specific embodiment of the dirt container 13 disposed on the cleaning device 12 is only for example and should not be construed as limiting the content and scope of the visual cleaning bucket 100 of the present invention.

In a specific embodiment of the present invention, the sewage pump 50 is installed at the bottom of the sewage partition 113, and specifically, the bottom of the sewage partition 113 has a fitting 11301, and the sewage pump 50 is hermetically installed at the fitting 11301 in such a manner that the sewage suction port 501 and the sewage discharge port 502 are communicated with the cleaning chamber 102 and the sewage discharge port 103, respectively. The sewage pump 50 is located at the bottom of the sewage partition 113, and has the shortest sewage discharge stroke, high power and low consumption.

In another embodiment of the present invention, the sewage pump 50 includes a pump body 51, a sewage suction pipe 52, and a sewage discharge pipe 53, wherein the sewage suction pipe 52 and the sewage discharge pipe 53 are respectively communicated with both ends of the pump body 51, and the sewage suction port 501 and the sewage discharge port 502 are respectively formed in the sewage suction pipe 52 and the sewage discharge pipe 53. The pump main body 51 is disposed in the cleaning bucket 10 in such a manner that the sewage suction pipe 52 and the sewage discharge pipe 53 are respectively located in the cleaning chamber 102 and the sewage chamber 103, and the sewage suction pipe 52 extends from the pump main body 51 to the bottom of the cleaning chamber 102, so as to ensure that the sewage at the bottom of the cleaning chamber 102 can be drained.

Preferably, the pump body 51 of the sewage pump 50 is installed at a side of the sewage barrier 113. For example, the pump body 51 is fixed to the side of the sewage barrier 113 by gluing, welding, or the like, so as to prevent the sewage pump 50 from being separated from the tub 10.

More preferably, the sewage pump 50 is detachably installed at a side or a top of the sewage barrier 113. Specifically, the sewage pump 50 further comprises a quick release mechanism 54, wherein the quick release mechanism 54 comprises a first quick release member 541 and a second quick release member 542, wherein the first quick release member 541 and the second quick release member 542 are respectively disposed on the sewage barrier 113 and the pump body 51, and the second quick release member 542 is detachably mounted to the first quick release member 541, so that the sewage pump 50 is detachably mounted to the sewage barrier 113. For example, but not limited to, the first quick-release member 541 and the second quick-release member 542 are detachably connected by a screw connection, a magnetic connection, a snap connection, a clearance fit, etc.

Alternatively, the pump body 51 is provided to the cleaning device 12 in such a manner that the soil suction pipe 52 and the soil discharge pipe 53 are located in the wash chamber 102 and the soil chamber 103, respectively. For example, the pump body 51 is fixed to the inner wall of the cleaning device 12 by gluing, welding, or the like. Alternatively, the pump body 51 is embedded in the inner wall of the cleaning device 12. Alternatively, the pump main body 51 may be attached to the cleaning apparatus 12 such that the second quick-release member 542 is detachably attached to the first quick-release member 541.

Alternatively, the pump main body 51 is provided to the dirt filtering device 13 in such a manner that the suction pipe 52 and the discharge pipe 53 are located in the washing chamber 102 and the sewage chamber 103, respectively.

It should be noted that the specific installation position and installation manner of the sewage pump 50 are not limited, and the specific installation position and installation manner of the sewage pump 50 shown in the specification and drawings are only exemplary and should not be construed as limiting the content and scope of the pump-sewage type cleaning bucket 100 of the present invention.

In an embodiment of the present invention, the pump-dirt type cleaning barrel 100 further includes a water inlet control mechanism 20, wherein the water inlet control mechanism 20 is disposed on the cleaning barrel 10, the water inlet control mechanism 20 allows the cleaning barrel 10 to be switched between a flow-through state and a closed state, the water inlet channel 104 of the cleaning barrel 10 in the flow-through state is opened, the water inlet channel 104 communicates the clean water chamber 101 and the cleaning chamber 102, and the clean water in the clean water chamber 101 automatically flows into the dirt water chamber 103. The water inlet channel 104 of the cleaning barrel 10 in the closed state is closed, the clean water chamber 101 and the cleaning chamber 102 are blocked, and the clean water in the clean water chamber 101 cannot flow into the cleaning chamber 102. The sewage pump 50 is operated to pump the sewage in the cleaning chamber 102 in the closed state into the sewage chamber 103, and then the water inlet control mechanism 20 is operated to switch the cleaning bucket 10 from the closed state to the circulation state. In this way, the clean water entering the cleaning chamber 102 can be prevented from being polluted by the residual sewage.

Referring to fig. 15 to 14, in some embodiments of the present invention, the water inlet control mechanism 20 of the pump-dirt cleaning bucket 100 controls the amount of water in the clean water chamber 101 into the clean water chamber 102 by manual operation.

Specifically, the inlet control mechanism 20 includes an operating member 201 and a limiting member 202, wherein the operating member 201 has a flow passage 20131, and the limiting member 202 has a longitudinal assembling chamber 2021 and a transverse flow passage 2022 communicating with the longitudinal assembling chamber 2021. The control member 201 is movably installed in the longitudinal assembling cavity 2021 of the retaining member 202, and when the flow channel 20131 of the control member 201 corresponds to the transverse flow channel 2022 of the retaining member 202, the flow channel 20131 of the control member 201, the transverse flow channel 2022 of the retaining member 202, the water inlet channel 104, the clean water cavity 101 and the cleaning cavity 102 are communicated with each other. The clean water in the clean water chamber 101 sequentially flows into the cleaning chamber 102 through the water inlet passage 104, the flow passage 20131 of the control member 201, and the transverse flow passage 2022 of the limiting member 202.

In an embodiment of the present invention, the operation member 201 includes an operation element 2011, an extension rod 2012 and a movable valve 2013, the operation element 2011 and the movable valve 2013 are respectively disposed at an upper end and a lower end of the extension rod 2012, and the flow channel 20131 is formed in the movable valve 2013. The cleaning portion 122 of the cleaning device 12 has a holding hole 12201, and the operating element 2011 is held above the cleaning device 12 in such a manner that the extension bar 2012 is rotatably mounted to the holding hole 12201 of the cleaning device 12. The retaining member 202 is disposed on the water inlet partition 112 in such a manner that the transverse flow passage 2022 can be communicated with the water inlet passage 104, and the movable valve 2013 is rotatably mounted on the longitudinal assembling cavity 2021 of the retaining member 202. The movable valve 2013 is rotatably retained in the longitudinal cavity 2021 of the retaining member 202 in such a manner that the outer surface of the movable valve fits against the inner surface of the retaining member 202. When the operating element 2011 is rotated by hand, the movable valve 2013 is rotated to the position where the flow channel 20131 corresponds to the transverse flow channel 2022 of the limiting member 202, the cleaning bucket 10 is in the flow state, and the water in the clean water chamber 101 automatically flows into the cleaning chamber 102.

Alternatively, the operating element 2011 is retained above the cleaning device 12 in such a manner that the extension bar 2012 is vertically movably attached to the retaining hole 12201 of the cleaning device 12. The movable valve 2013 is vertically movably held in the longitudinal assembling cavity 2021 of the limiting member 202 in such a manner that an outer surface of the movable valve fits to an inner surface of the limiting member 202. A spring is disposed below the movable valve 2013, and the cleaning bucket 10 can be switched between the flow-through state and the closed state by pressing the operating element 2011.

It should be noted that the embodiment of the water inlet control mechanism 20 is only an example, and the water inlet control mechanism 20 can be implemented as a pedal drive, an electric control drive, etc. to switch the cleaning bucket 10 between the circulation state and the closing device. It should be understood by those skilled in the art that the specific embodiment of the inlet control mechanism 20 is only an example and should not be construed as limiting the contents and scope of the suzuo pump dirt cleaning bucket 100 of the present invention.

In this embodiment of the pump-dirt cleaning barrel 100 of the present invention, the pump-dirt cleaning barrel 100 further includes a visual window 30, wherein the visual window 30 includes at least one transparent cleaning visual window 31, wherein the transparent cleaning visual window 31 corresponds to the cleaning cavity 102 of the cleaning barrel 10, and the amount of water in the cleaning cavity 102 can be observed through the cleaning visual window 31, so as to prevent the amount of water in the cleaning cavity 102 from being too much or too little.

Preferably, the cleaning window 31 extends from a lower edge of the cleaning tub 10 to an upper edge of the cleaning tub 10. Thus, the user can observe whether there is residual sewage at the bottom of the cleaning chamber 102 after the flat mop 200 leaves the cleaning chamber 102, and turn on the sewage pump 50 to pump the sewage in the cleaning chamber 102 into the sewage chamber 103 when the residual sewage in the cleaning chamber 102 is found.

In an embodiment of the present invention, the visual window 30 includes a transparent clear water visual window 32, wherein the transparent clear water visual window 32 corresponds to the clear water cavity 102 of the cleaning barrel 10, and the amount of the clear water in the clear water cavity 101 can be observed through the clear water visual window 32, so that the user can replenish the clear water into the clear water cavity 101 in time. Preferably, the fresh water visible window 32 extends from the lower edge of the cleaning bucket 10 to the upper edge of the cleaning bucket 10.

Referring to fig. 15 to 14, in an embodiment of the present invention, the viewing window 30 includes a transparent sewage viewing window 33, wherein the transparent sewage viewing window 32 corresponds to the sewage chamber 103 of the cleaning bucket 10, and the amount of water in the sewage chamber 103 can be viewed through the sewage viewing window 33, so that a user can pour the sewage in the sewage chamber 103 in time. Preferably, the dirty water visible window 33 extends from a lower edge of the cleaning bucket 10 to an upper edge of the cleaning bucket 10.

Preferably, the cleaning visible window 31, the clear water visible window 32 and the sewage visible window 33 are integrally formed, that is, the clear water visible window 32 is connected with the cleaning visible window 31 and the sewage visible window 33, and the visible window 30 is of an integrated structure. For example, the sidewall of the cleaning barrel 10 is made of a transparent material, and the amounts of water in the cleaning cavity 102, the clean water cavity 101 and the sewage cavity 103 can be clearly observed through the transparent sidewall of the cleaning barrel 10, that is, the sidewall of the cleaning barrel 10 serves as the visible window 30.

Preferably, the cleaning view window 31, the clear water view window 32 and the sewage view window 33 are arranged at intervals, that is, the cleaning view window 31, the clear water view window 32 and the sewage view window 33 are independent from each other.

In this embodiment of the present invention, the pump-dirt type cleaning bucket 100 further includes at least one set of scales 40, wherein the scales 40 are disposed on the cleaning bucket 10, at least one set of scales 40 corresponds to the water level in the cleaning cavity 102, and the water level scales in the cleaning cavity 102 can be observed through the cleaning visual window 31, so as to accurately control the water inflow into the cleaning cavity 102. For example, the scales corresponding to the water level in the cleaning chamber 102 can identify words such as "standard water level" and "maximum water level", and the user can control the water level entering the cleaning chamber 102 between the "standard water level" and the "maximum water level", so as to ensure that the flat mop 200 can be sufficiently cleaned and prevent the water in the cleaning chamber 102 from overflowing after the flat mop 200 is put into the cleaning chamber 102.

Preferably, at least one group of scales 40 corresponds to the water level in the sewage cavity 103, and the water level scales in the sewage cavity 103 can be observed through the sewage visual window 33, so that the problem that the use area is polluted due to the overflow of the sewage in the sewage cavity 103 due to too high water level is avoided.

Preferably, at least one group of scales 40 corresponds to the water level in the clear water cavity 101, the water level scales in the clear water cavity 101 can be observed through the clear water visual window 32, the water level height in the clear water cavity 101 is convenient to master, and when the water level in the clear water cavity 101 is low, a proper amount of clear water can be timely supplemented.

It is worth mentioning that the scale is arranged on the cleaning barrel 10, so that the user can clearly control the water volume in the clean water cavity 101, the cleaning cavity 102 and the sewage cavity 103, the overflow caused by the overhigh water level is avoided, and the phenomenon of dumping caused by the serious unbalance of the water volume distribution in the cleaning barrel 10 is avoided.

Referring to fig. 15, the pump-dirt type cleaning bucket 100 further includes a detection device 60, wherein the detection device 60 is installed in the cleaning bucket 10, the detection device 60 is communicatively connected to the sewage pump 50, and after the detection device 60 detects that the flat mop 200 in the cleaning chamber 102 leaves the cleaning chamber 102, the detection device 60 controls the sewage pump 50 to be kept in an open state and pumps the residual sewage in the cleaning chamber 102 into the sewage chamber 102.

Specifically, the detection device 60 is located near the cleaning opening 1202, and the detection device 60 is located above the cleaning device 12, so that the detection device 60 can detect that the flat mop 200 moves from top to bottom immediately when the flat mop 200 approaches the upper surface of the cleaning bucket 100 and enters the cleaning chamber 102. When the detection device 60 detects that the flat mop 200 moves in the reverse direction and leaves the cleaning chamber 102 from the bottom to the top, the sewage pump 50 is controlled to be turned on to pump the sewage remaining in the cleaning chamber 102 into the sewage chamber 102. For example, but not limiting of, the detection device 60 may be implemented as a laser detector, a microwave detector, or other detection device.

Referring to fig. 16, the pump-sewage cleaning bucket 100 further includes a water level detecting device 70, wherein the water level detecting device 70 is installed at the bottom of the washing chamber 102, and the water level detecting device 70 is communicably connected to the detecting device 60 and the sewage pump 50. The water level detecting device 70 is used for detecting the water level in the cleaning chamber 102, when the detecting device 60 detects that the flat mop 200 leaves the cleaning chamber 102, the water level detecting device 70 starts to detect whether there is residual sewage in the cleaning chamber 102, and when the water level detecting device 70 detects that the sewage remains in the cleaning chamber 102, the sewage pump 50 is turned on, and the sewage pump 50 in the cleaning chamber 102 is driven into the sewage chamber 103. If the water level detecting device 70 does not detect the residual sewage in the cleaning chamber 102, the sewage pump 50 continues to be kept in the closed state. In this way, the power consumption of the sewage pump 50 can be reduced.

The cleaning tub 10 further includes a holder 14, wherein the holder 14 is rotatably installed at an upper portion of the tub main body 11, and a user can move the visible cleaning tub 100 by holding the holder 14.

The cleaning barrel 10 further comprises a drainage valve 15, the container 11 further has a drainage outlet 105, wherein the drainage outlet 105 is formed at the lower part of the container body 111, the drainage outlet 105 can be communicated with the sewage chamber 103, the drainage valve 15 is installed at the drainage outlet 105, and the drainage valve 15 can open the drainage outlet 105 or close the drainage outlet 105. When the drainage outlet 105 is opened, the sewage in the sewage chamber 103 can be automatically drained out of the barrel without the user pouring the sewage by dumping the cleaning barrel 10.

Referring to the drawings of fig. 1 to 29, a visual cleaning bucket 100 according to some preferred embodiments of the present invention will be described in the following description, wherein the visual cleaning bucket 100 is applied to a cleaning tool 1000, wherein the cleaning tool 1000 comprises the visual cleaning bucket 100 and a flat mop 200, and the visual cleaning bucket 100 is used for washing the flat mop 200. The visible cleaning barrel 100 has a clean water chamber 101, a cleaning chamber 102, a sewage chamber 103 and a water inlet channel 104, wherein the clean water chamber 102 can be connected to the cleaning chamber 102, and the sewage chamber 103 and the cleaning chamber 102 are independent. Clear water in the clear water cavity 103 can enter the cleaning cavity 102, the flat mop 200 can be placed in the cleaning cavity 102 for cleaning, and sewage absorbed by the flat mop 200 can be scraped into the sewage cavity 103 in the cleaning process. The water inlet passage 104 is formed at a lower portion of the visible cleaning barrel 100, and the water inlet passage 104 may be communicated with the clean water chamber 101 and the washing chamber 102. After the water inlet channel 104 is communicated with the clean water cavity 101 and the cleaning cavity 102, the clean water stored in the clean water cavity automatically enters the cleaning cavity 102.

Specifically, the visible cleaning bucket 100 includes a cleaning bucket 10 and a water inlet control mechanism 20, the water inlet control mechanism 20 is disposed on the cleaning bucket 10, the water inlet control mechanism 20 allows the cleaning bucket 10 to be switched between a flow-through state and a closed state, the water inlet channel 104 of the cleaning bucket 10 in the flow-through state is opened, and the water inlet channel 104 communicates the clean water chamber 101 and the cleaning chamber 102. The water inlet channel 104 of the cleaning barrel 10 in the closed state is closed, the clean water chamber 101 and the cleaning chamber 102 are blocked, and the clean water in the clean water chamber 101 cannot flow into the cleaning chamber 102.

In this specific embodiment of the visible cleaning barrel 100 of the present invention, the visible cleaning barrel 100 further comprises a visible window 30, wherein the visible window 30 is disposed on the cleaning barrel 10, and the water amount in the cleaning barrel 10 can be observed through the transparent visible window 30.

In an embodiment of the present invention, the window 30 includes at least one transparent cleaning window 31, wherein the transparent cleaning window 31 corresponds to the cleaning cavity 102 of the cleaning barrel 10, and the amount of water in the cleaning cavity 102 can be observed through the cleaning window 31, so as to prevent the amount of water in the cleaning cavity 102 from being too much or too little. Preferably, the cleaning visible window 31 extends from a lower edge of the cleaning tub 10 to an upper edge of the cleaning tub 10.

In an embodiment of the present invention, the visual window 30 includes a transparent clear water visual window 32, wherein the transparent clear water visual window 32 corresponds to the clear water cavity 102 of the cleaning barrel 10, and the amount of the clear water in the clear water cavity 101 can be observed through the clear water visual window 32, so that the user can replenish the clear water into the clear water cavity 101 in time. Preferably, the fresh water visible window 32 extends from the lower edge of the cleaning bucket 10 to the upper edge of the cleaning bucket 10.

In an embodiment of the present invention, the visual window 30 includes a transparent sewage visual window 33, wherein the transparent sewage visual window 32 corresponds to the sewage cavity 103 of the cleaning barrel 10, and the amount of water in the sewage cavity 103 can be observed through the sewage visual window 33, so that a user can pour the sewage in the sewage cavity 103 in time. Preferably, the dirty water visible window 33 extends from a lower edge of the cleaning bucket 10 to an upper edge of the cleaning bucket 10.

Preferably, the cleaning visible window 31, the clear water visible window 32 and the sewage visible window 33 are integrally formed, that is, the clear water visible window 32 is connected with the cleaning visible window 31 and the sewage visible window 33, and the visible window 30 is of an integrated structure. For example, the sidewall of the cleaning bucket 10 is made of a transparent material, and the water amounts in the cleaning cavity 102, the clean water cavity 101 and the sewage cavity 103 can be clearly observed through the transparent sidewall of the cleaning bucket 10, that is, the sidewall of the cleaning bucket 10 serves as the visible window 30.

Preferably, the cleaning view window 31, the clean water view window 32 and the sewage view window 33 are arranged at intervals, that is, the cleaning view window 31, the clean water view window 32 and the sewage view window 33 are independent from each other.

In this embodiment of the present invention, the visual cleaning barrel 100 further comprises at least one set of scales 40, wherein the scales 40 are disposed on the cleaning barrel 10, at least one set of scales 40 corresponds to the water level in the cleaning cavity 102, and the water level scales in the cleaning cavity 102 can be observed through the cleaning visual window 31, so as to accurately control the water inflow into the cleaning cavity 102. For example, the scale corresponding to the water level in the cleaning chamber 102 can mark words such as "standard water level" and "highest water level", and the user can control the water level entering the cleaning chamber 102 between the "standard water level" and the "highest water level", so as to ensure that the flat mop 200 can be sufficiently cleaned and prevent the water in the cleaning chamber 102 from overflowing after the flat mop 200 is put into the cleaning chamber 102.

Preferably, at least one group of scales 40 corresponds to the water level in the sewage cavity 103, and the water level scales in the sewage cavity 103 can be observed through the sewage visual window 33, so that the problem that the use area is polluted due to the overflow of the sewage in the sewage cavity 103 due to too high water level is avoided.

Preferably, at least one set of the scales 40 corresponds to the water level in the clean water cavity 101, the water level scales in the clean water cavity 101 can be observed through the clean water visible window 32, the height of the water level in the clean water cavity 101 can be conveniently mastered, and when the water level in the clean water cavity 101 is low, a proper amount of clean water can be timely supplemented.

It is worth mentioning that the scale is arranged on the cleaning barrel 10, so that the user can clearly control the water volume in the clean water cavity 101, the cleaning cavity 102 and the sewage cavity 103, the overflow caused by the overhigh water level is avoided, and the phenomenon of dumping caused by the serious unbalance of the water volume distribution in the cleaning barrel 10 is avoided.

In this specific embodiment of the visual cleaning bucket 100 of the present invention, the cleaning bucket 10 includes a bucket body 11 and a cleaning device 12, the cleaning device 12 has a water filling opening 1201, a cleaning opening 1202 and a sewage opening 1203, wherein the water filling opening 1201, the cleaning opening 1202 and the sewage opening 1203 are arranged at a distance from each other, and the cleaning opening 1202 is located between the water filling opening 1201 and the sewage opening 1203. Clear water chamber 101 wash chamber 102 dirty water chamber 103 and inhalant canal 104 form in bucket body 11, just wash chamber 102 and be located dirty water chamber 103 with between the clear water chamber 101. The cleaning device 12 is installed above the tub body 11 such that the filler 1201, the cleaning port 1202, and the sewage port 1203 correspond to the clean water chamber 101, the wash chamber 102, and the sewage chamber 103 of the tub body 11, respectively.

The barrel body 11 comprises a container body 111, a water inlet partition 112 and a sewage partition 113, wherein the container body 111 has a container space 1101, the water inlet partition 112 and the sewage partition 113 are arranged at intervals in the container body 111 the container space 1101, the inner wall of the container body 111 and the water inlet partition 112 form the clean water chamber 101, the inner wall of the container body 111, the water inlet partition 112 and the sewage partition 113 form the cleaning chamber 102, and the inner wall of the container body 111 and the sewage partition 113 form the sewage chamber 103. The inlet passage 104 is formed in the inlet baffle 112. The cleaning device 12 is installed above the container body 111 such that the filler 1201, the cleaning port 1202, and the sewage port 1203 correspond to the clean water chamber 101, the wash chamber 102, and the sewage chamber 103, respectively.

The clear water view window 32, the cleaning view window 31 and the sewage view window 33 of the view window 30 are disposed on the container main body 111 of the tub body 11. For example, the sidewall of the container body 111 is made of a transparent material, and the viewing window 30 is formed on the sidewall of the container body 111. Or, the lateral wall of splendid attire main part 111 is equipped with an assembly mouth respectively, the area of assembly mouth covers clear water chamber 101 clean chamber 102 and sewage chamber 103, clear water visual window 32 clean visual window 31 and sewage visual window 33 integrated into one piece, integrated into one piece visual window 30 through technologies such as hot pressing, gluing set up in splendid attire main part 111 the assembly mouth, just visual window 30 seals the assembly mouth. Or, the lateral wall of splendid attire main part 111 is equipped with three mutual spaced the fitting up mouth, it is three the fitting up mouth corresponds to respectively clear water chamber 101 clean chamber 102 and sewage chamber 103, mutually independent clear water visual window 32 clean visual window 31 and sewage visual window 33 is set up in three respectively through technologies such as hot pressing, gluing the fitting up mouth, and seals the fitting up mouth.

The scale 40 is disposed on the outer surface or the inner surface of the container main body 111 of the tub body 11. Preferably, the scale 40 is disposed on an inner surface of the containing body 111, and the scale 40 corresponds to the visible window 30. Preferably, the scale 40 is disposed on the visible window 30. Preferably, the scale 40 is disposed on the outer surface of the tub body 11, and the scale 40 is located at one side of the viewing window 3. Optionally, the scales 40 are disposed on the water inlet partition 112 and the sewage partition 113, and the corresponding scales 40 can be seen through the cleaning view window 31 and the sewage view window 33.

The mop 200 includes a mop body 210 and a holding bar 220, wherein the mop body 210 includes a mop plate 211 and a cleaning element 212, wherein the cleaning element 212 has a cleaning surface 2120. The cleaning element 212 is mounted on the carriage 211 with the cleaning surface 2120 facing outward. The mop plate 211 of the mop body 210 is mounted on the bottom of the grip lever 220, and the mop 200 cleans a working area such as a floor or window glass by attaching the cleaning surface 2120 to the working area.

The water filling port 1201 is communicated with the clean water cavity 101, so that a user can replenish clean water from the water filling port 1201 to the clean water cavity 101 without disassembling the cleaning device 12, and the operation is convenient. The cleaning port 1202 is communicated with the cleaning chamber 102, and the mop 200 moves from top to bottom in such a manner that the cleaning surface 2120 of the mop body 210 faces the sewage port 1203, enters the cleaning chamber 102 from the cleaning port 1202, soaks in the cleaning chamber 102, and decontaminates. The sewage port 1203 is communicated with the sewage chamber 103, the soaked mops 200 move from bottom to top and then from top to bottom, and water absorbed by the mops 200 flows into the sewage chamber 103 from the sewage port 1203 under the action of the cleaning device 12.

Specifically, the cleaning device 12 includes a water feeding part 121, a cleaning part 122, and a water draining part 123, wherein the water feeding part 121, the cleaning part 122, and the water draining part 123 are integrally formed. The water inlet 1201, the cleaning port 1202, and the sewage port 1203 are formed in the water inlet 121, the cleaning part 122, and the dewatering part 123, respectively.

The cleaning portion 122 includes a holding portion 1221 and a scraping portion 1222 opposite to the holding portion 1221, wherein the scraping portion 1222 and the holding portion 1221 are integrally formed, and the scraping portion 1222 connects the holding portion 1221 and the dewatering portion 123. The cleaning port 1202 is formed between the holding portion 1221 and the scraping portion 1222, and the mop 200 can enter the cleaning chamber 102 from the cleaning port 1202 by the cleaning surface 2120 of the mop body 210 facing the scraping portion 1222. And, in the process that the mop 200 enters the cleaning cavity 102, the dirt scraping part 1222 of the cleaning part 122 presses the mop 200, and the dirt scraping part 1222 can scrape off the dirt attached to the cleaning surface 2120 of the mop 200.

Preferably, the cleaning opening 1202 of the cleaning portion 122 is shaped like a "letter" to guide a user to insert the mop 200 into the cleaning cavity 102 with the cleaning surface 2120 facing the scraping portion 1222. Specifically, the holder 1221 includes two carriage holders 12211 and a rod holder 12212, the rod holder 12212 is located between the two carriage holders 12211, the two holder 12211 extends outward from the rod holder 12212, and the cleaning opening 1202 is formed in a shape of a letter "convex" between the two carriage holders, the rod holder 12212, and the dirt scraping portion 1222.

Further, the dirt scraping portion 1222 is located between the cleaning opening 1202 and the sewage opening 1203. The dewatering part 123 includes a drainage part 1231 and a maintaining part 1232, wherein the drainage part 1231 and the maintaining part 1232 are integrally formed, and the sewage port 1203 is formed between the drainage part 1231 and the maintaining part 1232. The drainage portion 1231 is located between the scraping portion 1222 and the maintaining portion 1232 of the cleaning portion 122, and the drainage portion 1231 extends from the scraping portion 1222 to the maintaining portion 1232.

Further, the upper surface of the dewatering part 123 is an inclined downward slope, and the inclined upper surface of the dewatering part 123 extends from the dirt scraping part 1222 of the cleaning part 122 to the edge of the sewage port 1203. After the dirt scraping portion 1222 of the cleaning portion 122 scrapes the dirt and the sewage from the mop 200, the scraped sewage and the dirt are guided to flow from the inclined surface of the dewatering portion 123 to the sewage inlet 1203 of the dewatering portion 123, and enter the sewage chamber 103 of the cleaning bucket 10 from the sewage inlet 1203. Preferably, the upper surface of the dewatering part 123 is a plane inclined downward. Optionally, the upper surface of the dewatering part 123 is a curved surface inclined downward.

Specifically, when the mop 200 enters the cleaning cavity 102 from the cleaning opening 1202 from the top to the bottom for the first time, the holding portion 1221 and the dirt scraping portion 1222 of the cleaning portion 122 press against the mop 200 and scrape off dirt and water from the mop 200, and the scraped-off dirt and water flows to the dirt cavity 103 along the inclined surface of the dewatering portion 123. The sewage cavity 103 and the cleaning cavity 102 are independent from each other, so that the dirt and sewage of the mop main body 210 of the mop 200 are scraped once before the mop main body 210 is contacted with the clean water in the cleaning cavity 102 for the first time, the cleaning efficiency is improved, the pollution degree of the clean water is reduced, and the water is saved.

Further, after the mop body 210 of the mop 200 enters the cleaning cavity 102, water in the cleaning cavity 102 is absorbed, and the mop 200 in the cleaning cavity 102 is moved from bottom to top to the bottom of the mop body 210 of the mop 200 close to the cleaning opening 1202. Then, the mop 200 is moved from the top to the bottom, the holding part 1221 of the cleaning part 122 and the dirt scraping part 1222 press the mop body 210 of the mop 200 again, and the dirt scraping part 1222 scrapes off the water and the dirt adsorbed to the mop body 210 while the mop body 210 moves downward, and the scraped water and the dirt flow to the water removing opening 123 along the inclined surface of the water removing part 123 and are accumulated in the dirt chamber 103.

Preferably, the cleaning barrel 10 further comprises a dirt filtering device 13, wherein the dirt filtering device 13 has a dirt inlet 1301, a dirt containing space 1302 and a filtering opening 1303, wherein the dirt containing space 1302 communicates with the dirt inlet 1301 and the filtering opening 1303, and the dirt filtering device 13 is held below the dirt scraping portion 1222 of the cleaning portion 122 of the cleaning device 12. The dirt inlet 1301 and the filter opening 1303 of the dirt filter 13 are respectively communicated with the cleaning chamber 102 and the sewage chamber 103. In the process that the mop main body 210 of the mop 200 enters the cleaning cavity 102, the dirt filtering device 13 presses and scrapes the cleaning surface 2120 of the mop 200, the sewage and the impurities adsorbed by the cleaning surface 2120 are scraped off by the dirt filtering device 13 and enter the object containing space 1302 through the dirt inlet 1301, the sewage enters the sewage cavity 103 through the filtering opening 1303, and the impurities are retained in the object containing space 1302 after being blocked.

Specifically, the dirt filtering device 13 includes a dirt rubbing plate 131, a dirt accommodating box 132, and a filter 133, wherein the dirt rubbing plate 131 and the filter 133 are respectively disposed on the dirt accommodating box 132, the filter 133 is retained in the filtering opening 1303, and the dirt inlet 1301 and the dirt accommodating space 1302 are formed between the dirt rubbing plate 131 and the dirt accommodating box 132. The dirt scraping plate 131 is held below the dirt scraping portion 1222 of the cleaning portion 122 in a forward protruding manner at an interval such that the dirt inlet 1301 is communicated with the cleaning opening 1202, and the dirt filtering device 13 is held above the dirt partition 113. Preferably, the dirt scraping plate is obliquely disposed to the dirt accommodating case 132.

When the mop main body 210 of the mop 200 enters the cleaning cavity 102 from the cleaning port 1202 from top to bottom, the smearing plate 131 can press the cleaning surface 2120 of the mop main body 210, scrape off the sewage and the sundries adsorbed by the cleaning surface 2120, the scraped sewage and the scraped sundries enter the accommodating space 1302 from the sewage inlet 1301, the filter element 133 filters the sewage and the sundries in the dirt accommodating box 132, the filtered sewage and the filtered sundries flow into the sewage cavity 103 from the filtering port 1303, and the sundries with larger volume are retained in the accommodating space 1302. For example, but not limiting of, the filter 133 is implemented as a filter screen or the like.

Preferably, the dirt filtering device 13 is detachably mounted below the cleaning device 12, so that a user can conveniently remove the impurities in the accommodating space 1302 by detaching the dirt filtering device 13. In a particular embodiment of the invention, the dirt filter means 13 is mounted to the cleaning means 12 in a drawable manner. For example, the cleaning device 12 is provided with two slide rails, the dirt accommodating box 132 of the dirt filtering device 13 is provided with slide grooves corresponding to the slide rails, and the dirt accommodating box 132 is detachably mounted to the cleaning device 12 in such a manner that the slide grooves correspond to the slide rails. Optionally, the dirt filter arrangement 13 is removably mounted to the cleaning arrangement 12 by means of a snap fit. Optionally, the dirt filter 13 is detachably mounted to the cleaning device 12 by means of a screw connection. Optionally, the dirt filter 13 and the cleaning device 12 are integrally formed. It should be understood by those skilled in the art that the specific embodiment of the dirt container 13 disposed on the cleaning device 12 is merely an example and should not be construed as limiting the content and scope of the visual cleaning bucket 100 of the present invention.

The cleaning tub 10 further includes a holder 14, wherein the holder 14 is rotatably installed at an upper portion of the tub main body 11, and a user can move the visible cleaning tub 100 by holding the holder 14.

The cleaning bucket 10 further comprises a drainage valve 15, the bucket body 11 further has a drainage outlet 105, wherein the drainage outlet 105 is formed at the lower part of the container body 111, the drainage outlet 105 can be communicated with the sewage chamber 103, the drainage valve 15 is installed at the drainage outlet 105, and the drainage valve 15 can open the drainage outlet 105 or close the drainage outlet 105. When the drainage port 105 is opened, the sewage in the sewage chamber 103 can be automatically drained out of the barrel without the user pouring the sewage by dumping the cleaning barrel 10.

It is worth mentioning that, the user can pass through wash visual window 31 and observe wash the water yield in the chamber 102, and through the operation visual clean bucket 100 water inlet control mechanism 20, control certainly get into in the clear water chamber 101 wash the water yield in the chamber 102, observe simultaneously the water level in the clear water chamber 102 corresponds scale 40, the accurate grasp water level height in the chamber 102 washs.

Referring to fig. 1 to 23, in some embodiments of the present invention, the water inlet control mechanism 20 of the visual cleaning barrel 100 controls the amount of water entering the clean water chamber 102 from the clean water chamber 101 by manual operation.

Specifically, the water inlet control mechanism 20 includes a manual operation element 201 and a limiting element 202, wherein the manual operation element 201 has a flow passage 20131, and the limiting element 202 has a longitudinal assembly cavity 2021 and a transverse flow passage 2022 communicating with the longitudinal assembly cavity 2021. The manual operation element 201 is movably installed in the longitudinal assembly cavity 2021 of the limiting element 202, and when the flow channel 20131 of the manual operation element 201 corresponds to the transverse flow channel 2022 of the limiting element 202, the flow channel 20131 of the manual operation element 201, the transverse flow channel 2022 of the limiting element 202, the water inlet channel 104, the clean water cavity 101 and the cleaning cavity 102 are communicated with each other. The clean water in the clean water chamber 101 sequentially flows into the cleaning chamber 102 through the water inlet passage 104, the flow passage 20131 of the manual operation element 201, and the transverse flow passage 2022 of the limiting element 202.

Referring to fig. 1 to 19, in an embodiment of the present invention, the manual operating device 201 includes an operating element 2011, an extension rod 2012 and a movable valve 2013, the operating element 2011 and the movable valve 2013 are respectively disposed at an upper end and a lower end of the extension rod 2012, and the flow channel 20131 is formed in the movable valve 2013. The cleaning portion 122 of the cleaning device 12 has a holding hole 12201, and the operating element 2011 is held above the cleaning device 12 in such a manner that the extension bar 2012 is rotatably mounted to the holding hole 12201 of the cleaning device 12. The retaining member 202 is disposed on the water inlet partition 112 in such a manner that the transverse flow passage 2022 can be communicated with the water inlet passage 104, and the movable valve 2013 is rotatably mounted on the longitudinal assembling cavity 2021 of the retaining member 202. The movable valve 2013 is rotatably retained in the longitudinal cavity 2021 of the retaining member 202 in such a manner that an outer surface of the movable valve fits against an inner surface of the retaining member 202. When the operating element 2011 is rotated by hand, the movable valve 2013 is rotated to the position where the flow channel 20131 corresponds to the transverse flow channel 2022 of the limiting member 202, the cleaning bucket 10 is in the flow state, and the water in the clean water chamber 101 automatically flows into the cleaning chamber 102.

The change of the water level entering the cleaning chamber 102 can be observed at any time through the cleaning window 31, and when the water level in the cleaning chamber 102 reaches a suitable height, the operating element 2100 is rotated again, so that the movable valve 2013 rotates relative to the limiting member 202 until the flow channel 20131 of the movable valve 2013 and the transverse flow channel 2022 of the limiting member 201 are staggered with each other, and the outer surface of the movable valve 2013 closes the transverse flow channel 2022 of the limiting member 202. The cleaning bucket 10 is switched from the circulation state to the closed state, and the water in the clean water chamber 101 stops flowing into the cleaning chamber 102.

Referring to fig. 20 and 21, in another specific embodiment of the present invention, the inlet control mechanism 20 further comprises an elastic member 203, wherein the elastic member 203 is retained in the longitudinal assembly cavity 2021 of the retaining member 202. The operating element 2011 is held above the cleaning device 12 in such a manner that the extension bar 2012 is vertically movably attached to the holding hole 12201 of the cleaning device 12. The movable valve 2013 is vertically movably held in the longitudinal assembling cavity 2021 of the stopper 202 in such a manner that an outer surface of the movable valve 2013 is attached to an inner surface of the stopper 202, the movable valve 2013 is disposed above the elastic member 203, the flow passage 20131 of the movable valve 2013 and the transverse flow passage 2022 of the stopper 202 are disposed in a staggered manner, and a lower portion of the movable valve 2013 blocks the transverse flow passage 2022 of the stopper 202.

When the operating element 2011 is pressed downwards by hand, the movable valve 2013 moves downwards relative to the limiting piece 202, the elastic piece 203 is squeezed, when the flow channel 20131 of the movable valve 2013 corresponds to the transverse flow channel 2022 of the limiting piece 202, the cleaning barrel 10 is in the flow state, and the water in the clean water cavity 101 automatically flows into the cleaning cavity 102. The change of the water level entering the cleaning cavity 102 can be observed at any time through the cleaning visible window 31, when the water level in the cleaning cavity 102 reaches a proper height, the hand is released, the acting force on the operating element 2011 is cancelled, the elastic member 203 releases elastic potential energy, the movable valve 2013 is pushed to move upwards to an initial position, the flow channel 20131 of the movable valve 2013 and the transverse flow channel 2022 of the limiting member 202 are arranged in a staggered mode, and the lower portion of the movable valve 2013 shields the transverse flow channel 2022 of the limiting member 202. In this manner, the cleaning bucket 10 is switched from the circulation state to the closed state.

Referring to fig. 22 and 23, the inlet control mechanism 20 includes a manual wireless switch 204 and a manual solenoid valve 205, wherein the manual solenoid valve 205 has a fluid passage 2051, wherein the manual wireless switch 204 is communicably connected to the manual solenoid valve 205, and the manual solenoid valve 205 is disposed in the inlet passage 104 in such a manner that the fluid passage 2051 can communicate with the clean water chamber 101 and the cleaning chamber 102. The fluid passage 2051 of the manual solenoid valve 205 can be controlled to open or close by manually operating the manual wireless switch 204, thereby allowing the cleaning bucket 10 to be switched between the circulation state and the closed state.

Specifically, the manual wireless switch 204 is movably installed on the cleaning barrel 10, the manual wireless switch 204 is pressed by a hand, the manual wireless switch 204 sends a control signal for controlling the manual electromagnetic valve 205, the manual electromagnetic valve 205 receives the control signal and then opens the fluid passage 2051, and the clean water in the clean water chamber 101 automatically flows into the cleaning chamber 102. Through clean visual window 31 can observe the entering constantly water level change in the clean chamber 102, when observing after the water level in the clean chamber 102 reaches suitable height, press again manual wireless switch 204, manual wireless switch 204 sends control manual solenoid valve 205 the control signal, manual solenoid valve 205 receives close behind the control signal fluid passage 2051. In this way, the cleaning bucket 10 is switched between the circulation state and the closed state.

Preferably, the manual wireless switch 204 is mounted above the cleaning device 12 for easy operation by the user. Optionally, the manual wireless switch 204 is mounted to the tub body 11. For example, the manual wireless switch 204 is attached to one side of the visual cleaning window 31, the manual wireless switch 204 is close to the visual cleaning window 31, and the user can press the manual wireless switch 204 on one side of the visual cleaning window 31 after observing the water level in the cleaning chamber 102 through the visual cleaning window 31.

In a specific embodiment of the present invention, the water inlet control mechanism 20 allows the cleaning bucket 10 to be switched between the circulation state and the closed state by means of foot driving. Specifically, referring to fig. 24 and 25, the water inlet control mechanism 20 includes a foot-operated wireless switch 206 and a foot-operated solenoid valve 207, wherein the foot-operated solenoid valve 207 has a water flow passage 2071, wherein the foot-operated wireless switch 206 is communicably connected to the foot-operated solenoid valve 207, and the foot-operated solenoid valve 207 is disposed at the water inlet passage 104 in such a manner that the water flow passage 2071 can communicate with the clean water chamber 101 and the clean chamber 102. The water flow passage 2071 of the foot-controlled solenoid valve 207 can be controlled to be opened or closed by stepping on the foot-operated wireless switch 206, thereby allowing the cleaning bucket 10 to be switched between the circulating state and the closed state.

Further, the pedal-type wireless switch 206 is movably installed at one side of the bottom of the cleaning bucket 10, the pedal-type wireless switch 206 is stepped on by a foot, the pedal-type wireless switch 206 sends a control signal for controlling the pedal-type electromagnetic valve 207, the pedal-type electromagnetic valve 207 opens the water flow channel 2071 after receiving the control signal, and the clean water in the clean water cavity 101 automatically flows into the cleaning cavity 102. The water level change entering the cleaning cavity 102 can be observed constantly through the cleaning visible window 31, when the water level in the cleaning cavity 102 reaches a proper height, the pedal-type wireless switch 206 is stepped again, the pedal-type wireless switch 206 sends out the control signal for controlling the foot-controlled electromagnetic valve 207, and the water flow channel 2071 is closed after the foot-controlled electromagnetic valve 207 receives the control signal. In this way, the user can switch the cleaning bucket 10 between the circulation state and the closed state without bending down.

It should be noted that the water inlet control mechanism 20 may also be implemented as a mechanical structure driven by a foot pedal, and the water inlet control mechanism 20 moves relative to the cleaning barrel 10 in a mechanical linkage manner, so as to switch the cleaning barrel 10 between the circulating state and the closed state.

In a specific embodiment of the present invention, when the automatic cleaning bucket 100 receives the flat mop 200, the water inlet passage 104 is automatically opened and the cleaning chamber 102 and the clean water chamber 101 are communicated with each other, and the clean water stored in the clean water chamber 101 can automatically flow from the clean water chamber 101 into the cleaning chamber 102 without a user's stooping operation.

Specifically, the water inlet control mechanism 20 of the visual cleaning barrel 100 comprises an electrically controlled water inlet valve 21, a control element 22 and a detection element 23, wherein the electrically controlled water inlet valve 21 is disposed on the water inlet channel 104 of the barrel body 11, the electrically controlled water inlet valve 21 is connected to the control element 22 in a driving manner, and the control element 22 can drive the electrically controlled water inlet valve 21 to switch between the open state and the closed state. The control unit 22 is communicatively connected to the detection unit 23, the detection unit 23 detects whether the mop 200 enters the washing cavity 102 of the cleaning bucket 10 in real time, and sends a control command to the control unit 23 when the detection unit 23 detects that the mop 200 enters the washing cavity 102 of the cleaning bucket 20, and the control unit 23 controls the electrically-controlled water inlet valve 21 to be switched to the open state when executing the control command. When the electrically controlled water inlet valve 21 is in the open state, the water inlet channel 104 of the cleaning barrel 100 is communicated with the clean water cavity 101, the clean water contained in the clean water cavity 101 has a higher water level, and the clean water in the clean water cavity 101 automatically flows into the cleaning cavity 102.

In a specific embodiment of the present invention, the detecting member 23 is installed at the cleaning device 12 of the cleaning bucket 10, and the detecting member 23 is close to the cleaning port 1202, and the control member 23 drives the electrically controlled water inlet valve 21 to open when the mop body 210 of the mop 200 passes through the cleaning port 1202.

Preferably, the detecting member 23 is disposed above the cleaning part 122 of the cleaning device 12, the detecting member 23 is located above the cleaning opening 1202, and the detecting member 23 can detect the mop 200 immediately when the mop 200 approaches the upper surface of the cleaning tub 100. Alternatively, the detection element 23 is installed below the cleaning portion 122.

Optionally, the detection element 23 is arranged below the cleaning device 12. For example, but not limited to, the sensing element 23 is mounted on the back of the cleaning device 12, the sensing element 23 is mounted on the inlet partition 112, and the sensing element 23 is mounted on the waste partition 113. It should be understood by those skilled in the art that the specific installation location of the detecting element 23 is only an example and is not intended to limit the content and scope of the visual cleaning barrel 100 of the present invention.

Preferably, the detecting element 23 is installed on the maintaining portion 1222 of the cleaning portion 122 to emit a detecting beam toward the dirt scraping portion 1221 and receive a reflected beam reflected by the detecting beam, when the mop body 210 of the mop 200 passes by the detecting element 23, the mop body 210 blocks the detecting beam, the reflected beam received by the detecting element 23 changes, the detecting element 23 determines that the mop 200 enters the cleaning cavity 102 of the cleaning bucket 10, and then sends the control command to the control element 23, and the control element 23, when executing the control command, drives the electrically controlled water inlet valve 21 to open, so that the clean water in the clean water cavity 101 can automatically flow into the cleaning cavity 102. The detection element 23 may be attached to the carriage maintaining part 12221 and/or the rod maintaining part 12222 of the maintaining part 1222. Alternatively, the detection element 23 emits the detection beam toward the maintenance part 1222 in such a manner as to be attached to the dirt scraping part 1221 of the cleaning part 122.

It should be noted that the embodiment of the detecting element 23 is not limited, and the detecting element may be implemented as one or more of a laser sensor, a microwave detector or a detecting device known to those skilled in the art, and the embodiment of the detecting element 23 is only an example and cannot be a limitation to the content and scope of the visual cleaning barrel 100 of the present invention.

Referring to fig. 26A, in a specific embodiment of the present invention, the electrically controlled inlet valve 21 of the inlet control mechanism 20 and the control element 22 are integrated, for example, the inlet control mechanism 20 is implemented as a solenoid valve, when the detecting element 23 detects that the mop 200 enters the cleaning chamber 102, the solenoid valve is opened, the clean water chamber 101 is communicated with the cleaning chamber 102, and the clean water in the clean water chamber 101 automatically flows into the cleaning chamber 102. Referring to fig. 26B and 27, in an embodiment of the present invention, the electrically controlled water inlet valve 21 and the control element 22 of the water inlet control mechanism 20 are of a split structure, for example, the control element 22 is implemented as an electric telescopic rod, the electrically controlled water inlet valve 21 is a water blocking plug, the water blocking plug is mounted at an end of the electric telescopic rod, and the electric telescopic rod is extended or retracted according to a detection result of the detection element 23, so that the water blocking plug blocks the water inlet channel 104, or allows the clean water cavity 101 and the clean water cavity 102 to communicate.

Preferably, when the mop body 210 blocks the detection element 23, the water inlet control mechanism 20 allows water to flow from the clean water chamber 101 to the cleaning chamber 102, and when the mop body 210 fails to block the detection element 23, the water inlet control mechanism 20 blocks the communication between the clean water chamber 101 and the cleaning chamber 102. The change of the water level entering the cleaning cavity 102 can be observed at any time through the cleaning visible window 31, and when the water level in the cleaning cavity 102 is observed to reach a proper height, the mop main body 210 is moved to not block the detection element 23. The cleaning bucket 10 is switched from the circulation state to the closed state, and the water in the clean water chamber 101 stops flowing into the cleaning chamber 102.

Preferably, the control element 22 of the inlet control mechanism 20 is preset with an operating rule to accurately control the amount of water in the wash chamber 102. For example, when the detecting element 23 detects that the mop body 210 enters the cleaning cavity 102, the control element 22 drives the electrically controlled water inlet valve 21 to open, and after the control element 22 keeps the electrically controlled water inlet valve 21 in the open state for a predetermined time, the control element 22 automatically controls the electrically controlled water inlet valve 21 to close, so as to avoid that water in the cleaning cavity is excessive, and therefore, when the mop is cleaned, water in the cleaning cavity overflows to pollute the use environment. Or, the control element 22 only allows the passage for communicating the clean water chamber 101 and the cleaning chamber 102 to be opened once within a preset time period, so as to prevent the clean water chamber and the cleaning chamber from being frequently communicated when the user repeatedly moves the mop 200 up and down, thereby preventing the mop from being incapable of being dewatered. It should be understood by those skilled in the art that the specific embodiment of the operation rule of the control element 20 is only an example and is not intended to limit the content and scope of the visual cleaning bucket 100 of the present invention.

Referring to fig. 28 and 29, in one embodiment of the present invention, the inlet control mechanism 20 is controlled by mechanical control to allow the inlet passage 104 to be opened or closed. Specifically, the water inlet control mechanism 20 is movably held in the cleaning chamber 102, when the mop body 210 of the mop 200 enters the cleaning chamber 102 from the cleaning opening 1202, the mop body 210 can drive the water inlet control mechanism 20 to move relative to the containing body 111, and the water inlet passage 104 connecting the clean water chamber 101 and the cleaning chamber 102 is opened, so that the clean water in the clean water chamber 101 can automatically flow into the cleaning chamber 102.

More specifically, the water inlet control mechanism 20 includes a trigger 24, an elastic restoring member 25, a linking member 26, a retaining member 27, an extending member 28 and a water-blocking plug 29, wherein the linking member 26 extends downward from the trigger 24, the trigger 24 is disposed at an upper end of the linking member 26, and a lower end of the trigger 24 is connected to the extending member 28. The linkage 26 is obliquely held in the cleaning cavity 102, the trigger 24 and the extension 28 are located at two sides of the linkage 26, and the trigger 24, the linkage 26 and the extension 28 form a "Z" structure. The water blocking plug 29 is fixed at the end of the extension member 28, the holding member 27 is fixed at the tub body 11, the middle of the linkage member 26 is rotatably mounted at the holding member 27, the elastic restoring member 25 is held between the trigger 24 and the water inlet partition 112 of the tub body 11, and the water blocking plug 29 is movably mounted at the water inlet passage 104.

When the mop body 210 of the mop 200 enters the cleaning cavity 102 from the cleaning opening 1202 in a manner of being attached to the trigger 24 of the water inlet control mechanism 20, the mop body 210 drives the trigger 24 to move backward, presses the elastic restoring member 25, and pushes the linkage 26 to rotate counterclockwise relative to the holder 27, and the extending member 28 and the water-blocking plug 29 disposed at the lower end of the linkage 26 are driven by the linkage 26 and move forward, away from the water inlet partition 112. After the water-blocking plug 29 leaves the water inlet channel 104, the water inlet channel 104 communicates the clean water chamber 101 and the cleaning chamber 102, and the clean water in the clean water chamber 101 automatically flows into the cleaning chamber 102.

After the force of the mop 200 on the trigger 24 of the water inlet control mechanism 20 is removed, the elastic potential energy accumulated by the elastic restoring member 25 is released, the elastic restoring member 25 drives the linkage 26 to rotate clockwise relative to the retainer 27, the trigger 24 restores to the initial position, the extending member 28 and the water separating plug 29 arranged at the lower end of the linkage 26 move backwards, approach the water inlet separating plate 112 and are retained in the water inlet channel 104, the clean water cavity 101 and the cleaning cavity 102 are blocked, and the clean water in the clean water cavity 101 cannot enter the cleaning cavity 102 any more.

Preferably, the width of the cleaning cavity 102 and the cleaning opening 1202 is greater than the width of the mop body 210 of the mop 200, and the water inlet control mechanism 20 is held within the cleaning cavity 102 with the trigger 24 near the end of the cleaning opening 1202 and allows the mop 200 to enter the cleaning cavity 102 from the cleaning opening 1202 without the mop body 210 contacting the trigger 24 and also allows the mop 200 to enter the cleaning cavity 102 from the cleaning opening 1202 with the mop body 210 abutting the trigger 24. Thus, when the mop 200 enters the washing chamber 102 with the trigger 24 abutting the trigger 24, the cleaning bucket 10 can be switched from the closed state to the circulation state, and when the mop 200 enters the washing chamber 102 with the mop body 210 not contacting the trigger 24, the cleaning bucket 10 still maintains the closed state. In this way, the user can control the amount of water in the washing chamber 102 according to the use requirement, and the frequent communication between the washing chamber 102 and the washing chamber 101 can be avoided, which results in the mop 200 being unable to be dewatered.

It will be appreciated by persons skilled in the art that the above embodiments are only examples, wherein features of different embodiments may be combined with each other to obtain embodiments which are easily conceivable in accordance with the disclosure of the invention, but which are not explicitly indicated in the drawings.

It will be appreciated by persons skilled in the art that the embodiments of the invention described above and shown in the drawings are given by way of example only and are not limiting of the invention. The objects of the invention have been fully and effectively accomplished. The functional and structural principles of the present invention have been shown and described in the examples, and any variations or modifications of the embodiments of the present invention may be made without departing from the principles.

Claims (41)

1. A cleaning bucket for cleaning a mop, comprising:

a cleaning bucket, wherein the cleaning bucket comprises a bucket body and a cleaning device, wherein the bucket body is provided with a clean water cavity, a cleaning cavity, a sewage cavity and a water inlet channel which can be communicated with the clean water cavity and the cleaning cavity, the water inlet channel is formed at the lower part of the bucket body, wherein the cleaning device is provided with a water filling opening, a cleaning opening and a sewage opening, and the cleaning device is kept above the cleaning bucket in a way that the water filling opening, the cleaning opening and the sewage opening respectively correspond to the clean water cavity, the cleaning cavity and the sewage cavity; and

a water inlet control mechanism, wherein the water inlet control mechanism is arranged on the cleaning barrel, when the mop enters the cleaning cavity from the cleaning port, the water inlet control mechanism controls the cleaning barrel to be automatically switched from a closed state to a circulating state, the water inlet channel of the cleaning barrel in the circulating state is communicated with the clean water cavity and the cleaning cavity, and the clean water cavity and the cleaning cavity of the cleaning barrel in the closed state are blocked.

2. The cleaning bucket of claim 1, wherein the water inlet control mechanism includes an electrically controlled water inlet valve, a control element and a detection element, wherein the electrically controlled water inlet valve is communicatively connected to the control element, the control element is communicatively connected to the electrically controlled water inlet valve, the electrically controlled water inlet valve is disposed in the water inlet passage, the detection element is disposed in the cleaning device, and when the detection element detects that the mop enters the cleaning chamber, the control element controls the electrically controlled water inlet valve to open and enables the water inlet passage to communicate the clean water chamber and the cleaning chamber.

3. The cleaning bucket of claim 2 wherein the electrically controlled water inlet valve and the control element are integrated into a solenoid valve.

4. The cleaning bucket of claim 2, wherein the control element is implemented as an electrically telescopic rod, the electrically controlled water inlet valve being disposed at an end of the electrically telescopic rod, the control element moving the electrically controlled water inlet valve in an electrically telescopic manner to enable the cleaning bucket to be switched between the closed state and the flow-through state.

5. The cleaning bucket of claim 1, wherein the inlet control mechanism is movably retained in the washing chamber, and the mop is capable of driving the inlet control mechanism to move relative to the cleaning bucket and mechanically open or close the inlet passage.

6. The cleaning bucket defined in claim 5, wherein the cleaning bucket includes a container body, a water inlet partition and a water outlet partition, wherein the container body has a container space, wherein the water inlet partition and the waste water partition are spaced apart from each other in the container space of the container body, and the clean water chamber is formed between the container body and the water inlet partition, the clean water chamber is formed between the water inlet partition and the waste water partition, and the waste water is formed between the container body and the waste water partition, the water inlet passage is formed in the water inlet partition, and the water inlet control mechanism is movably disposed in the water inlet partition.

7. The cleaning bucket as claimed in claim 6, wherein the water inlet control mechanism includes a trigger, an elastic restoring member, a linking member, a retaining member, an extending member and a water-blocking plug, wherein the trigger and the extending member are respectively disposed at the upper end and the lower end of the linking member, the linking member is obliquely retained in the washing chamber, the trigger and the extending member are disposed at both sides of the linking member, the water-blocking plug is fixed at the end of the extending member, the retaining member is fixed at the container body, the middle of the linking member is rotatably mounted to the retaining member, the elastic restoring member is retained between the trigger and the water inlet partition, and the water-blocking plug is movably mounted to the water inlet passage.

8. The cleaning bucket of claim 7, wherein the cleaning cavity and the cleaning opening have a width greater than a width of the mop, the inlet control mechanism being retained in the cleaning cavity with the trigger proximate an end of the cleaning opening.

9. The cleaning bucket according to any one of claims 1 to 8, wherein the cleaning device includes a water supply portion, a cleaning portion, and a water discharge portion, wherein the water supply port, the cleaning port, and the sewage port are formed at the water supply portion, the cleaning portion, and the water discharge portion, respectively, the cleaning portion includes a holding portion and a dirt scraping portion opposite to the holding portion, the dirt scraping portion connects the holding portion and the water discharge portion, the dirt scraping portion and the water discharge portion are located between the cleaning port and the sewage port, and an upper surface of the water discharge portion is an inclined surface inclined downward.

10. The cleaning bucket of claim 9, wherein the cleaning opening of the cleaning bucket is "male" in shape.

11. The cleaning bucket according to claim 9, wherein the cleaning bucket further comprises a dirt filtering device, wherein the dirt filtering member has a dirt inlet, a dirt containing space and a filtering opening, wherein the dirt containing space is communicated with the dirt inlet and the filtering opening, the dirt filtering device is held below the dirt scraping portion of the cleaning device, and the dirt inlet and the filtering opening of the dirt filtering device are communicated with the washing chamber and the sewage chamber, respectively.

12. The cleaning bucket according to claim 11, wherein the dirt filtering device includes a dirt rubbing plate, a dirt accommodating case, and a filter member, wherein the dirt rubbing plate and the filter member are respectively disposed in the dirt accommodating case, the filter member is held in the filter opening, the dirt inlet and the content space are formed between the dirt rubbing plate and the dirt accommodating case, and the dirt rubbing plate is held at an interval below the dirt scraping portion of the cleaning portion in a forwardly protruding manner.

13. The cleaning bucket according to claim 12, wherein the dirt rubbing plate is obliquely disposed to the dirt containing box.

14. A cleaning bucket adapted for use in cleaning a mop, said cleaning bucket comprising:

a cleaning bucket, wherein the cleaning bucket comprises a containment device and a cleaning device, wherein the containment device has a clean water chamber, a clean chamber, and a dirty water chamber, wherein the cleaning device has a filler, a clean port, and a dirty water port, wherein the cleaning device is held above the cleaning bucket in such a manner that the filler, the clean port, and the dirty water port correspond to the clean water chamber, the clean chamber, and the dirty water chamber, respectively; and

and the sewage pump is provided with a sewage suction port and a sewage discharge port, and the sewage pump is arranged in the cleaning barrel in a mode that the sewage suction port and the sewage discharge port are respectively communicated with the cleaning cavity and the sewage cavity.

15. The cleaning bucket of claim 14, wherein the receptacle includes a receptacle body, a water inlet partition and a sewage partition, wherein the receptacle body has a receptacle space, wherein the water inlet partition and the sewage partition are spaced apart from each other in the receptacle space of the receptacle body, and form the clean water chamber between the receptacle body and the water inlet partition, the clean water chamber between the water inlet partition and the sewage partition, and the sewage chamber between the receptacle body and the sewage partition, the sewage partition having a fitting opening formed in a bottom of the sewage partition, the sewage pump being sealingly mounted to the fitting opening in such a manner that the sewage suction opening and the sewage discharge opening are communicated with the clean water chamber and the sewage discharge opening, respectively.

16. The cleaning bucket of claim 14, wherein the sewage pump includes a pump body, a sewage suction pipe and a sewage discharge pipe, wherein the sewage suction pipe and the sewage discharge pipe are respectively communicated with both ends of the pump body, the sewage suction port and the sewage discharge port are respectively formed in the sewage suction pipe and the sewage discharge pipe, the pump body is held at an upper portion of the cleaning bucket in such a manner that the sewage suction pipe and the sewage discharge pipe are respectively located in the washing chamber and the sewage chamber, and the sewage suction pipe extends from the pump body to a bottom of the cleaning chamber.

17. The cleaning bucket of claim 16, wherein the sump pump further includes a quick release mechanism, wherein the quick release mechanism includes a first quick release member and a second quick release member, wherein the first quick release member and the second quick release member are disposed on the cleaning bucket and the pump body, respectively, and the first quick release member is detachably mounted to the second quick release member, such that the sump pump is detachably mounted to the cleaning bucket.

18. The cleaning bucket of claim 17, wherein the first quick disconnect and the second quick disconnect are connected in a manner selected from the group consisting of: the type group is composed of threaded connection, buckle connection, clamping connection, magnetic connection and clearance fit connection.

19. The cleaning bucket according to any one of claims 14 to 18, further comprising at least one transparent cleaning window, wherein the cleaning window is disposed on the container and corresponds to the cleaning chamber, and water in the cleaning chamber is visible through the cleaning window.

20. The cleaning bucket according to any one of claims 14 to 18, further comprising a detection device, wherein the detection device is mounted to the cleaning bucket, the detection device is communicatively connected to the sewage pump, and the detection device controls the sewage pump to remain in an open state after the detection device detects that the mop in the cleaning cavity leaves the cleaning cavity.

21. The cleaning bucket according to any one of claims 14 to 18, further comprising a detection device and a water level detection device, wherein the detection device is mounted to the cleaning bucket, the water level detection device is retained in the cleaning chamber, the water level detection device is communicatively connected to the detection device and the sewage pump, and the sewage pump is switched to an on state when the detection device detects that the flat mop leaves the washing chamber and the water level detection device detects that sewage remains in the washing chamber.

22. The cleaning bucket according to any one of claims 14 to 18, further comprising a water inlet control mechanism, wherein the container has a water inlet passage, wherein the water inlet passage is formed at a lower portion of the container, wherein the water inlet control mechanism is movably disposed on the cleaning bucket, the water inlet control mechanism controls the cleaning bucket to switch between a flow-through state and a closed state, the water inlet passage of the cleaning bucket in the flow-through state communicates with the clean water chamber and the clean chamber, and the clean water chamber and the clean chamber of the cleaning bucket in the closed state are blocked.

23. The cleaning bucket according to any one of claims 14 to 18, wherein the water inlet control mechanism includes an operating member and a retaining member, the operating member includes an operating element, an extending rod and a movable valve, the retaining member has a longitudinal assembly cavity and a transverse flow passage communicating with the longitudinal assembly cavity, the operating element and the movable valve are respectively disposed at the upper end and the lower end of the extending rod, the movable valve has a flow passage, the cleaning device has a retaining hole, the retaining member is disposed at the container in such a manner that the transverse flow passage can be communicated with the water inlet passage, the operating element is retained above the cleaning device in such a manner that the extending rod is rotatably mounted at the retaining hole, and the movable valve is rotatably retained at the longitudinal assembly cavity of the retaining member.

24. A cleaning bucket, comprising:

a cleaning bucket, wherein the cleaning bucket comprises a bucket body and a cleaning device, wherein the bucket body is provided with a clean water cavity, a cleaning cavity and a sewage cavity, wherein the cleaning device is provided with a water filling opening, a cleaning opening and a sewage opening, and wherein the cleaning device is held above the cleaning bucket in a manner that the water filling opening, the cleaning opening and the sewage opening respectively correspond to the clean water cavity, the cleaning cavity and the sewage cavity; and

a visual window, wherein the visual window includes at least one transparent clean visual window, wherein the clean visual window is arranged on the barrel body, and the clean visual window corresponds to the cleaning cavity, and water in the cleaning cavity can be seen through the clean visual window.

25. The cleaning bucket of claim 24, wherein the viewing window includes at least one transparent clear water viewing window, wherein the clear water viewing window is disposed on the bucket body, and the clear water viewing window corresponds to the clear water chamber through which water in the clear water chamber can be viewed.

26. The cleaning bucket of claim 25, wherein the viewing window includes at least one transparent dirty water viewing window, wherein the dirty water viewing window is disposed on the bucket body and corresponds to the dirty water chamber through which water in the clean water chamber is visible.

27. The cleaning bucket of claim 26, wherein the cleaning view window integrally extends from the clear water view window to the dirty water view window.

28. The cleaning bucket of claim 26, wherein the cleaning view window, the fresh water view window and the contaminated water view window are disposed at the bucket body in a spaced relationship with each other.

29. The cleaning bucket of claim 27, further comprising at least one set of graduations, wherein at least one set of the graduations is disposed on the bucket body and corresponds to a water level within the cleaning cavity.

30. The cleaning bucket of claim 26, further comprising at least one set of graduations, wherein the at least one set of graduations is disposed on the bucket body and corresponds to a water level within the fresh water cavity.

31. The cleaning bucket of claim 26, further comprising at least one set of graduations, wherein the at least one set of graduations is disposed on the bucket body, and the graduations correspond to a water level within the waste water chamber.

32. The cleaning bucket according to any one of claims 24 to 31, further comprising a water inlet control mechanism, wherein the bucket body has a water inlet channel, wherein the water inlet channel is formed at a lower portion of the bucket body, wherein the water inlet control mechanism is movably disposed on the cleaning bucket, the water inlet control mechanism controls the cleaning bucket to switch between a flow-through state and a closed state, the water inlet channel of the cleaning bucket in the flow-through state communicates the clean water chamber and the clean chamber, and the clean water chamber and the clean chamber of the cleaning bucket in the closed state are blocked.

33. The cleaning bucket of claim 32, wherein the water inlet control mechanism includes a manual operating member and a limiting member, the manual operating member includes an operating element, an extension rod and a movable valve, the limiting member has a longitudinal assembly cavity and a transverse flow passage communicating with the longitudinal assembly cavity, the operating element and the movable valve are respectively disposed at the upper end and the lower end of the extension rod, the movable valve has a flow passage, the cleaning device has a retaining hole, the limiting member is disposed at the bucket body in such a manner that the transverse flow passage can be communicated with the water inlet passage, the operating element is rotatably mounted at the retaining hole above the cleaning device, and the movable valve is rotatably retained at the longitudinal assembly cavity of the limiting member.

34. The cleaning bucket of claim 32, wherein the water inlet control mechanism includes a manual operation member, a limiting member and an elastic member, the manual operation member includes an operation element, an extension rod and a movable valve, the limiting member has a longitudinal assembly cavity and a transverse flow passage communicating with the longitudinal assembly cavity, the operation element and the movable valve are respectively disposed at the upper end and the lower end of the extension rod, the movable valve has a flow passage, the cleaning device has a retaining hole, the limiting member is disposed at the bucket body in such a manner that the transverse flow passage can be communicated with the water inlet passage, the operation element is retained above the cleaning device in such a manner that the extension rod is movably mounted at the retaining hole up and down, and the movable valve is retained at the longitudinal assembly cavity of the limiting member in such a manner that the movable valve can move up and down, the elastic member is disposed below the movable valve.

35. The cleaning bucket of claim 32, wherein the inlet control mechanism includes a manual wireless switch and a manual solenoid valve, wherein the manual solenoid valve has a fluid passage, wherein the manual wireless switch is communicatively connected to the manual solenoid valve, the manual solenoid valve is disposed in the inlet passage in such a manner that the fluid passage can communicate with the fresh water chamber and the cleaning chamber, the manual wireless switch allows the manual solenoid valve to be manually controlled to switch between an open state and a closed state, and enables the cleaning bucket to switch between the flow-through state and the closed state.

36. The cleaning bucket of claim 32, wherein the water inlet control mechanism includes a foot-operated wireless switch and a foot-operated solenoid valve, wherein the foot-operated solenoid valve has a water flow passage, wherein the foot-operated wireless switch is communicatively connected to the foot-operated solenoid valve, the foot-operated solenoid valve is disposed at the water inlet passage in such a manner that the water flow passage can communicate with the fresh water chamber and the cleaning chamber, and the foot-operated wireless switch allows the foot-operated solenoid valve to be foot-operated to switch between an open state and a closed state and enables the cleaning bucket to switch between the circulating state and the closed state.

37. The cleaning bucket of claim 32, wherein the mop actuates the water ingress control mechanism and controls the cleaning bucket to automatically switch from the closed state to the flow-through state when the mop enters the cleaning cavity from the cleaning opening.

38. The cleaning bucket of claim 37, wherein the inlet control mechanism includes an electrically controlled inlet valve, a control member and a detection member, wherein the electrically controlled inlet valve is communicatively connected to the control member, the control member is communicatively connected to the electrically controlled inlet valve, the electrically controlled inlet valve is disposed in the inlet passage, the detection member is disposed in the cleaning device, and when the detection member detects that the mop enters the cleaning chamber, the control member controls the electrically controlled inlet valve to open and makes the inlet passage communicate with the clean water chamber and the cleaning chamber.

39. The cleaning bucket of claim 37, wherein the bucket body includes a container body, a water inlet partition and a waste partition, wherein the container body has a container space, wherein the water inlet partition and the waste partition are spaced apart from each other in the container space of the container body, and form the clean water chamber between the container body and the water inlet partition, the clean water chamber between the water inlet partition and the waste partition, and the waste water chamber between the container body and the waste partition, the water inlet passage is formed in the water inlet partition, and the water inlet control mechanism is movably disposed in the water inlet partition.

40. The cleaning bucket according to claim 37, wherein the water inlet control mechanism includes a trigger member, an elastic restoring member, a linking member, a retaining member, an extending member and a water-blocking plug, wherein the trigger member and the extending member are respectively disposed at the upper end portion and the lower end portion of the linking member, the linking member is obliquely retained in the washing chamber, the trigger member and the extending member are disposed at both sides of the linking member, the water-blocking plug is fixed at the end portion of the extending member, the retaining member is fixed at the containing device, the middle portion of the linking member is rotatably mounted to the retaining member, the elastic restoring member is retained between the trigger member and the water inlet partition, and the water-blocking plug is movably mounted to the water inlet passage.

41. A cleaning implement comprising a mop and a cleaning bucket as claimed in any one of claims 1 to 40.

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