CN114376466B

CN114376466B - Method for manufacturing flexible endless belt for surface cleaning, flexible endless belt, and cleaning base

Info

Publication number: CN114376466B
Application number: CN202111022741.6A
Authority: CN
Inventors: 唐成; 段飞; 钟亮
Original assignee: Beijing Shunzao Technology Co Ltd
Current assignee: Beijing Shunzao Technology Co Ltd
Priority date: 2021-09-01
Filing date: 2021-09-01
Publication date: 2023-04-14
Anticipated expiration: 2041-09-01
Also published as: CN114376466A

Abstract

The present disclosure provides a method of manufacturing a flexible endless belt for surface cleaning, which is applied to a cleaning base, and cleans a surface to be cleaned by the flexible endless belt when the flexible endless belt is driven to move, comprising: maintaining the substrate in tension; applying an adhesive to at least a partial region of the outer peripheral surface of the base material and/or to at least a partial region of one surface of the cleaning body; winding a cleaning body around the outer peripheral surface of the base material and forming a cleaning surface of the cleaning body into the outer peripheral surface of the flexible annular belt; and securing at least one end of the cleaning body to at least one open end of the substrate. The present disclosure also provides a flexible endless belt and a cleaning base.

Description

Method for manufacturing flexible endless belt for surface cleaning, flexible endless belt, and cleaning base

Technical Field

The present disclosure relates to a method of manufacturing a flexible endless belt for surface cleaning, a flexible endless belt, and a cleaning base.

Background

Wet surface cleaning apparatuses are suitable for cleaning hard floor surfaces, such as ceramic tiles, hardwood floors, soft carpeted surfaces and the like.

When the wet type surface cleaning device cleans the surface to be cleaned, the cleaning liquid is firstly conveyed to the cleaning module, and is applied to the surface to be cleaned through the cleaning module, and when the cleaning module and the surface to be cleaned generate relative motion, the surface to be cleaned is cleaned.

The crawler-type cleaning device can effectively improve the contact area between the cleaning module and the surface to be cleaned, so that the wet-type surface cleaning equipment has a better cleaning effect. However, when the crawler-type cleaning device is used, the position of the flexible annular belt is limited in a mode that the end covers are pressed tightly, so that the cleaning distance of the flexible annular belt to the edge is large, and the use experience is poor.

Moreover, the flexible track is prone to slipping during use, which affects the cleaning efficiency of the surface cleaning apparatus and has a relatively short service life.

Disclosure of Invention

In order to solve one of the above-described technical problems, the present disclosure provides a method of manufacturing a flexible endless belt for surface cleaning, a flexible endless belt, and a cleaning base.

According to an aspect of the present disclosure, there is provided a flexible endless belt manufacturing method applied to a cleaning base to clean a surface to be cleaned by a flexible endless belt when the flexible endless belt is driven to move, the flexible endless belt manufacturing method including:

maintaining the substrate in a tensioned state;

applying an adhesive to at least a partial region of the outer peripheral surface of the base material and/or to at least a partial region of one surface of the cleaning body;

winding a cleaning body around an outer circumferential surface of a base material such that a cleaning surface of the cleaning body is formed as an outer circumferential surface of the flexible annular band; and

at least one end of the cleaning body is secured to at least one open end of the substrate.

According to the flexible endless belt manufacturing method of at least one embodiment of the present disclosure, the re-fixing of the at least one end portion of the cleaning body with the at least one end portion of the base material includes:

and (3) fixing at least one end of the cleaning body and at least one end of the base material again by sewing through the sewing thread.

According to a flexible endless belt manufacturing method of at least one embodiment of the present disclosure, the sewing lines sew at least a partial region of the cleaning body in a circumferential direction of the end portion of the cleaning body.

According to the flexible endless belt manufacturing method of at least one embodiment of the present disclosure, a groove is formed on an inner peripheral surface of the base material so that at least a part of the sewing thread is located within the groove.

According to at least one embodiment of the present disclosure, the flexible endless belt is formed by a plurality of flexible endless belts.

In accordance with at least one embodiment of the present disclosure, the flexible endless belt is manufactured by a method in which the seam is located within the groove.

According to the manufacturing method of the flexible endless belt of at least one embodiment of the present disclosure, the groove is formed as an annular mounting groove along a circumferential direction of the base material, and the sewing line is sewn once along the circumferential direction of the cleaning body.

According to the manufacturing method of the flexible endless belt of at least one embodiment of the present disclosure, the flexible endless belt is driven to rotate by a rotating portion, an annular mounting groove is formed in a circumferential direction of the rotating portion, and when the flexible endless belt is engaged with the rotating portion, a suture thread is positioned in the groove.

According to the manufacturing method of the flexible endless belt of at least one embodiment of the present disclosure, an axial direction restriction portion is formed on an inner wall surface of the base material in a circumferential direction of the base material, and when the flexible endless belt is engaged with the rotating portion, a position of the flexible endless belt in an axial direction of the rotating portion is restricted by the axial direction restriction portion.

According to a manufacturing method of a flexible endless belt of at least one embodiment of the present disclosure, the axial stopper portion includes an annular groove and an annular projection formed in a circumferential direction of an inner surface of the base material.

According to the flexible endless belt manufacturing method of at least one embodiment of the present disclosure, after the adhesive is cured, at least one end portion of the cleaning body and at least one end portion of the base material are fixed again.

According to another aspect of the present disclosure, there is provided a flexible endless belt manufactured by the above-described method of manufacturing a flexible endless belt, including: the base material is made of a flexible material; and a cleaning body bonded to the substrate such that a cleaning surface of the cleaning body forms a portion of an outer surface of the flexible endless belt;

wherein at least one of both ends of the cleaning body is fixed to an end portion of the base material.

According to a flexible endless belt of at least one embodiment of the present disclosure, one end of the cleaning body and one end of the base material are sewn by a suture line so that the one end of the cleaning body is fixed to the one end of the base material.

According to a flexible annular band of at least one embodiment of the present disclosure, the sewing line sews at least a partial region of the cleaning body in a circumferential direction of the end portion of the cleaning body.

According to the flexible endless belt of at least one embodiment of the present disclosure, a groove is formed on an inner peripheral surface of the base material so that at least a part of the sewing thread is located within the groove.

According to at least one embodiment of this disclosure, the flexible annular band, the suture thread stubs are located within the groove.

According to the flexible annular belt of at least one embodiment of the present disclosure, the groove is formed as an annular mounting groove along a circumferential direction of the base material, and the sewing line is sewn for one turn along the circumferential direction of the cleaning body.

According to the flexible annular belt of at least one embodiment of this disclosure, the flexible annular belt passes through the rotation portion drive and rotates, is formed with annular mounting groove in the circumference of rotation portion, when the flexible annular belt with the rotation portion cooperation, make the stylolite be located in the recess.

According to the flexible annular belt of at least one embodiment of the present disclosure, an axial direction restriction portion is formed on an inner wall surface of the base material in a circumferential direction of the base material, and when the flexible annular belt is engaged with the rotating portion, a position of the flexible annular belt in an axial direction of the rotating portion is restricted by the axial direction restriction portion.

According to the flexible annular band of at least one embodiment of this disclosure, the axial stopper portion includes an annular groove and an annular protrusion formed in a circumferential direction of the inner surface of the base material.

According to another aspect of the present disclosure, there is provided a cleaning base comprising: a housing module forming an accommodating portion; the rotating shaft assembly is rotatably arranged on the shell module and is positioned in the accommodating part; the flexible annular belt wraps the rotating shaft assembly and is driven by the rotating shaft assembly to move so as to clean the surface to be cleaned through the flexible annular belt;

wherein the flexible annular band is located in a receiving portion of the housing module.

Drawings

The accompanying drawings, which are included to provide a further understanding of the disclosure and are incorporated in and constitute a part of this specification, illustrate exemplary embodiments of the disclosure and together with the description serve to explain the principles of the disclosure.

Fig. 1-10 show schematic views of a surface cleaning apparatus according to various embodiments of the present disclosure.

Fig. 11 shows a schematic view of a connection according to one embodiment of the present disclosure.

Fig. 12 to 14 show schematic views of a cleaning liquid storage part according to an embodiment of the present disclosure.

Fig. 15 to 24 show schematic views of the whole or parts of the recovery storage part according to an embodiment of the present disclosure.

Fig. 25 shows a schematic view of an electrical line accommodation portion according to an embodiment of the present disclosure.

Fig. 26-64 show schematic views of all or part of the components of a cleaning base according to various embodiments of the present disclosure.

Detailed Description

The present disclosure will be described in further detail with reference to the drawings and embodiments. It is to be understood that the specific embodiments described herein are for purposes of illustration only and are not to be construed as limitations of the present disclosure. It should be further noted that, for the convenience of description, only the portions relevant to the present disclosure are shown in the drawings.

Figure 1 shows a schematic view of the surface cleaning apparatus from one angle. Figure 2 shows a schematic view of another angle of the surface cleaning apparatus. Figure 3 shows an exploded view of the surface cleaning apparatus.

As shown in fig. 1 to 3, the surface cleaning apparatus may include a handle portion 100, a main body portion 200, a cleaning liquid storage portion 300, a recovery storage portion 400, a connecting portion 500, and a cleaning base 600.

The handle portion 100 may include a handle portion 110 and a connection rod 120. The handle portion 100 is for gripping by a user to operate the surface cleaning apparatus.

A control portion 111 may be provided on the handle portion 110, wherein a user may control the surface cleaning apparatus through the control portion 111, the control portion 111 may be in the form of a control button, a touch button, or the like, and a plurality of control portions 111 may be provided on the handle portion 110 to perform various controls on the surface cleaning apparatus.

The control part 111 may be provided in the accommodation space provided by the handle part 110, and in the case of a control button or the like, for example, the control part 111 may move relative to the surface of the handle part 110 to turn on or off the corresponding operation. The surface of the control part 110 may be disposed to be recessed with respect to the outer contour surface of the handle part 110, that is, the surface of the control part 110 may be disposed to be lower than the outer contour surface of the handle part 110. With such an arrangement, a user can be prevented from operating the surface cleaning apparatus by mistake or unintentionally. For example, in the case where the surface cleaning apparatus uses a cleaning liquid having a relatively high temperature, it is possible to ensure the operation related to the high-temperature cleaning liquid, and for example, in the case where the high-temperature cleaning liquid is replenished from a base station or cleaning is performed by the high-temperature cleaning liquid, if the control portion concerned is erroneously triggered, a safety hazard may be caused. For safety, a control unit in the form of a thumb switch or the like may be used.

The connecting rod 120 may be disposed between the handle portion 110 and the body portion 200 to connect the handle portion 100 and the body portion 200. Wherein the connecting rod 120 may be in the form of a hollow tube, for example it may be a hollow circular tube. The connecting rod 120 may be fixedly connected to or integrally provided with the handle portion 100. The connection end of the connection rod 120 is connected to the body portion 200.

Fig. 4 shows a schematic view of the handle portion 100 separated from the body portion 200 (a portion of which is shown). The connection end of the connection rod 120 may be provided with a mounting hole 121 and a mounting groove 122. The mounting groove 122 may be a notch extending along the length direction of the connecting rod 120 or a groove provided at the end of the connecting end, and in the case where the connecting rod 120 is inserted into the main body 200, the mounting groove 122 may be engaged with a protrusion provided in the main body 200, so that the handle portion 100 may be prevented from being rotated after the connecting rod 120 is connected to the main body 200. In addition, the mounting hole 120 may be fitted with a mounting protrusion 211 provided to the main body portion 100, so that the mounting protrusion 211 may be fitted into the mounting hole 121 to fix the connecting rod 120 when the connecting rod 120 is coupled to the main body portion 200. The body portion 200 may be provided with an inner sleeve 212, wherein the inner sleeve 212 may be inserted into the hollow portion of the connecting rod 120, mating with the opening of the connecting end of the connecting rod 120. The body portion 200 may further be provided with an outer sleeve 213, and the outer sleeve 212 may be tightly sleeved on the outer side of the connecting end of the connecting rod 120. By way of the present disclosure, the handle portion 100 may be detachably mounted to the body portion 200, for example, the mounting boss 211 may be pressed to be disengaged from the mounting hole 121 at the time of detachment, and thus the handle portion 100 may be detached from the body portion 200, except that, at the time of mounting, the lower end of the connecting rod 120 is allowed to pass through and then fitted into the mounting hole 121 by inserting the connecting rod 120 and setting the slope of the mounting boss 211.

The surface cleaning apparatus may also include a display, which may be in the form of, for example, an LED or LCD display screen, a touch screen, or an indicator light. As shown in fig. 1 (only the mounting position of the display unit is shown in fig. 1), the display unit 214 may be provided on the front side surface of the main body 200, or the display unit 214 may be provided on the upper side surface of the main body 200. In the present disclosure, it is preferable that the display screen is disposed at an upper position of the front side of the main body 200. In addition, the present disclosure may include two or more display portions, and the display portions may be provided at positions such as a front side surface and an upper side surface, respectively. The display section may provide a display interface to display the working posture or the like of the surface cleaning apparatus to the user. Further, in the case where the display portion is a touch screen, the surface cleaning apparatus may receive an instruction of a user through the touch screen. In one embodiment, the display may display a plurality of poses of the surface cleaning apparatus, and may display pose information of the surface cleaning apparatus, including, but not limited to: a condition of a surface to be cleaned (hard floor, carpet, etc.), a cleaning mode (e.g., normal cleaning mode, intensive cleaning mode, pressurized cleaning mode, etc.), a battery power condition, a wireless (e.g., WIFI) connection gesture, a cleaning liquid level, a cleaning liquid storage mounted in place, a recovery liquid level, a filter gesture, a floor type, a self-cleaning mode, etc. The gesture display type provided by the display part can be various display types such as visual display, text display, graphic display or indicator light display.

According to one embodiment of the disclosure, a surface cleaning apparatus may be in wireless communication with a portable device to provide gestures to the portable device and/or receive instructions from the portable device. The portable device may be in various forms such as a smart phone, a tablet computer, a notebook computer, and the like. The interactive interface of the display screen in the portable device may provide the pose of the surface cleaning apparatus to the user via a communication connection in the form of a local or wide area network, and may provide relevant instructions to the surface cleaning apparatus via user input, for example, the user may effect any suitable type of control of the surface cleaning apparatus such as self-cleaning, drying, water replenishment, heating, etc. via the interactive interface in the portable device.

A control circuit section 700, which may be in the form of a printed circuit board, may be provided in the main body section 200 of the surface cleaning apparatus, and an electronic device such as a Microcontroller (MCU), a memory, or the like may be provided on the control circuit section 700, and the control circuit section 700 may receive an instruction from the control section 111 and/or the display section 214, may provide various information to the display section 214, may also receive an instruction from a remote portable apparatus, or provide various information to a portable apparatus, or the like. The microcontroller may be operably coupled to various functional systems of the surface cleaning apparatus, including, but not limited to, cleaning fluid supply and fluid recovery systems, for example. A user may interact with the microcontroller via the control section 111, the display section 214, or a user interface of the portable device, for example, the microcontroller may be operatively coupled with the control section 111 to receive user input instructions, may be operatively communicatively coupled with the display section 214 to provide various display gesture information, or receive user instructions. In the present disclosure, the microcontroller may also be configured to execute a cleaning cycle for the self-cleaning mode of operation, and additionally the microcontroller may also execute software for a self-cleaning cycle, a drying cycle, and the like.

The control circuit unit 700 may further include a wireless communication module for performing wireless communication, for example, a WIFI module, and the wireless communication module may perform wireless communication with the portable device or may perform wireless communication with the control unit 111 (in addition, the control circuit unit 700 may be in communication connection with the control unit 111 in a wired manner). In case of connection with a portable device, the portable device may download a corresponding control program or may be a networked and device. The wireless communication module may detect the presence of a wireless network, wireless signal strength, router-related information, and is configured to be connectable to the internet through a local network. Furthermore, the wireless communication module can be integrated with the microcontroller.

A power supply 800, which may be a battery such as a rechargeable battery, may be provided in the main body portion 200 of the surface cleaning apparatus for cordless operation. The battery may be a polymer battery or a lithium ion battery, etc. And in one embodiment, the power supply part 800 may be detachably mounted to the main body part 200, and charging may be performed by detaching the power supply part 800 from the main body part 200. In addition, the power supply unit 800 may further include a charging port or a power line, and may be charged through the charging port without detaching the rechargeable battery, or may be operated by a cord through the power line, so that the cord operation may be performed when the cruising power demand is high, and the rechargeable battery may be in a power-off posture (supplied with power through the power line) when the cord operation is performed, or may be charged while supplying power to the surface cleaning apparatus.

In the present disclosure, the power supply part 800 is positioned to be isolated from potential liquid contact, for example, to avoid the influence of leakage of the cleaning liquid storage part 300 and/or the recovery storage part 400 and the like on the power supply part 800. In the present disclosure, the power supply part 800 is disposed at a position above the cleaning liquid storage part 300 and/or the recovery storage part 400 and in the main body part 200. Preferably, the power supply portion may be provided at a position below the cleaning liquid storage portion 300 and/or the recovery storage portion 400 and in the main body portion 200, and more optionally, in the main body portion 200 near the connection portion 500, and by this arrangement, the position of the center of gravity of the surface cleaning apparatus may be effectively lowered, thereby relieving the hand pressure of the user. Of course, it will be understood by those skilled in the art that other locations are possible, and it is only necessary to maintain the power supply part 800 at a distance from the location where the liquid leakage may occur.

In the present disclosure, the various components of the surface cleaning apparatus are arranged relative to each other so that the surface cleaning apparatus can be rotated in both directions. Although it is shown in the present disclosure that the movement may be in two directions, those skilled in the art may also set it to move only in the first direction described below.

In which in fig. 5 to 7 a rotation of the surface cleaning apparatus in a first direction (hereinafter also referred to as X-direction) is shown, wherein the first direction is in a plane perpendicular to the surface to be cleaned, which may also be referred to as up-down rotation relative to the surface to be cleaned. For example, fig. 5 shows the surface cleaning apparatus in an upright posture, fig. 6 shows the surface cleaning apparatus in a posture rotated by 30 °, and fig. 7 shows the surface cleaning apparatus rotated to a posture parallel to the surface to be cleaned. Wherein in the first orientation the surface cleaning apparatus (main body portion) is rotatable relative to the surface to be cleaned in a range of 0 ° to 120 °, optionally in a range of 0 ° to 95 °, 0 ° to 110 ° or the like. The posture parallel to the surface to be cleaned means that the angle between the main body portion and the surface to be cleaned is 0 ° or substantially 0 ° (e.g., 0 ° to 5 °, etc.).

Fig. 8 to 10 show the rotation of the surface cleaning apparatus in a second direction (hereinafter also referred to as Y-direction) in a plane parallel to the surface to be cleaned, which may also be referred to as left-right rotation relative to the surface to be cleaned. For example, fig. 8 shows the surface cleaning apparatus not rotating in the second direction, fig. 9 shows the surface cleaning apparatus rotating in the second direction, and fig. 10 shows the surface cleaning apparatus not being able to rotate in the second direction.

As shown in fig. 6, the X-axis about which the X-direction rotation is about may be perpendicular to the direction of the page of fig. 6, and the X-direction rotation may be defined by a pivot joint. The Y axis about which the Y direction rotation is about may be perpendicular to the X axis (a direction parallel to the plane of the paper of fig. 6, e.g. the Y axis extends along the main body portion) and the Y direction rotation may be defined by a swivel joint, further the Y axis is optionally perpendicular to the axis of the moving wheel of the cleaning base and/or the axis of the roller brush of the cleaning base. The Y axis may be at an angle (e.g. an acute angle) to the surface on which the surface cleaning apparatus is placed, such as 80 ° to 90 °, preferably around 80 °, when the main body portion is in an upright position, as shown in figure 5, the acute angle being the angle between the main body portion and the cleaning base, that is, the main body portion is inclined in a forward ("left" in figure 5) downward direction. When the main body is rotated so that the surface cleaning apparatus is in an inclined use position, the Y axis will be at an acute angle to the placing surface (surface to be cleaned) on the other side (right side), that is, the main body is inclined in a rearward (right in fig. 5) downward direction.

When the surface cleaning apparatus is in the upright posture, the X-axis is set to a position in which the intersection of the Y-axis and the surface to be cleaned is forward (leftward in the drawing) and when the surface cleaning apparatus is in the inclined posture, the X-axis is set to a position in which the intersection of the Y-axis and the surface to be cleaned is rearward (rightward in the drawing), as viewed from the position in which the user uses the surface cleaning apparatus, as shown in fig. 5 and 6.

The rotation of the surface cleaning apparatus may be defined by the attachment 500 described above. Wherein the connection part 500 may be a separate component and fixed to the lower end of the main body part 200, or the connection part 500 may be a component integrally molded with the main body part 200 and located at the lower end of the main body part 200.

The connection part 500 is used to connect the main body part 200 with the cleaning base 600, the connection part 500 may be a hollow structure, and air, fluid communication, and lines and the like required for power supply and the like between the main body part 200 and the cleaning base 600 such as a floor brush may be implemented through the connection part 500, so that power supply, circulation of air and/or liquid, and the like may be implemented between the main body part 200 and the cleaning base 600 via wires and/or pipes passing through the connection part 500. Furthermore, a flexible hose for sucking dust and recovering liquid may be passed through the connection portion.

As shown in fig. 11, a collection hose for collecting liquid, garbage, and the like can be housed inside the connection portion 500, and an outlet 506 of the hose can communicate with the collection and storage portion. The recovery hose is of a flexible material and can be deformed in response to tilting of the surface cleaning apparatus. In addition, a cleaning liquid supply line 308 may be accommodated, and the cleaning liquid supply line 308 may pass through the connection part 500 and communicate with a corresponding line in the cleaning base 600, thereby sending the cleaning liquid into the cleaning base 600. The cleaning liquid supply conduit 308 may be rigid and not bend as the connection rotates. Further, a liquid detecting device may be further provided at the cleaning liquid supply line 308 for detecting whether the cleaning liquid is supplied to the cleaning base 600, and a detection signal of the liquid detecting device may be supplied to a microprocessor or the like.

According to one embodiment, the connection part 500 may include a universal joint to enable the main body part 200 to be rotated in both directions with respect to the cleaning base 600.

According to one embodiment, the connection part 500 may include a polyaxial joint that may couple the main body part 200 with the cleaning base 600 so as to allow the main body part 200 to rotate in the first and second directions with respect to the cleaning base 600.

As shown in fig. 5, the main body 200 can be pivoted to an upright position (also referred to as a storage position) by the link 500, in which the main body 200 is at an angle of 80 ° to 90 °, preferably around 80 °, to the surface (or floor surface) of the cleaning base 600. In this position, the surface cleaning apparatus is in a self-supporting attitude (also referred to as an upright attitude), that is, the main body portion 200 and the like can be supported by the cleaning base 600, and the upright attitude can be achieved without the aid of other objects.

When the rotation in the X direction is defined by the pivot joint, for example, as shown in fig. 5, the surface of the cleaning base 600 may be provided with one support protrusion 501, and correspondingly, the connection part 500 may be provided with one support fitting 502 (as shown in fig. 6). As shown in fig. 8, the support projection 501 may be formed with a support groove 503, and the support groove 503 is provided corresponding to the support fitting 502, so that when the main body portion 200 is brought to an upright position (for example, between 80 ° and 90 ° with respect to the forward direction), the support fitting 502 is fitted into the support groove 503, and since the cleaning base 600 is placed on the floor, it may form a seat, and due to the abutting action of the support fitting 502 and the support projection 501, the surface cleaning apparatus is brought to a self-supporting posture. The support fitting part 502 and the support convex part 501 also have a releasable locking function, and when the main body part is enabled to be in the upright position, the support fitting part and the support convex part are clamped. When pivoting from the upright position to the main body portion, the user may apply a certain force causing the two to disengage.

When the main body 200 is rotated in the X direction, the support fitting portion 502 and the support protrusion portion 501 may be disengaged, for example, as shown in fig. 6. After the support fitting portion 502 and the support boss portion 501 can be disengaged, the main body 200 can be rotated in the Y direction up to a predetermined angle at which the main body 200 can be rotated. For example, fig. 8 shows the body portion 200 rotated to an angle, and fig. 9 shows the body portion 200 rotated in the Y direction at the angle. Here, the predetermined angle may be an angle of 30 ° from the horizontal direction of the surface to be cleaned. Of course, other angles, such as about 20 °, etc., may be provided.

As shown in fig. 7, the main body portion 200 can finally be rotated in the X direction to a position horizontal to the surface to be cleaned, and in the case of a predetermined angle smaller than the above (for example, in the case of less than 30 °). The main body portion 200 may be made incapable of rotating in the Y direction with respect to the cleaning base 600.

The connection portion 500 may be provided with a stopper protrusion 504. The stopper protrusion 504 may be provided on a side of the connection part 500 opposite to the support fitting part 502, and it may be integrally formed with the connection part 500. The limit protrusion 504 protrudes with respect to the surface of the connection part 500, and the limit protrusion 504 may include at least a limit plane 505. The stopper plane 505 may be provided at positions on both sides of the connection part 500. Accordingly, the cleaning base 600 can include an outwardly extending mount 6611. In the present disclosure, the mounts 6611 are two in number and each extend outwardly from the cleaning base 600. The mount 6611 may be used to support two moving wheels. For example, the roller of the moving wheel may be fixed to the extension arm. The two mounting members 6611 are spaced apart by a predetermined distance, wherein the distance may be equal to or slightly greater than the distance between the two limiting planes 505, such that when the main body portion 200 is rotated within a predetermined angular range (e.g., 0 ° to 30 °), the two limiting planes 505 may respectively contact the inner wall surfaces of the two mounting members 6611, thereby limiting the rotation of the main body portion in the Y direction. It should be noted that the mounting member 6611 should not cause any limitation to the rotation of the main body 200 without being in the predetermined angular range.

Further, at least one of the two extension arms may be provided as a hollow structure through which electric wires and/or pipes may be allowed to pass in order to communicate the main body part with the cleaning base.

According to the technical solution of the present disclosure, when the user operates the surface cleaning apparatus in a wide space, since the angle between the main body portion 200 and the surface to be cleaned is not too small (for example, in the case of 30 ° or more), since the mount 6611 does not cause any influence on the rotation in the Y direction, the user can rotate the main body portion 200 in the Y direction, thereby guiding the cleaning base portion 600 to turn left and right (Y direction). However, when a user desires to operate the surface cleaning apparatus in a narrow or low space (e.g., a sofa bottom or the like), the surface cleaning apparatus cannot enter the narrow or low space without lowering the posture of the main body portion 200, and thus the space will not be cleaned. In the present disclosure, the user may adjust the body portion 200 to have its posture lower, which enables the body portion 200 to extend into a narrow or low space. When the attitude of the main body portion 200 is below the predetermined angle, the user's controllability of the surface cleaning apparatus starts to decline, at which time the Y-direction rotation of the main body portion 200 with respect to the cleaning base 600 is not desired. In this way, the rotation in the Y direction can be restricted by the two stopper planes 505 contacting the inner wall surfaces of the two mounting members 6611, respectively, so that the user cannot perform the left-right guiding.

Further, although not shown in the figures, a pivot portion (e.g., a circular pivot shaft) may be provided on an inner wall surface of the mounting member 6611, and the pivot portion may be rotatably connected to the connecting portion (e.g., connected to a wall surface of the connecting portion, or provided with a corresponding lug on the connecting portion and connected to the pivot portion). Also the inner wall surfaces of the mounting members 6611 on opposite sides may be provided with pivot portions for connection with the connecting portions. By means of the pivot, the surface cleaning apparatus can be made to be rotatable in the X-direction.

Further, in the present disclosure, when the surface cleaning apparatus is in an inclined use position (for example, in a case where an angle with a surface to be cleaned is greater than or equal to 30 °), a rotation angle in the Y direction may be defined, thereby preventing the rotation angle in the Y direction from being excessively large.

Further, the connection part 500 may be detachably mounted with the cleaning base 600. For example, a snap structure may be provided therebetween, such as a mounting hole provided on the connecting portion and a snap projection provided on the cleaning base, the engagement of the two being achieved by fitting the snap projection into the mounting hole, and the disengagement of the two being achieved by pressing the snap projection away from the mounting hole.

In the present disclosure, as shown in fig. 7, when the main body 200 is in the "lying flat" (parallel to the surface to be cleaned) posture, the height of the main body 200 is set to be equal to or less than 120mm, for example, the height may be set to be 100mm to 120mm, or 105mm to 120mm, or the like, and further, the height of the cleaning base 600 is set to be equal to or less than the height of the main body 200. In addition, the width of the cleaning base 600 should be set to be greater than or equal to the width of the main body 200 (the "width" referred to herein means the width of the cleaning base and the main body in a direction perpendicular to the direction of travel of the surface cleaning apparatus (both directions are in a horizontal plane)).

In addition, to facilitate movement of the surface cleaning apparatus by a user when the main body 200 is in a "lying flat" (parallel to the surface to be cleaned) position, parallel rollers 215 may be provided. In the lying position shown in fig. 7, the user can operate the surface cleaning apparatus by holding the handle portion without providing a supporting force to the surface cleaning apparatus, according to the parallel roller 215. The supporting force of the surface cleaning apparatus can be achieved by moving the wheels and the parallel rollers. Thus in the lying position, the user need only apply a towing force to operate the surface cleaning apparatus. In addition, the parallel roller 215 is disposed at a position separated from the center of gravity of the surface cleaning apparatus or the center of gravity of the main body to prevent the surface cleaning apparatus from being tilted. The parallel rollers may be disposed on the main body portion, the handle portion, or the like.

According to the above-mentioned embodiment of the present disclosure, the user can make the main body portion rotate along both the X direction and the Y direction within a certain angle range, and can conveniently realize the guiding of the cleaning base portion, and will restrict the main body portion from rotating in the Y direction within another angle range. This arrangement may allow the user to better operate the surface cleaning apparatus.

As shown in fig. 3, the main body 200 may include a frame body 220 for supporting the cleaning liquid storage 300 and the recovery storage 400, and may also be used for supporting other components, such as a motor, a fan, and the like. For example, on a portion of the frame body 220 that houses the cleaning liquid storage 300 and the recovery storage 400, two housing walls may be provided, and the liquid storage 300 and the recovery storage 400 are housed at least partially in the two housing walls, which may constitute a housing of the surface cleaning apparatus. In the case of two housing walls, the housing walls are provided on opposite sides of the side of the surface cleaning apparatus different from the cleaning liquid storage part 300 and the recovery storage part 400, and extend in the height direction of the surface cleaning apparatus.

The cleaning liquid storage part 300 and the recovery storage part 400 may be disposed on the frame body 220 so as to be located at both sides of the main body part 200. In the present disclosure, the cleaning liquid storage 300 and the recovery storage 400 are optionally located on both left and right sides of the main body portion 200 (with respect to the travel direction of the surface cleaning apparatus, the cleaning path). The thickness of the cleaning liquid storage part 300 may be equal to or less than the thickness of the recovery storage part 400, and the heights thereof may be the same or substantially the same. It should be noted that although the cleaning liquid storage unit 300 and the recovery storage unit 400 are mainly described as being located on the left and right sides of the main body 200 in the present disclosure, it is also preferable that the cleaning liquid storage unit 300 and the recovery storage unit 400 are provided on the front and rear sides (front and rear sides along the cleaning direction) of the main body 200 in the present disclosure, and in the case of providing on the front and rear sides, the respective arrangement relationships of the respective components described herein are also the same or similar.

In the present disclosure, the cleaning liquid storage part 300 and the recovery storage part 400 may be detachably mounted to the side of the frame body 220, the mounted side may be the opposite side of the frame body 220, and the thickness of the cleaning liquid storage part 300 and the recovery storage part 400 is set to be smaller than the width, which may secure a sufficient capacity and may make the height of the main body part 200 less than a predetermined height, for example, 120mm, after lying flat.

Fig. 12 and 13 show schematic views of a cleaning liquid storage 300 according to an embodiment of the present disclosure. Fig. 14 shows a schematic view of the cleaning liquid storage 300 with a part of the wall removed. The cleaning liquid storage part 300 is used to store cleaning liquid and is provided to the cleaning base 600 via a pipe. In this context, the cleaning liquid may be one or more of any suitable liquid, including but not limited to cleaning water, concentrated detergent, dilute detergent, mixtures thereof, or the like. In addition, the cleaning liquid can be normal-temperature cleaning liquid or high-temperature cleaning liquid.

As shown in fig. 12 to 14, the cleaning liquid storage part 300 is flat in shape, and includes a cavity constituted by a plurality of wall surfaces so as to contain the cleaning liquid, and the capacity of the cleaning liquid storage part 300 may be set to 500mL or the like. The cleaning liquid storage part 300 may include a handle 301 and a pressing part 302, and preferably the handle 301 and the pressing part 302 are located at an upper position of the cleaning liquid storage part 300. The cleaning liquid storage part 300 can be attached or detached by a user through the handle 301, and specifically, the cleaning liquid storage part 300 can be detached by the user by pinching the pressing part 302 (having a spring built therein) to move it downward to disengage the latch member 303 from the groove provided in the main body part. In the present disclosure, although the handle 301 is illustrated as a built-in handle (hidden handle), it may be provided as an outwardly protruding handle by those skilled in the art. As shown in the drawing, the surface of the upper wall of the cleaning liquid storage part 300 is provided as an inclined surface, so that the cleaning liquid storage part 300 can be pushed onto the main body part 200 and fixed to the main body part 200 by the action of the latch member 303 when the cleaning liquid storage part 300 is mounted.

The cleaning liquid storage 300 may be provided with an inlet port 305, and the inlet port 305 may be closed by a cover plate 304. Thus, when the cleaning liquid is supplied to the cleaning liquid storage 300, the cover plate 304 may be opened to input the cleaning liquid through the inlet port 305. The cover plate 304 may then be closed to seal off the inlet port 305 to avoid leakage of cleaning liquid when the surface cleaning apparatus is in use. The cover plate 304 may be pivotable with respect to the wall surface of the cleaning liquid storage 300, for example, the underside of the cover plate 304 may have a pivot axis and the pivot axis is inserted into the wall surface.

In addition, the cover plate 304 is provided with a blocking portion, such as a plunger, in correspondence with the loading port 305, so that the loading port 305 is blocked by the blocking portion upon changing the closure, which at least partly enters the loading port 305. Of course, one skilled in the art will appreciate that other forms of sealing may be used.

At or near the location of the liquid inlet 305, a vent valve may be provided, which may be a two-way vent valve for selectively drawing gas into the cleaning liquid reservoir 300 or exhausting gas from the cleaning liquid reservoir 300 in order to equalize the internal and external pressures of the cleaning liquid reservoir 300. Further, a vent valve may be provided at an upper wall of the cleaning liquid storage part 300, and may be spaced a predetermined distance from the inlet port 305. The cover plate 304 may cover the inlet port 305 and the vent valve when closed. When the gas pressure on the two sides of the two-way vent valve is unbalanced, the vent valve can be deformed instantly, so that the internal and external gas flow is balanced.

According to an embodiment of the present disclosure, the cleaning liquid storage part 300 may further include a filter 306, the filter 306 being disposed at the liquid outlet of the cleaning liquid storage part 300, and the cleaning liquid supplied from the cleaning liquid storage part 300 is filtered through the filter 306 to filter out impurities in the cleaning liquid. An outlet valve 307 may also be provided in communication with the liquid outlet to selectively allow cleaning liquid to flow from the liquid outlet. The outlet valve 307 may be opened to allow the cleaning liquid to be supplied when the cleaning liquid storage part 300 is mounted to the main body part 200, and the outlet valve 307 may be closed to prevent the cleaning liquid from leaking when the cleaning liquid storage part 300 is removed from the main body part 200. A filter 306 may be installed at one side of the lower wall surface of the cleaning liquid storage part 300 and an outlet valve 307 may be installed at the other side, which are the positions of the liquid outlet.

The outlet valve 307 may communicate with the cleaning liquid supply pipe 308, and the cleaning liquid supply pipe 308 may be accommodated inside the connection part 500 as described above and communicate with the supply pipe of the cleaning base 600. In addition, a liquid detecting means may be further provided near the cleaning liquid supply line 308 or the outlet valve 307 for detecting whether or not the cleaning liquid is supplied to the cleaning base 600. The liquid detection device may be any suitable detection device for detecting the presence of cleaning liquid in the cleaning liquid supply line 308. The liquid detection device may be a conductivity sensor and is located in the cleaning liquid supply line 308 to detect the presence of cleaning liquid.

When the liquid detection means detects that there is no liquid, indicating that there is no cleaning liquid in the cleaning liquid storage 300 or that the cleaning liquid storage 300 has been removed, the liquid detection means may provide a signal to the microcontroller, which may provide information to the user through the display. In addition, the liquid detection device may be located inside the cleaning liquid storage portion 300 and used for detecting the liquid level of the cleaning liquid storage portion 300, so that when the liquid level is too low, indicating that no cleaning liquid exists in the cleaning liquid storage portion 300, a signal may be provided to the microcontroller, or when the cleaning liquid storage portion 300 is removed from the main body portion 200, the electrical connection of the liquid detection device is disconnected, and the microcontroller may also know that the cleaning liquid storage portion 300 is removed.

The input from the liquid detection means may further be used by the microcontroller in order to determine a suitable shut down or otherwise interrupt the supply system of cleaning liquid. For example, the microcontroller may shut down or prevent at least one electrical component of the surface cleaning apparatus from being activated when cleaning liquid is not present in the cleaning liquid store 300 or when it is removed. The electrical components may include pumps, valves, various motors, etc., which may stop the operation of the surface cleaning apparatus.

In the case where the surface cleaning apparatus is in the lying posture, the height of the cleaning liquid storage 300 may be set to be significantly larger than the width thereof, and the liquid outlet of the cleaning liquid storage 300 may be set at a lower position (right position in fig. 14) of the lower wall surface of the cleaning liquid storage 300.

Fig. 15 to 18 show schematic views of a recycling storage section 400 according to one embodiment of the present disclosure. In which fig. 15 shows a schematic view of the recycling storage 400 at one angle, fig. 16 shows a schematic view of the recycling storage 400 at another angle, fig. 17 shows an exploded view of a part of the recycling storage 400, and fig. 18 shows an exploded view of the recycling storage 400.

As shown in fig. 15 to 18, the recovery storage part 400 includes a cavity constituted by a plurality of wall surfaces so as to accommodate the recovery liquid. The recovery storage part 400 may include a second handle 401 and a second pressing part 402, and preferably the second handle 401 and the second pressing part 402 are located at an upper position of the recovery storage part 400. The user can mount or remove the recovery storage part 400 through the second handle 401, and specifically, the user can remove the recovery storage part 400 by kneading the second pressing part 402 (having a spring built therein) to move it downward to disengage the second latch 403 from the groove provided in the main body part. In the present disclosure, although the second handle 301 is illustrated as an outwardly protruding handle, it may be provided as a built-in handle (hidden handle) by those skilled in the art. As shown in the drawings, the surface of the upper wall of the recovery storage part 400 is provided as an inclined surface, so that the recovery storage part 400 can be pushed onto the main body part 200 and fixed to the main body part 200 by the action of the second latch 403 when the recovery storage part 400 is mounted.

The underside of the recovery storage portion 400 may be provided with an inlet port 404, and the inlet port 404 may communicate with an outlet 506 of a hose so as to enter the recovery storage portion 400 through the inlet port 404 with the recovered solid waste or the recovered liquid.

Further, a liquid level detection portion 405 may be further provided in the recovery storage portion 400, wherein the liquid level detection portion 405 may be provided in plurality so as to detect both the liquid level of the internal recovery liquid when the recovery storage portion 400 is in the upright posture and the liquid level of the internal recovery liquid when the recovery storage portion 400 is in the horizontal posture, which will be described later in detail.

According to one embodiment of the present disclosure, the recycling storage part 400 may include two parts: a first storage section 406 and a second storage section 407. Wherein the first storage 406 and the second storage 407 are separable. When it is necessary to remove the garbage and the recovery liquid from the recovery storage part 400, the first storage part 406 and the second storage part 407 may be separated. When the first storage portion 406 and the second storage portion 407 are joined together, a seal may be provided therebetween to ensure that the recovered liquid does not leak or the like.

As shown in fig. 17 and 18, the top wall of the first storage portion 406 may be provided with an exhaust port 408, the exhaust port 408 providing a passage port through which gas during suction by the surface cleaning apparatus is exhausted from the surface cleaning apparatus. A gas filtering assembly, which may be any suitable form of filter such as a HEPA filter, for example, may also be provided outside of the exhaust port 408. The gas filter assembly may be disposed in first reservoir 406 or in body portion 200 above first reservoir 406. For example, where the gas filter assembly is disposed in the body portion 200, the gas filter assembly may be disposed adjacent the exhaust port 408 and receive gas from the exhaust port 408. For example, a filter assembly receiving part may be provided at a corresponding position of the main body part 200, and the gas filter assembly may be detachably mounted thereto.

The gas filtration assembly may include a filter media supported on a support, which in one embodiment may be a pleated filter media, and may be made of a material that remains porous when wet. The air filter assembly may further include a mesh screen carried by the frame and disposed on the air upstream side of the filter media for filtering large particles of material. The gas filter assembly may be designed as a unitary assembly for removal from the filter assembly receptacle for replacement or the like.

A gas-liquid separation device 420 may be accommodated in the first storage part 406, wherein the gas-liquid separation device 420 may include a gas-liquid separation motor 421 and a gas-liquid separator 422. The gas-liquid separator 422 is driven to operate by the rotation of the gas-liquid separating motor 421, so that the recovered gas and liquid are separated from each other, the liquid is left in the recovery storage part 400, and the gas is discharged from the surface cleaning apparatus after being filtered.

In one embodiment of the present disclosure, the rotating shaft of the gas-liquid separation motor 421 may be coupled with the first timing pulley 423, and the second timing pulley 424 is coupled with the first timing pulley 423 through a timing belt 425, such that when the gas-liquid separation motor 421 rotates, the second timing pulley 424 rotates accordingly. The second timing pulley 424 and bearings 426 are coupled to a drive shaft 427, and the drive shaft 427 is used to drive the gas-liquid separator 422 for rotation.

In one embodiment, the reclamation store 400 may also include a filter 430. The filter 430 will be described in detail with reference to fig. 19 to 21, in which the opposite arrangement of the filter 430 and the gas-liquid separation device 420 is shown in fig. 20 and 21. The filter 430 may include a solid storage portion 431, a conduit passing port 432, a filtering portion 433, a second anti-surge portion 434, and a first anti-surge portion 435.

The solid receptacle 431 can be used to store solid waste, such as debris, hair, etc., recovered during cleaning. The solid storage part 431 at least comprises a bottom wall 4311, a first side wall 4312 and a top wall 4313, wherein the bottom wall 4311 and the first side wall 4312 are provided with liquid guide holes, so that the recovered liquid flows out from the solid storage part 431 to the cavity of the recovery storage part 400, and only the solid garbage is left. Wherein the drain hole is sized to allow only liquid or liquid and fine debris to pass through. The solid storage part 431 may further include an open part so that the solid waste can be discharged through the open part when the user cleans the solid waste. A conduit pass-through port 432 may be provided in the bottom wall 4311, the conduit pass-through portion 432 allowing a recovery conduit (not shown) to pass therethrough, wherein the recovery conduit communicates with the inlet port 404 of the liquid storage portion 400 to direct recovered liquid or solids or the like to the filter 430 when the surface cleaning apparatus is in operation.

Additionally, the solids reservoir 431 may further include a second side wall 4314 and a third side wall 4315, wherein the second side wall 4314 and the third side wall 4315 are oppositely disposed and extend between the bottom wall 4311 and the top wall 4313. In the present disclosure, the second and

third side walls

4314 and 4315 are provided only at a partial position between the bottom wall 4311 and the top wall 4313, and an unprepared position may be used as the above-described open portion. The solid storage part 431 may further include a fourth side wall 4316, the fourth side wall 4316 extending upward from the bottom wall 4311, but it does not extend to the top wall 4313, but is provided to extend only a distance, so that a space for containing the solid may be formed by the fourth side wall 4316, the second side wall 4314, the third side wall 4315 and the bottom wall 4311, and it is also possible to facilitate the cleaning of the garbage through the open part. End faces of the fourth side wall 4316, the second side wall 4314, the third side wall 4315, and the top wall 4313 may be provided to fit an inner wall of the recovery storage part 400.

A space, which may be shaped like an L and opened on the top wall 4313 adjacent to the first side wall 4312, is opened on the top wall 4313 and a filter net (not shown) is detachably mounted to constitute the filter part 433. Further, a conduit support part 436 may be provided on the top wall 4313, and the conduit support part 436 extends a predetermined length toward the inside of the solid storage part 431 to support an end (open end) of the recovery conduit. Further, after supporting the end of the recovery conduit, the open end of the recovery conduit may be directed toward the top wall 4313 and spaced a distance from the top wall 4313. As shown in fig. 20, since the top wall 4313 is provided between and separates the open end of the recovery conduit and the gas-liquid separator 422, the recovery liquid from the open end of the recovery conduit can be prevented from reaching the gas-liquid separator 422 by the blocking action of the top wall 4313. When the recovered liquid with entrained solids enters the space formed by the solids reservoir 431 through the recovery conduit, the solids are retained in the space of the solids reservoir 431 by the filter 433 in the form of a screen or the like, and only the liquid is allowed to enter the space where the gas-liquid separator 422 is located through the filter 433, so that the solids are retained in the solids reservoir 431.

The second anti-surge portion 434 is provided in the form of a partition plate, and one or more liquid through holes are opened in the partition plate so as to allow the recovery liquid to pass therethrough, prevent the rapidly changing liquid from being waved in the recovery storage portion 400 by the blocking action of the partition plate when the recovery liquid passes therethrough, and allow the liquid in the spaces on both sides of the second anti-surge portion 434 to be communicated through the liquid through holes.

For example, when the surface cleaning apparatus is changed from the upright posture to the inclined use posture, or the parallel posture (lying posture), or from the inclined use posture to the parallel posture, the recovered liquid stored in the recovery storage part 400 will generate waves due to the change in the angle of the surface cleaning apparatus, and the liquid may enter the gas-liquid separator 422 if the waves are not suppressed. The waves can be blocked by the partition of the second anti-surge portion 434, and the liquid can also flow through the liquid through holes provided in the partition. At least one (for example, three) end surfaces of the second surge protector 434 may be attached to the inside of the collection storage unit 400.

Further, the opening area occupied by the filter portions 433 may be set to be larger than or equal to the opening area occupied by the liquid through hole or holes provided by the second anti-surging portion 434 (for example, the total opening area occupied by the two filter portions 433 may be set to be larger than or equal to the total opening area occupied by the liquid through holes), so that air mainly enters the gas-liquid separator 422 from the position of the filter portion 434 at least when the surface cleaning apparatus is in the parallel posture. Thus, when viewed in the parallel posture, the liquid is prevented from reaching the gas-liquid separator 422 from the lower portion of the first surging prevention part 435 through the first surging prevention part 435, affecting the gas-liquid separation effect of the gas-liquid separator 422.

The first anti-surge portion 435 is disposed opposite the gas-liquid separator 422, and optionally, a central axis of the first anti-surge portion 435 and a central axis of the gas-liquid separator 422 are parallel to or coincide with each other, and it is preferable in the present disclosure that both central axes coincide with each other (as shown in fig. 20). The central axis of the gas-liquid separator 422 may be an axis at which the center of the drive shaft thereof is located, and the central axis of the first surging prevention part 435 may be a central axis of a hollow portion of the first surging prevention part 435 mentioned below.

As shown, the first anti-surge portion 435 may include an edge portion 4351, a transition portion 4352, and a hollow portion 4353. The transition portion 4352 is located between the edge portion 4351 and the hollow portion 4353. From the plane in which the edge portion 4351 lies, the transition portion 4352 extends obliquely to the hollow portion 4353, such that the transition portion forms an inclined plane between the edge portion 4351 and the hollow portion 4353. When the surface cleaning apparatus mounted with the recovery storage part 400 is viewed in a parallel posture, the inclined direction of the transition portion 4352 is a downward direction, and the inclined direction of the transition portion 4352 is a direction away from the gas-liquid separator 422.

So that the liquid in the space where the gas-liquid separator 422 is located can enter the first anti-surge portion 435 and slide down along the transition portion 4352. Further, due to the shape arrangement of the first anti-surge portion 435, when the surface cleaning apparatus is changed from the upright posture to the inclined use posture, or the parallel posture (lying posture), or from the inclined use posture to the parallel posture, due to the angle change of the surface cleaning apparatus, it is also possible to cancel the waves generated by the angle change by the first anti-surge portion 435, thereby preventing the liquid from entering the gas-liquid separator 422 due to the waves.

Furthermore, when the surface cleaning apparatus (accordingly, the recovery storage portion 400) performs attitude change between the inclined use attitude and the parallel attitude, a wave may be formed between the first chamber and the fourth chamber, and the wave may affect the open end of the recovery duct 440 and even the gas-liquid separator 422. To avoid these effects, the bottom wall 4311 may serve as a third surge prevention portion, wherein when a wave contacts the bottom wall 4311, the wave may be counteracted by the avoidance of the bottom wall 4311, and fluid communication between the first and fourth chambers is achieved through the liquid guide hole of the bottom wall 4311. In an alternative embodiment, the first side wall 4312 can also be used as a third surge protection part, and the implementation principle thereof is the same as that of the bottom wall 4311, and the description thereof is omitted.

Therefore, according to the above mode of the present disclosure, a three-stage anti-surge function can be realized, so as to avoid a large amount of liquid from entering the gas-liquid separator 422.

As described above, when a user needs to clean the trash in the filter 430, it can be taken out of the recycling storage part 400, so that the first anti-surge part 435 can serve as a hand-held part for the user to take out the filter 430. When the first storage part 406 and the second storage part 407 are separated, a user can access the filter 430 accommodated therein through the opening of the second storage part 407, and then take out the filter 430 by holding the first anti-surge part 435. In an alternative embodiment, when filter 430 is installed in second storage portion 407, first anti-surge portion 435 protrudes outward relative to second storage portion 407 for gripping by a user.

In the present disclosure, the filter 430 may be integrally formed or fixedly provided, and as shown in fig. 20, the extending axes of the top wall 4313 and the second surge protector 434 coincide, or may be one plate-shaped portion, and the solid storage 431 is located at one side of the plate-shaped portion, while the first surge protector 435 is located at the other side of the plate-shaped portion. The first anti-surge portion 435 may be fixed to the top wall 4313 or integrally formed with the top wall 4313 or the like, and with respect to a central axis of the solid storage portion 431 (a central axis extending in the height direction of the recovery storage portion 400 in the upright posture), an extending direction of the first anti-surge portion 435 is deviated from the central axis so as to lift the filter 430 and provide a larger arrangement space to the filter portion 433.

The inner cavity of the recycling storage part 400 may be divided into a first cavity, a second cavity, and a third cavity according to a space formed by the filter 430 and the case of the recycling storage part 400. The first cavity is a space formed by the second anti-surge portion 434 and the first side wall 4312; the second cavity is a space formed by the first anti-surge part 435 and the second anti-surge part 434; the third cavity is a space formed by the first anti-surge part 435 and the top wall 4313, namely a space where the gas-liquid separator 422 is located; the fourth cavity is a space where the solid storage part 431 is located.

The formation of waves in the second chamber is prevented by the second anti-surge portion 434 when the liquid flows from the first chamber to the second chamber, and the formation of waves in the third chamber is prevented by the first anti-surge portion 435 when the liquid flows from the second chamber to the third chamber.

Fig. 22 shows an oblique sectional view of the recovery storage section 400. Fig. 23 shows a partial sectional view of the recovery storage part 400.

Fig. 22 and 23 are schematic views showing the recovery storage unit 400 in a parallel posture. It should be noted that although the parallel posture is taken as an example for explanation, the principle is the same in the case of the inclined use posture and the upright posture, and the description is omitted.

In the present disclosure, a suction source 460 (shown in FIG. 3) may be disposed in the recovery flow path to suction the recovered liquid, gas, and/or solids, wherein the suction source may be disposed downstream of gas-liquid separator 422. Wherein the suction source may be disposed in a housing, and the housing may include a suction motor housing that may house the suction motor and a fan housing that may house the fan. Alternatively, both may be provided in one housing. The fan housing may include a gas inlet to draw gas into the fan housing, and the gas inlet may be substantially aligned with a central region of the fan, which may be the central axis of the motor, for example. The fan housing may further comprise a gas outlet through which gas is discharged. The suction motor may be a brushless dc motor and may be powered directly by rechargeable batteries. In the case of supplying power by a wired method, an ac/dc conversion part may be provided in the control circuit part to convert ac power into dc power to supply to the motor, thereby realizing long-endurance washing.

The suction source 460 is provided at a position separate from the recovery storage part 400, and may be provided in the upper case 210 of the main body part 200, for example. Wherein the upper housing 210 and the frame body 220 may be detachably mounted or integrally formed. A power supply part 800 such as a rechargeable battery and a control circuit part 700 may also be accommodated in the upper case. In addition, a sound device 900 is provided on a side surface of the upper case 210, and the sound device 900 may be connected to the control circuit section 700 so as to emit a sound through the sound device 900 to prompt a user or the like.

Recovered liquid, gas and/or solids are drawn through the recovery conduit 440 and into the fourth chamber where solids (e.g., solid waste other than debris) will reside in the solids reservoir 431. Some or all of the liquid can flow into the first cavity through the liquid-conducting holes in the bottom wall 4311 and/or the first side wall 4312, and gas, liquid and/or vapor (and possibly also debris that is not filtered through the filter portion) will pass through the filter portion 433 into the third cavity, where the filter portion 433 functions to block solids and allow liquid and gas (possibly with some debris entrained) to pass through. In the third cavity, the gas and liquid are separated by the gas-liquid separator 422 so that the gas passes through and is discharged along the passage, leaving liquid (possibly with debris) in the third cavity (the liquid and/or small particle trash is thrown away in the third cavity by the rotation of the gas-liquid separator 422). In the parallel posture or the inclined use posture of the recovery storage part 400, the liquid of the third cavity may enter the second cavity through the hollow portion of the first surging-prevention part 435. And the first and second cavities may be in fluid communication through the liquid through-hole of the second surging prevention part 434, wherein the liquid of the third cavity may flow into the fourth cavity through the filtering part 433 and then flow into the first cavity from the fourth cavity in the upright posture or the inclined use posture of the recovery storage part 400.

The flow path of the gas is shown by arrows in fig. 22, where the gas enters the recovery conduit 440 from the inlet port 404, merges into the first chamber along the recovery conduit 440, then flows into the second chamber via the filtration part 433, is separated by the gas-liquid separator 422, and then is discharged from the gas outlet 408 through the gas channel.

The recovery conduit 440 (or its central axis) is disposed offset from the longitudinal central axis of the recovery storage 400 and may be parallel to the longitudinal central axis. It is provided that the recovery duct 440 is closer to the main body portion or closer to the cleaning liquid storage portion 300 than the longitudinal center axis in a posture of being mounted to the recovery storage portion 400. In the present disclosure, the recovery duct 440 may be positioned near the upper side of the recovery storage part 400 when the recovery storage part 400 is in the parallel posture, and in a case where the recovery storage part 400 is in the upright posture or the inclined use posture in another view, the recovery duct 440 may be positioned near the front side of the recovery storage part 400. Also, in alternative embodiments of the present disclosure, the recovery duct 440 may be fixed to the wall of the recovery storage part 400 or integrally formed with the wall. This prevents liquid from the recovery storage portion 400 from entering the recovery conduit 440 when the surface cleaning apparatus is in a parallel position (lying flat). The level of the liquid in the recovery storage portion 400 may also be made lower than the open end of the recovery conduit 440 to prevent the recovery liquid from entering the recovery conduit 440 when the surface cleaning apparatus is in an upright or inclined use attitude.

As shown in the enlarged part a of fig. 23, in order to prevent liquid or moisture or the like from leaking from the third chamber into the gas passage to deteriorate the gas-liquid separation effect, a labyrinth structure may be provided at a connecting portion of the third chamber and the gas passage, wherein the labyrinth structure may include a first baffle 451, a second baffle 452, and a third baffle 453, wherein the first baffle 451 may be disposed at an upstream position, the second baffle 452 may be disposed at a midstream position, and the third baffle 453 may be disposed at a downstream position in a direction from the third chamber to the gas passage. A first baffle 451 and a third baffle 453 may be provided on the support (or the wall thereof) of the recovery storage unit 400, and a second baffle 452 may be provided on the gas-liquid separator 422 (e.g., the casing of the gas-liquid separator 422). When the collecting and storing part 400 is in the parallel posture, the extending direction of the first flap 451 and the third flap 453 is downward, and the extending direction of the second flap 452 is upward. Thus, the first baffle 451, the second baffle 452, the third baffle 453, the support (or the wall) of the recovery storage part 400, and the housing of the gas-liquid separator 422 constitute a three-stage labyrinth structure, so that liquid, moisture, or the like can be prevented from entering the gas passage. In one embodiment of the present disclosure, the liquid level detection portion 405 may be used to detect the liquid level of the liquid in one or more postures in the recovery storage portion 400, for example, the liquid of the recovered liquid in at least one of a parallel posture, a self-supporting state, and a parallel posture and a self-supporting state may be detected.

The first threshold limit level of the level detection means is set to: when the recovery storage part is in a parallel posture, the liquid level is a first preset distance away from the gas-liquid separator, so that the recovery storage part is prevented from exceeding a first limit liquid level threshold value. Preferably, the height at which the first anti-surge portion is located or a height below the height is set as the first limit liquid level threshold value. Preferably, a height at or below which the lowest point of the first anti-surge portion is located is set as the first limit liquid level threshold value. The second limit level threshold of the level detection means is set to: when the recovery storage part is in a vertical posture parallel to the horizontal posture, the liquid level is a second preset distance away from the gas-liquid separator so as to prevent the recovery storage part from exceeding a second limit liquid level threshold value. Preferably, a height at which the second anti-surge portion is located or a height below the height is the second limit liquid level threshold value. The liquid level detection device comprises more than two liquid level detection parts, and at least two liquid level detection parts are arranged on the liquid level height of the first limit liquid level threshold; more preferably, the liquid level detection portion is arranged below the liquid level height of the first threshold limit liquid level. Optionally, the liquid level detection device includes more than two liquid level detection portions, and at least two liquid level detection portions are disposed on the liquid level height of the second limit liquid level threshold. Optionally, the liquid level detection device includes two or more second liquid level detection portions, and one or more liquid level detection portions are disposed at a liquid level height of the second limit liquid level threshold; more preferably, one or more second liquid level detection portions are provided below the liquid level height of the second limit liquid level threshold. Further, it is noted that the first liquid level detection section may be multiplexed with the second liquid level detection section. Through the setting of these first liquid level detection portion and second liquid level detection portion, can carry out accurate detection in corresponding gesture respectively to avoid shaking the detection interference that brings because of liquid.

Furthermore, in the case where the liquid level in the recovery storage portion 400 is obtained, it is also possible to control whether or not to interrupt the recovery system, thereby shutting down the surface cleaning apparatus or the like, in accordance with the detected liquid level. The liquid detection portion 405 may be any suitable detection device or element or the like. In the present disclosure, the liquid level detection part may be in the form of a sensor, for example, may be in the form of a metal probe sheet. The following description will take the example of a metal probe, but it will be understood by those skilled in the art that other detection means may be used.

The metal probe sheet may be provided on the inner side surface or the outer side surface of the recovery storage unit 400, and preferably may be provided on the outer side surface of the recovery storage unit 400. And it is more preferable in the present disclosure to dispose a metal probe sheet on a side surface of the recovery and storage section 400 facing the frame body. The number of the metal probe pieces may be set to two or other numbers, and the number of the metal probe pieces is selected so that the level of the recovered liquid can be detected at least in the upright posture and the parallel posture, and more preferably also in the inclined use posture.

According to an embodiment, as shown in fig. 24 and 25 (fig. 24 shows a schematic view of the recovery storage part 400 in an upright posture, fig. 25 shows a schematic view of the recovery storage part 400 in a parallel posture), four or more liquid level detection parts (metal probes) may be provided, and the four or more liquid level detection parts may be provided in a row-column manner, for example, in the case of four as shown in the drawing, the four liquid level detection parts may be provided in two rows and two columns. Although the arrangement is described here, it may be an irregular shape.

For example, when the liquid level of the recovered liquid is detected in the upright posture, the height of the liquid level can be obtained by the liquid level detection portions in the two rows. Of course, it will be appreciated by those skilled in the art that more level detection sections may be provided to achieve greater accuracy. For example, when the liquid level of the recovery storage unit 400 in the upright posture is measured, the liquid level measurement may be performed by a set of liquid level detection units arranged along the height direction of the recovery storage unit 400. Further, the uppermost liquid level detection means may be provided at a capacity threshold position of the recovery storage portion 400 to prevent liquid from exceeding the threshold height, and when the threshold height is reached, the surface cleaning apparatus may alarm to remind the user of the treatment.

When the liquid level of the recovered liquid is detected in a parallel posture, the height of the liquid level can be obtained by the two rows of liquid level detection parts. For example, when the liquid level of the recovery storage unit 400 in the upright posture is measured, the liquid level measurement may be performed by a set of liquid level detection units arranged along the thickness direction of the recovery storage unit 400. Alternatively, the uppermost liquid level detection means may be provided at a capacity threshold position of the recovery storage portion 400 to prevent liquid from exceeding the threshold height, and when the threshold height is reached, the surface cleaning apparatus may alarm to alert the user to the treatment. For example, the threshold height may be a height below the open end of the recovery conduit (whether in an upright, tilted use, or parallel position).

In addition, when the liquid level of the recovered liquid is detected in an inclined use posture, the detection may be performed by liquid level detection devices arranged in a line.

Furthermore, the fluid level detection means may also be used to detect whether the recovery storage portion 400 is present on the surface cleaning apparatus. For example, the liquid level detection device may cooperate with a sensing device disposed on the frame of the main body 200, e.g., in the presence of a mutual sensing signal, the recycling storage portion 400 is considered to be present on the surface cleaning apparatus.

Continuing with the example of the metal probe sheet, the metal probe sheet is disposed on a side surface of the recycling storage portion 400 facing the frame body, and a conductive sheet may be disposed on the frame body, and when the recycling storage portion 400 is mounted, the conductive sheet may supply power to the metal probe sheet, so that the metal probe sheet can detect the liquid level and/or the existence of the recycling storage portion 400. Although a metal probe and a conductive strip are illustrated, it should be understood that the two may take any other suitable form.

In addition, the liquid level detection unit and the detection unit for detecting the presence of the recovery storage unit 400 may be provided separately, that is, independent detection methods may be used for the two functions. In addition, two or more sets of detection units may be provided to realize two detection functions.

Further, as shown in fig. 26, an electric wire housing part 230 may be further provided in a space between the cleaning liquid storage part 300 and the recovery storage part 400. The electric wire accommodation portion 230 may be provided in the frame body 220, and may be fixed to the frame body 220, for example. The electric wire housing part 230 may extend from the entire height of the cleaning liquid storage part 300 and the recovery storage part 400, or from the lower ends of the cleaning liquid storage part 300 and the recovery storage part 400 to the vicinity of the control circuit part 700 and/or the power supply part 800.

The electric line accommodation part 230 may have a long bar shape having a groove, and a power supply line, a control line, and the like may be accommodated in the electric line accommodation part 230, thereby achieving electrical communication with the cleaning base 600.

In addition, as an alternative embodiment, a receiving portion in the form of a groove or the like may be provided on the frame body 220 as the electric wire receiving portion 230 described above. The conductive sheet may be provided on the electric wire housing part 230.

In the present disclosure, the detection portion of the liquid level detection device is near the rear of the surface cleaning apparatus relative to the recovery conduit. The detection portion of the liquid level detection device is one or more detection portions arranged from the outlet of the recovery conduit to the rear portion of the surface cleaning apparatus so as to be able to detect the liquid level of the recovered liquid of the recovery storage portion when in at least one of the intermediate postures of the parallel posture and the self-supporting posture. The detection unit communicates between the inside and the outside of the collection box, and may penetrate through a wall of the collection and storage unit, for example. As shown, the detection portion may include a first arrangement and a second arrangement, the first arrangement and the second arrangement being arranged along a longitudinal direction of the surface cleaning apparatus. Preferably, the first arrangement at least comprises a first probe point and a second probe point, the second arrangement at least comprises a third probe point and a fourth probe point, and the first probe point and the fourth probe point can be in electric communication with each other. When the probe is in a parallel posture, the first probe point is communicated with the third probe point or the second probe point is communicated with the fourth probe point; and when the device is in a vertical posture and/or a self-supporting posture, the first probe point is communicated with the second probe point or the third probe point is communicated with the fourth probe point.

As the surface cleaning apparatus performs a suction operation, a downstream located suction source 460 performs a suction operation, drawing gas from the exhaust port 408 and then out of the surface cleaning apparatus. Upstream of the suction source 460 is a recovery storage part 400, and a recovery duct 440 in the recovery storage part 400 receives recovered substances such as recovered liquid, gas, and solids sucked from the cleaning base 600 from an outlet 506, and the recovery duct 440 guides the recovered substances to the recovery storage part 400, the liquid and the solids remaining in the recovery storage part 400, and the gas being discharged from the gas outlet 408 through a gas passage by the gas-liquid separator 422. Furthermore, one or more additional filters can be arranged in the gas channel. For example, additional filters may be provided downstream of the suction source 460 and/or between upstream thereof and the recovery storage 400.

Figure 27 shows a schematic view of a cleaning base according to one embodiment of the present disclosure. Fig. 28 shows a schematic view of another angle of a cleaning base according to an embodiment of the present disclosure. Figure 29 shows a schematic internal structure of a cleaning base according to one embodiment of the present disclosure.

The surface cleaning apparatus of the present disclosure may include a cleaning base 600 as shown in fig. 27. The cleaning base 600 can be used as a cleaning component of a surface cleaning apparatus.

The cleaning base 600 according to an embodiment of the present disclosure, as shown in fig. 27 to 29, includes: a cleaning module 610, the cleaning module 610 comprising a cleaning surface that can be driven into surface contact with a surface to be cleaned; a fluid distribution module 620, the fluid distribution module 620 being used to provide a predetermined amount of cleaning liquid to the cleaning module 610 to provide the cleaning liquid to the surface to be cleaned by the movement of the cleaning surface of the cleaning module 610, so that the cleaning base 600 performs wet cleaning on the surface to be cleaned; and a soil suction module 630, the soil suction module 630 being provided with a negative pressure for collecting and sucking soil (e.g., dust and hair, etc.) after the cleaning module 610 cleans the surface to be cleaned into the soil suction module 630, thereby preventing the cleaning base 600 from leaving stains such as used cleaning liquid on the surface to be cleaned after cleaning the surface to be cleaned. Of course, the surface cleaning apparatus is also capable of dry cleaning a surface to be cleaned when the fluid dispensing module 620 is not providing cleaning liquid to the cleaning module 610.

As shown in fig. 29, the cleaning base 600 according to one embodiment of the present disclosure further includes: the connector module 640 is installed and the cleaning base 600 is attached to the main body portion 200 by attaching the connector module 640 to the attachment portion 500 to enable at least a portion of the cleaning module 610 of the cleaning base 600 to contact a surface to be cleaned when the surface cleaning apparatus is operated to effect cleaning of the surface to be cleaned.

As shown in fig. 27-29, the cleaning base 600 further includes a housing module 650, the mounting adapter module 640 being rotatably disposed in the housing module 650, the housing module 650 being formed to clean at least a portion of an outer surface of the base 600 and being capable of providing support for the cleaning module 610, the fluid distribution module 620, and the fluid distribution module 620 as described above.

Wherein the cleaning module 610 may be disposed at the front of the housing module 650 and received in the brush chamber formed by the housing module 650.

As shown in fig. 27-29, the cleaning base 600 further includes a moving wheel module 660, the moving wheel module 660 being coupled to the housing module 650, the moving wheel module 660 contacting and rolling on the surface to be cleaned when the surface cleaning apparatus is in operation to reduce the power required to move the surface cleaning apparatus and also to effectively prevent the cleaning base 600 from contaminating the surface that has been cleaned.

The cleaning base 600 of the present disclosure will be described in detail below with reference to the drawings.

Figure 30 shows a schematic structural view of a cleaning module according to one embodiment of the present disclosure. Figure 31 shows a schematic view of the cleaning module of figure 30 mounted to a housing module. Fig. 32 shows a schematic structural view of a cleaning module according to another embodiment of the present disclosure. Figure 33 shows a schematic view of the cleaning module of figure 32 mounted to a housing module.

As shown in fig. 30 to 33, the cleaning module 610 includes a cleaning part 611 and a cleaning driving device 612, and the cleaning driving device 612 is disposed on the housing module 650 and is used for driving the cleaning part 611 to rotate, so that the cleaning part 611 makes frictional contact with the surface to be cleaned, and the cleaning part 611 cleans the surface to be cleaned.

The cleaning part 611 includes: a first rotating part 6111 and a ring member 6112, wherein the cleaning driving device 612 is configured to drive the first rotating part 6111 to rotate, and when the first rotating part 6111 rotates, the ring member 6112 is driven to move, so that the ring member 6112 and the surface to be cleaned generate a relative motion, thereby cleaning the surface to be cleaned.

As shown in fig. 30 to 33, the cleaning driving device 612 is disposed outside the first rotating part 6111, but the cleaning driving device 612 may be disposed inside the first rotating part 6111, so that the cleaning base 600 has a smaller volume and thus a surface to be cleaned that can be adapted to wash a smaller space.

The cleaning driving device 612 may be a motor, such as a dc motor, a stepping motor, etc., and the dc motor is preferably a dc brushless motor. When the cleaning driving device 612 is located outside the first rotating part 6111, as shown in fig. 30 to 33, the cleaning driving device 612 is connected to the first rotating part 6111 through the transmission assembly 613, and transmits the power generated by the cleaning driving device 612 to the first rotating part 6111, so that the first rotating part 6111 rotates. The transmission assembly 613 may be a belt transmission assembly, a chain transmission assembly, a gear transmission assembly, etc., and in the present disclosure, the belt transmission assembly is preferably a synchronous belt transmission assembly.

Specifically, the cleaning driving device 612 is fixed to the housing module 650, for example, a mounting portion 651 of the housing module 650, the cleaning driving device 612 is mounted with a driving timing pulley, and the driving timing pulley and the cleaning driving device 612 are respectively located at two sides of the mounting portion 651, that is, the cleaning driving device 612 is located at the inner side of the mounting portion 651, and the driving timing pulley is located at the outer side of the mounting portion 651; wherein the mounting portion 651 is formed extending forwardly from the housing module 650.

The housing module 650 is formed with a receiving portion (brush chamber), and the endless belt type cleaning device is provided to the bracket portion 618, and is located in the receiving portion of the housing module 650 when the bracket portion 618 is mounted to the housing module 650; when the holder portion is detached from the housing module, the endless belt cleaning device is detached from the housing module.

Of course, the mounting portion 651 may be formed separately from the housing module 650 and fixed to the housing module 650, or detachably provided to the housing module 650, so that the cleaning module 610 can be more conveniently detached. One end of the first rotating part 6111 is rotatably disposed on the housing module 650, for example, rotatably disposed on a mounting part 651 of the housing module 650, and the cleaning driving device 612 drives the first rotating part 6111 to rotate through a transmission shaft 614 described below.

In the present disclosure, the cleaning module 610 further includes a transmission shaft 614, and the transmission shaft 614 is rotatably disposed on the housing module 650, for example, rotatably disposed on the mounting portion 651 of the housing module 650. One end of the transmission shaft 614 is provided with a transmission member such as a driven synchronous pulley, and the driven synchronous pulley is in transmission connection with the driving synchronous pulley. Of course, the driving synchronous pulley and the driven synchronous pulley can be replaced by gears, chain wheels, pulleys and the like, and the technical knowledge of the skilled person in the art can be used for completing the operation, and the detailed description of the disclosure is omitted.

The other end of the transmission shaft 614 is inserted into the first rotating part 6111 and is in transmission connection with the first rotating part 6111; on one hand, the transmission shaft 614 can be directly connected to the first rotating part 6111, and the transmission shaft 614 and the first rotating part 6111 rotate at the same speed; of course, the transmission shaft 614 can also be indirectly connected to the first rotating portion 6111 through the speed changing device 615, the speed changing device 615 can be formed as a part of the cleaning driving device 612, or the cleaning driving device 612 can include the speed changing device 615, in which case, preferably, the housing of the speed changing device 615 can be fixed with the mounting portion 651, and the rotation speed of the transmission shaft 614 is greater than that of the first rotating portion 6111; more preferably, the transmission shaft 614 may also be a part of the cleaning driving device 612, i.e. the cleaning driving device 612 may also comprise the transmission shaft 614.

When the transmission shaft 614 is directly connected to the first rotation part 6111, the other end of the transmission shaft 614 is connected with the first driving connection member 616, the first driving connection member 616 includes at least one key part, for example, the first driving connection member 616 may be formed as a spline shaft; accordingly, the second driving connecting member 617 is fixed inside the first rotating portion 6111, the second driving connecting member 617 is formed with a groove portion to be engaged with the first driving connecting member 616, and the first driving connecting member 616 drives the second driving connecting member 617 to rotate when the key portion of the first driving connecting member 616 is inserted into the groove portion of the second driving connecting member 617.

Of course, correspondingly, first drive linkage 616 may be formed with a slot, in which case second drive linkage 617 includes at least one key, and the driving connection of first drive linkage 616 and second drive linkage 617 is achieved by the mating of the key of second drive linkage 617 with the slot of first drive linkage 616.

The other end of the first rotating portion 6111 is rotatably disposed at the bracket portion 618, wherein the bracket portion 618 is connected to the housing module 650, and preferably, the bracket portion 618 is detachably connected to the housing module 650, so that the cleaning module 610 can be maintained or cleaned when the bracket portion 618 is detached from the housing module 650. In particular, the cradle portion includes a mechanical connector corresponding to the housing module, which is simultaneously aligned with a mating connector of the housing module when the cradle portion is accessed into the housing module mated therewith. And the bracket portion 618 is connected to at least the first rotating portion, and when the bracket portion is mounted to the housing module, at least a portion of the cleaning drive device slides into the first rotating portion; more specifically, when the bracket portion is mounted to the housing module, the transmission slides into the first rotating portion cavity and mechanically couples the transmission and the first rotating portion.

As shown in fig. 30 and 31, when the cleaning module 610 includes only the first rotating part 6111 and the ring 6112 disposed outside the first rotating part 6111, the cleaning module 610 is formed in the form of a roll brush. As shown in fig. 32 and 33, the cleaning module 610 may also be formed in the form of an endless belt type cleaning device, in which case the cleaning module 610 further includes a second rotating part 6113, the second rotating part 6113 is disposed in parallel with the first rotating part 6111, and one end of the second rotating part 6113 is also rotatably disposed at the housing module 650.

The ring-shaped member 6112 is disposed to wrap the first rotating portion 6111 and the second rotating portion 6113, and the ring-shaped member 6112 located below the first rotating portion 6111 and the second rotating portion 6113 is brought into contact with the surface to be cleaned.

The outer diameters of the first rotating portion 6111 and the second rotating portion 6113 may be the same or different. When the outer diameters of the first rotating portion 6111 and the second rotating portion 6113 are different, the diameter of the first rotating portion 6111 is preferably larger than the diameter of the second rotating portion 6113.

The cleaning surface is located on the ring-shaped member 6112, and the ring-shaped member is used for power transmission between the first rotating portion 6111 and the second rotating portion 6113.

The second rotating part 6113 is arranged in front of the first rotating part 6111 by taking the moving direction of the surface cleaning device for cleaning the surface to be cleaned as the front direction, namely, the first rotating part 6111 is close to the rear side of the cleaning module, and the second rotating part 6113 is close to the front side of the cleaning module; of course, the second rotating portion 6113 may be disposed behind the first rotating portion 6111, and a person skilled in the art may adjust the position of the second rotating portion 6113 according to his or her knowledge.

As shown in fig. 32 and 33, further, the other end of the second rotating portion 6113 is also rotatably provided to the bracket portion 618, so that the first rotating portion 6111 and the second rotating portion 6113 are rotatably supported by the bracket portion 618. Here, when the cleaning module 610 includes the first rotating part 6111 and the second rotating part 6113, that is, the cleaning module 610 is formed as an endless belt type cleaning apparatus, the endless member 6112 is formed as a flexible endless belt portion.

Fig. 34 shows a schematic structural view of a cleaning module 610 according to another embodiment of the present disclosure. As shown in fig. 34, the cleaning driving device 612 may be disposed inside the first rotating portion 6111, in which one end of the first rotating portion 6111 is rotatably disposed on the housing module 650, for example, the mounting portion 651 of the housing module 650; the other end of the first rotating portion 6111 is rotatably disposed on the bracket portion 618.

Accordingly, when the cleaning driving device 612 is located inside the first rotation portion 6111, since there is no transmission member such as a timing belt, the edgewise distance of the cleaning base 600 is reduced to be smaller. For example, as shown in fig. 34, the value of the edgewise cleaning distance X depends only on the thickness of the bracket portion 618, and the value of the edgewise cleaning distance Y depends only on the thickness of the mounting portion 651, so that it is not necessary to mount a timing belt, and it is prevented that the mounting of a wide timing belt deteriorates the welting performance.

The cleaning drive 612 is fixed to the mounting portion 651, and the speed change device 615 may be connected to the cleaning drive 612, but the speed change device 615 may not be used when the cleaning drive 612 is selected to be a speed reduction motor, and the power of the cleaning drive 612 is directly transmitted to the first drive connecting member 616.

The transmission 615 is connected to the first drive connection 616 to transmit drive to the first drive connection; furthermore, the first driving connecting member 616 is in transmission connection with the second driving connecting member 617, and when the second driving connecting member 617 is fixed with the first rotating portion 6111, a driving force can be provided to the first rotating portion 6111, so that the first rotating portion 6111 can be rotated.

On the other hand, the first support 6191 is disposed inside the other end of the first rotating portion 6111, for example, the inner wall surface of the first rotating portion 6111 is fixed to the outer wall surface of the first support 6191. Inside the first support 6191, a second support 6192 is provided, said second support 6192 being detachable with respect to the first support 6191, i.e. the second support 6192 can be removed from the first support 6191.

The support portion 6193 is fixed to the second support member 6192 through the bracket portion 618, and a bearing is disposed between the support portion 6193 and the bracket portion 618, so that the support portion 6193 is rotatably supported on the bracket portion 618 through the bearing, and the first rotating portion 6111 can rotate relative to the bracket portion 618.

With a similar structure, both ends of the second rotating portion 6111 can be rotatably disposed at the bracket portion 618 and the mounting portion 651, respectively, and will not be described in detail herein.

Fig. 35 illustrates a schematic structural view of a first rotating part according to an embodiment of the present disclosure. FIG. 36 shows a schematic representation of a ring according to one embodiment of the present disclosure. In order to prevent the ring-shaped member 6112 from being detached from the first rotating portion 6111 and/or the second rotating portion 6113, as shown in fig. 35, at least one end of the first rotating portion 6111 and/or the second rotating portion 6113 is formed with an outer flange portion 6111A, and preferably, both ends of the first rotating portion 6111 and/or the second rotating portion 6113 are formed with outer flange portions 6111A, thereby confining the ring-shaped member 6112 between the two outer flange portions 6111A.

In order to prevent the ring 6112 from slipping on the first rotating portion 6111 and/or the second rotating portion 6113, as shown in fig. 35, an external tooth portion 6111B is formed on the circumferential surface of at least one of the first rotating portion 6111 and/or the second rotating portion 6113; accordingly, the inner circumferential surface of the ring member 6112 is formed with inner teeth, so that slipping of the ring member 6112 is effectively prevented by cooperation of the outer teeth 6111B and the inner teeth, and efficiency of cleaning the surface to be cleaned is improved.

Moreover, in consideration of the large length of the first rotating portion 6111 and/or the second rotating portion 6113, in order to prevent the flexible annular belt portion from being folded, etc., as shown in fig. 35, at least one annular groove 6111C is formed on the outer circumferential surface of the first rotating portion 6111 and/or the second rotating portion 6113 to divide the first rotating portion 6111 and the second rotating portion 6113 into a plurality of portions in the axial direction by the annular groove 6111C.

Further, as shown in fig. 35, at least one of both sides of the annular groove 6111C is provided with an annular projection 6111D, more preferably, both sides of the annular groove 6111C are provided with annular projections 6111D, wherein an internal tooth portion is formed in a region between the two annular grooves 6111C and a region between the annular groove 6111C and the outer flange portion 6111A.

Accordingly, corresponding to portions of the annular groove 6111C and the annular protrusion 6111D, the inner surface of the ring member 6112 forms an annular protrusion 6111D and an annular groove 6111C, such that the annular protrusion 6111D of the ring member 6112 is engaged with the annular groove 6111C of the first rotating portion 6111 and/or the second rotating portion 6113, and such that the annular groove 6111C of the ring member 6112 is engaged with the annular protrusion 6111D of the first rotating portion 6111 and/or the second rotating portion 6113.

Fig. 37 illustrates a structural schematic view of a first rotating part 6111 according to another embodiment of the present disclosure. Fig. 38 shows a schematic structural view of a ring 6112 according to another embodiment of the present disclosure. In the disclosure, in another case, a soft rubber layer 6111E is disposed in an area between the two annular grooves 6111C and/or between the annular groove 6111C and the outer flange 6111A, so that friction between the first rotating portion 6111 and the annular member 6112 is increased through the soft rubber layer 6111E, and relative sliding between the annular member 6112 and the first rotating portion 6111 is prevented. More preferably, the soft rubber layer 6111E may be made of a natural or synthetic rubber, such as Ethylene Propylene Diene Monomer (EPDM) or nitrile rubber, or a soft material such as silicone. On the other hand, the soft rubber layer 6111E may also be provided with an external tooth portion 6111B, so that the relative sliding between the first rotating portion 6111 and the ring-shaped member 6112 is further prevented by the soft rubber layer 6111E with the external tooth portion 6111B.

Fig. 39 shows a cross-sectional schematic of fig. 37. Fig. 40 shows a cross-sectional schematic of fig. 38. As shown in fig. 39 and 40, the radial dimension of the outer flange portions 6111A at the two ends of the first rotating portion 6111 and/or the second rotating portion 6113 of the present disclosure is smaller than the thickness of the ring member 6112, so that when the cleaning module 610 performs a cleaning operation, the outer flange portions 6111A of the first rotating portion 6111 and/or the second rotating portion 6113 do not contact the surface to be cleaned, damage to the surface to be cleaned by the first rotating portion 6111 and/or the second rotating portion 6113 is effectively prevented, and the cleaning effect is also improved.

Considering that the structure of the second rotating portion 6113 of the present disclosure is similar to that of the first rotating portion 6111, a person skilled in the art can know the structure of the second rotating portion 6113 according to the structure of the first rotating portion 6111, and an illustration of the second rotating portion 6113 is not provided based on this disclosure.

FIG. 41 shows a schematic diagram of a process for making an annular part according to one embodiment of the present disclosure. In the present disclosure, the ring 6112 is an important part of the cleaning work, and the flexible ring belt portion is in direct contact with the surface to be cleaned when the surface cleaning apparatus is used for the cleaning work. Preferably, the ring member 6112 includes a cleaning body 6112A and a base material 6112B, the cleaning body 6112A is similar to the cleaning body 6112A of a common floor brush, and a floss material such as a cleaning cloth can be selected. The base material 6112B is generally a flexible soft material, and the cleaning body 6112A can be fixed on the base material 6112B by gluing, sewing or the like, so that the whole ring-shaped member 6112 is attached around the first rotating portion 6111, or attached around the first rotating portion 6111 and the second rotating portion 6113 which are parallel to each other.

In view of the particularity of the ring-shaped member 6112 of the present disclosure, the present disclosure provides a method for manufacturing the ring-shaped member 6112, which includes: s601, preparing a base material 6112B using a flexible material, wherein the base material 6112B has a ring-shaped cross section. The flexible material for preparing the base material 6112B may be rubber, fiber cloth, or the like, so that the ring 6112 can have an effect similar to a conveyor belt. S602, the base material 6112B is tensioned by at least two tension rollers, and an adhesive is applied to the outer circumferential surface of the base material 6112B. In the present disclosure, at least one of the tension rollers may be driven to be rotatable so that the base material 6112B moves on the tension roller, thereby enabling convenient application of an adhesive on the outer surface of the base material 6112B. S603, applying an adhesive on one surface of the cleaning body 6112A, placing the cleaning body 6112A on the base material 6112B, and removing the base material 6112B from the tension roller after the adhesive is cured, so as to obtain the ring-shaped member 6112.

One skilled in the art will appreciate that after the adhesive is applied to the outer surface of the tension roll, the adhesive may not be applied to the surface of the cleaning body 6112A. Alternatively, the adhesive may be applied only to the outer peripheral surface of the tension roller and one surface of the cleaning body 6112A. However, in order to provide the ring-shaped member 6112 with a better cleaning effect, the ring-shaped member 6112 of the present disclosure has an adhesive applied to both the outer circumferential surface of the tension roller and the surface of the ring-shaped member 6112 during the manufacturing process.

More preferably, in order to improve the service life of the ring 6112 and prevent the separation between the base material 6112B and the ring 6112 of the ring 6112, the circumferential direction of at least one end of the ring 6112 in the present disclosure is sewn by a sewing line 6112C, that is, at least one end of the cleaning body and at least one open end of the base material are fixed again, so that when the ring 6112 in the present disclosure is used, the currently conventional manner of pressing the end cap can be avoided, thereby reducing the cleaning-to-edge distance of the cleaning body 6112A. More preferably, both ends of the cleaning body 6112A are sewn by a sewing thread 6112C.

FIG. 42 shows a schematic view of an annular part prepared according to one embodiment of the present disclosure. FIG. 43 shows a schematic cross-sectional view of an annular member according to one embodiment of the present disclosure. FIG. 44 illustrates a schematic cross-sectional view of an annular member according to another embodiment of the present disclosure. As shown in fig. 42 and 43, in order to prevent the thread ends of the sutures 6112C on both sides from causing the protrusion of the ring 6112 when the ring 6112 is mounted to the first rotating part 6111 or the second rotating part 6113, thereby increasing the risk that the flexible annular belt portion falls off from the first rotating part 6111 or the second rotating part 6113, in the present disclosure, grooves may be formed on the outer circumferential surfaces of the first rotating part 6111 and the second rotating part 6113 at positions opposite to the sutures 6112C to accommodate the thread ends of the sutures 6112C and the sutures 6112C through the grooves; accordingly, when the grooves are formed at the first and

second turning parts

6111 and 6113, the grooves on the first and

second turning parts

6111 and 6113 are annular mounting grooves.

Further, as shown in fig. 44, a groove may be formed in the inner peripheral surface of the base material 6112B so that the sewing thread 6112C is positioned in the groove; more preferably, when the groove is formed on the inner peripheral surface of the base material 6112B, the groove may be formed as an annular mounting groove, or may not be formed, for example, the groove formed on the base material 6112B is formed in the shape of a blind hole to accommodate the joint of the suture 6112C through the blind hole.

The following describes a schematic view of the detachable endless belt cleaning assembly of the present disclosure with reference to the accompanying drawings. FIG. 45 shows a schematic view of a removable endless belt cleaning assembly, according to one embodiment of the present disclosure. FIG. 46 shows a schematic view of another angle of a detachable endless belt cleaning assembly according to one embodiment of the present disclosure.

When the cleaning module 610 is a roller brush, the roller brush can be detached by detaching the first rotating portion 6111 of the roller brush.

As for the endless belt type cleaning apparatus, as shown in fig. 45 and 46, the present disclosure further includes a detachable endless belt cleaning assembly including: a bracket portion 618, the bracket portion 618 being detachably disposed on the housing module 650; and an endless belt type cleaning device which is provided to the bracket portion 618 and which is detached from the housing module 650 when the bracket portion 618 is detached from the housing module 650.

Wherein, endless belt formula cleaning device includes: the flexible annular belt part is driven to move by the rotating shaft assembly so as to clean the surface to be cleaned through the flexible annular belt part.

The effect of the removable annular belt cleaning assembly being removed from the housing module 650 can be seen by reference to figures 45 and 46.

The cleaning driving device 612 is used for driving the rotation of the rotating shaft assembly, wherein the cleaning driving device 612 is arranged outside the rotating shaft assembly, of course, the cleaning driving device 612 can also be arranged inside the rotating shaft assembly, thereby enabling the cleaning base 600 to have a smaller volume, and therefore, the cleaning base 600 can be adapted to clean the surface to be cleaned in a smaller space. The rotating shaft assembly includes a first rotating part 6111 and a second rotating part 6113, and the structures and the position relationships of the first rotating part 6111 and the second rotating part 6113 are described above and are not described in detail herein.

And for conveniently mounting the detachable endless belt cleaning assembly to the housing module 650, the mounting portion 651 is provided with a first support bearing and a second support bearing, for example, an inner ring of the first support bearing is disposed on the mounting portion 651, preferably, the first support bearing may be disposed on the transmission shaft 614, for example, an inner ring of the first support bearing may be sleeved and fixed on the transmission shaft 614, so that when the detachable endless belt cleaning assembly is mounted to the housing module 650, one end of the first rotating portion 6111 of the rotating shaft assembly may be rotatably supported on the first support bearing, for example, an inner wall surface of one end of the first rotating portion 6111 may be detachably disposed on an outer ring of the first support bearing, or an inner wall surface of one end of the first rotating portion 6111 may be slidably disposed on an outer ring of the first support bearing.

Similarly, an inner ring of the second support bearing is provided to the mounting portion 651, and preferably, the inner ring of the second support bearing may be fixed to the mounting portion 651, and when the detachable endless belt cleaning assembly is mounted to the housing module 650, one end of the second rotator 6113 may be rotatably supported at the second support bearing; for example, an inner wall surface of one end of the second rotating portion 6113 is provided in the outer ring of the second support bearing, or the inner wall surface of one end of the second rotating portion 6113 is slidably provided in the outer ring of the second support bearing.

Figure 47 shows a schematic view of a flexible annular band portion being detached, according to an embodiment of the present disclosure. As shown in fig. 47, when the detachable endless belt cleaning assembly is detached from the housing module 650, the flexible endless belt portion can be detached from the first and

second turning portions

6111, 6113 for easy cleaning or replacement.

Fig. 48 illustrates a schematic view in which the first and

second turning parts

6111 and 6113 are detached according to an embodiment of the present disclosure. As shown in fig. 48, at least one of the first rotating portion 6111 and the second rotating portion 6113 may be detachable from the bracket portion 618 to prevent hairs from existing between the bracket portion 618 and the rotating shaft assembly, thereby facilitating the user's cleaning.

Correspondingly, a third support bearing and a fourth support bearing are disposed on the bracket portion 618, for example, an inner ring of the third support bearing is disposed on the bracket portion 618, and the other end of the first rotating portion 6111 of the rotating shaft assembly is rotatably supported on the third support bearing, for example, an inner wall surface of the other end of the first rotating portion 6111 is detachably disposed on an outer ring of the third support bearing, or an inner wall surface of the other end of the first rotating portion 6111 is slidably disposed on an outer ring of the third support bearing.

Similarly, an inner ring of the fourth support bearing is disposed on the bracket portion 618, and preferably, the inner ring of the fourth support bearing may be fixed to the bracket portion 618, and the other end of the second rotation portion 6113 is rotatably supported by the fourth support bearing; for example, the inner wall surface of the other end of the second rotating portion 6113 is disposed on the outer ring of the fourth support bearing, or the inner wall surface of the other end of the second rotating portion 6113 is slidably disposed on the outer ring of the fourth support bearing.

Fig. 49 illustrates a schematic view in which a first rotating part and a second rotating part are installed according to one embodiment of the present disclosure. As shown in fig. 49, when the detachable endless belt cleaning assembly is mounted to the housing module 650, considering that the flexible endless belt portion is under tension, the first and second

rotating portions

6111 and 6113 may approach each other under the force applied by the flexible endless belt portion, resulting in the first and second

rotating portions

6111 and 6113 not being properly aligned with the first and second support bearings, and the first and second

rotating portions

6111 and 6113 needing to maintain interference fits with the first and second support bearings, respectively, all of which cause difficulty in mounting, and the user experiences a poor experience when washing the replacement endless belt and when mounting and dismounting the entire cleaning endless belt assembly.

Fig. 50 shows a schematic view of a cage installation location according to an embodiment of the present disclosure. Fig. 51 shows a schematic view of a cage in a disengaged state according to an embodiment of the present disclosure. At this time, as shown in fig. 50 and 51, the detachable endless belt cleaning assembly further includes a holder 6114, and the holder 6114 is provided to the first rotating part 6111 and the second rotating part 6113, for defining positions of the first rotating part 6111 and the second rotating part 6113, to prevent the first rotating part 6111 and the second rotating part 6113 from approaching each other.

Preferably, the number of the retainers 6114 is at least one, and when the number of the retainers 6114 is one, the retainers 6114 are arranged at one ends of the first rotating part 6111 and the second rotating part 6113 far away from the bracket part 618; when the number of the holders 6114 is set to two, the holders 6114 may be provided at both ends of the first rotating portion 6111 and the second rotating portion 6113. That is, in the present disclosure, the flexible annular belt portion can be made into a consumable material, and a holder 6114 is installed on the other side of the support portion 618, so that the first rotating portion 6111 and the second rotating portion 6113 are prevented from approaching each other due to the tensioning action of the flexible annular belt portion, and the whole detachable annular belt cleaning assembly can be easily mounted to the surface cleaning apparatus.

The cost of consumable materials made of the whole detachable annular belt cleaning assembly is too high, so that the flexible annular belt portion and the retainer 6114 can be considered as consumable materials, and the retainer 6114 is respectively installed on two sides of the cleaning annular belt, so that the assembly and replacement of a user are more convenient and the cost is lower.

Fig. 52 shows a schematic view of a ring 6112 according to one embodiment of the present disclosure. As shown in fig. 52, the circumferential length of the outer circumferential surface of the ring-shaped member 6112 of the present disclosure is 20cm or more, whereby the problem of hair entanglement in most use environments can be effectively solved. That is, since most of the dropped hair in the home environment has a length of 20cm or less, when the circumference of the outer circumferential surface of the ring-shaped member 6112 is set to 20cm or more, the hair cannot be wound around the ring-shaped member 6112 by one turn, and thus, when the ring-shaped member 6112 is moved, dirty things such as hair are scraped off by the blades and enter the dirty water storage portion via the dirty suction module 630.

Fig. 53 shows a schematic view of a cleaning base 600 in cleaning a surface to be cleaned according to one embodiment of the present disclosure. As shown in fig. 53, when the cleaning base 600 is used to clean a surface to be cleaned, the speed for pushing the surface cleaning apparatus to advance on the surface to be cleaned is about 0.5m/s, and if the linear velocity of the ring 6112 is less than 0.5m/s, a certain relative speed with the surface to be cleaned may not be formed, so that the cleaning base 600 cannot clean the same position at least once during the process of pushing and pulling the surface cleaning apparatus.

However, when the linear velocity of the surface of the flexible endless belt portion which is in contact with the surface to be cleaned is 0.5m/s or more (the direction of the linear velocity is backward), it can be ensured that the surface cleaning apparatus cleans a predetermined area of the surface to be cleaned at least once during use.

Fig. 54 shows a schematic structural view of a cleaning base 600 according to another embodiment of the present disclosure. Fig. 55 shows a schematic view of another angle of a cleaning base 600 according to another embodiment of the present disclosure. Fig. 56 shows an internal structural view of a cleaning base 600 according to another embodiment of the present disclosure. The moving wheel module 660 is disposed at the housing module 650 such that the lowest point of the moving wheel module 660 is located below the lowest point of the housing module 650, such that when the surface cleaning apparatus is in operation, the moving wheel module 660 contacts and rolls on the surface to be cleaned, thereby reducing the power required by the surface cleaning apparatus when moving; the moving wheel module 660 is located at the rear side of the housing module 650 to be able to effectively prevent the cleaning base 600 from contaminating the surface after cleaning has been performed.

In one aspect, as shown in fig. 27-29, the moving wheel module 660 is integrally formed with the housing module 650, i.e., the moving wheel module 660 includes: moving wheel frames 661 and moving wheels 662; wherein, the movable wheel frame 661 is integrally formed with the housing module 650 and is located at the rear side of the housing module 650; the moving wheel 662 is rotatably disposed on the moving wheel frame 661. In the present disclosure, the moving wheel frame 661 includes two mounting members 6611, and the number of the moving wheels 662 is two, that is, one moving wheel 662 is mounted on each mounting member 6611, wherein the two mounting members 6611 are located between the two moving wheels 662, or the two moving wheels 662 are located outside the two mounting members 6611. Of course, one skilled in the art will recognize that the moving wheels 662 may also be disposed inboard of the mounts 6611.

On the other hand, as shown in fig. 54 to 56, the moving wheel module 660 includes a moving wheel frame 661 and a moving wheel 662. Wherein the moving wheel housing 661 is formed separately from the case module 650, and the case module 650 is connected to the moving wheel housing 661 such that the case module 650 can move with respect to the moving wheel housing 661. For example, the housing module 650 has at least one degree of rotational freedom with respect to the moving wheel frame 661, and preferably, the housing module 650 has two degrees of rotational freedom with respect to the moving wheel frame 661, i.e., a pitch degree of freedom (Y-axis) and a roll degree of freedom (X-axis).

The following describes the moving wheel holder 661 in detail with reference to the accompanying drawings. As shown in fig. 55, the moving wheel frame 661 includes two mounting members 6611 and a connecting member 6612 connecting the two mounting members 6611.

Wherein the number of moving wheels 662 is two, i.e. one moving wheel 662 is mounted on each mounting 6611, wherein two mounting members 6611 are located between two moving wheels 662 or, in other words, two moving wheels 662 are located outside two mounting members 6611. Of course, those skilled in the art will appreciate that the moving wheels 662 may also be disposed inboard of the mounts 6611.

The housing module 650 is formed with a connection neck portion 652, and in the present disclosure, an axis of the connection neck portion 652 is disposed in a front-rear direction, a rotation ring 663 is disposed at an outer portion of the connection neck portion 652, and the connection neck portion 652 is allowed to rotate within the rotation ring 663, so that the housing module 650 has a tumbling degree of freedom. Also, the rotating ring 663 is rotatably provided to the connecting portion 6612, wherein the axis of rotation of the rotating ring 663 with respect to the connecting portion 6612 is parallel to the axis of rotation of the moving wheel 662 and is not collinear, so that the housing module 650 has a degree of freedom in pitch.

When the cleaning base 600 is used, since the area to be cleaned by the flexible annular band portion is large, if the unevenness of the ground at home is encountered, one surface is determined by three points, which inevitably results in the moving wheel 662 or the flexible annular band portion not being able to contact the ground at the same time, if only one end of the flexible annular band portion is contacted with the ground, the other end inevitably is not able to well contact the ground, resulting in an unsatisfactory cleaning effect.

However, the housing module 650 and the moving wheel module 660 of the present disclosure are connected in a hinged manner, so that relative floating is formed between the housing module 650 and the moving wheel module 660, and thus the housing module adapts to uneven ground, the flexible annular belt portion is ensured to be in effective contact with the surface to be cleaned, and the cleaning effect is ensured.

As shown in fig. 27-29, the cleaning base 600 is mounted to a connection portion of the surface cleaning apparatus, e.g., detachably mounted to a main body portion of the surface cleaning apparatus, by a mounting adapter module 640 to enable at least a portion of the cleaning base 600 to contact a surface to be cleaned when the surface cleaning apparatus is operated and to enable cleaning of the surface to be cleaned when the cleaning base 600 is moved along a preset path.

The field joint module 640 is rotatably disposed to the housing module 650 to enable a predetermined angle to be formed between the surface cleaning apparatus and the cleaning base 600, for example: when the surface cleaning apparatus is in the inoperative condition, the surface cleaning apparatus is at an angle of approximately 90 ° to the housing module 650 of the cleaning base 600, with the surface cleaning apparatus in an upright condition; when the surface cleaning apparatus is in an operational state, the angle between the surface cleaning apparatus and the housing module 650 of the cleaning base 600 is 120 ° or more, even the angle between the surface cleaning apparatus and the housing module 650 may be 180 °, i.e. both the surface cleaning apparatus and the housing module 650 are parallel to the surface to be cleaned, so that the surface cleaning apparatus of the present disclosure can clean the surface to be cleaned under a sofa as well as the surface to be cleaned under a bed, etc.

Fig. 57 and 59 show exploded schematic views of a cleaning base 600 according to one embodiment of the present disclosure. Fig. 58 shows a schematic view of another angle of a cleaning base 600 according to an embodiment of the present disclosure. Fig. 60 shows a schematic view of another angle of a cleaning base 600 according to an embodiment of the present disclosure. As shown in fig. 57-60, the fluid distribution module 620 of the cleaning base 600 of the present disclosure is disposed at a housing module 650 for providing cleaning liquid to the cleaning module 610, for example, to an endless belt cleaning device to enable wet cleaning of a surface to be cleaned by the endless belt cleaning device.

The fluid distribution module 620 comprises a flow control part 621 and a fluid distributor 622, wherein the flow control part 621 is connected to the cleaning liquid storage part of the surface cleaning apparatus through a first liquid supply pipeline, and is used for supplying the cleaning liquid stored in the cleaning liquid storage part of the surface cleaning apparatus to the fluid distributor 622 through the flow control part 621.

The flow control part 621 is connected to the fluid distributor 622 through the second liquid supply line to uniformly supply the cleaning liquid to the surface of the endless belt type cleaning device and maintain the endless belt type cleaning device in a wet state to be applied to the surface to be cleaned by the endless belt type cleaning device, thereby improving the cleaning quality.

When the flow control portion 621 is directly connected to the fluid distributor 622, the second fluid supply line may not be used; when a heating device is provided between the flow rate control portion 621 and the fluid distributor 622, the flow rate control portion 621 and the fluid distributor 622 are connected using a second liquid supply line, and at this time, the heating device is provided on the second liquid supply line.

In the present disclosure, the flow control portion 621 may be selected as a water pump, preferably a peristaltic pump, so as to better prevent liquid leakage by the peristaltic pump and more precisely control the flow provided to the fluid dispenser 622, and a valve such as a check valve is not required.

Wherein the flow control portion 621 is disposed at the housing module 650 and may be located inside the housing module 650, and the fluid distributor 622 is also disposed at the housing module 650 and is located at the cleaning module 610, for example, at the rear side of the endless belt type cleaning apparatus.

In the present disclosure, the fluid distributor 622 is a labyrinth fluid distributor 622 so that the cleaning liquid is uniformly distributed on the surface of the endless belt type cleaning apparatus. The cleaning base 600 further comprises an upper housing 670, the upper housing 670 being provided to the housing module 650 and forming a part of the outer surface of the cleaning base 600 and at least partially covering the cleaning assembly; for example, the upper housing 670 may be detachably disposed to the housing module 650, and preferably, a rear portion of the upper housing 670 may be detachably disposed to the housing module 650, and a front portion of the upper housing 670 may be positioned above the ring 6112 and may at least partially cover the ring 6112.

As shown in fig. 64, the fluid dispenser 622 may include one or more water outlets, which may be formed in a housing module 650 or in an upper housing 670. In one implementation, the plurality of water outlets form a single row of formations.

The cleaning liquid flowing out to the surface of the ring 6112 through the water outlet is uniformly distributed on the surface of the ring 6112 after passing through the brush plate part 671.

Wherein the wiper portion 671 is disposed on the upper housing 670 or is integrally formed with the upper housing 670, in one implementation, the wiper portion 671 extends along a length direction of the cleaning module, and both ends of the wiper portion 671 are not shorter than both ends of the ring member.

More preferably, the brash portion 671 is located on a downstream side of the fluid distributor 622 in a direction of movement of the ring of the cleaning module, such that when the fluid distributor 622 supplies cleaning liquid to the ring of the cleaning module, the cleaning liquid is more evenly distributed on the surface of the ring 6112 by the brash portion 671, and at this time, the brash portion 671 is in contact with the surface of the ring.

The fluid distributor 622 may be mounted to the upper housing 670 or the fluid distributor 622 may be integrally formed with the upper housing 670 to provide cleaning liquid to the outer surface of the rear portion of the ring 6112 and apply the cleaning liquid to the surface to be cleaned as the ring 6112 moves.

The fluid distributor 622 has a predetermined interval with the surface of the endless belt type cleaning device, wherein the predetermined interval may be different according to the pressure of the cleaning liquid outputted from the flow control portion 621, for example, when the pressure of the cleaning liquid outputted from the flow control portion 621 is large, the predetermined interval is also large, and accordingly, when the pressure of the cleaning liquid outputted from the flow control portion 621 is small, the predetermined interval is also small. When the cleaning module 610 is an endless belt type cleaning apparatus, if foreign matter enters the inner surface of the flexible endless belt portion, the foreign matter may enter between the flexible endless belt portion and the first rotating portion 6111 or an area between the flexible endless belt portion and the second rotating portion 6113, possibly causing damage to the endless belt.

For this reason, as shown in fig. 57 and ZH, when the flexible annular band portion is wound around the first rotating portion 6111 and the second rotating portion 6113, the upper edge of the mounting portion 651 is formed not lower than the lower surface of the upper portion of one end of the flexible annular band portion, and the lower edge of the mounting portion 651 is formed not higher than the upper surface of the lower portion of one end of the flexible annular band portion, so that the mounting portion 651 can close one end of the flexible annular band portion.

Accordingly, the upper edge of the leg portion 618 is formed not lower than the lower surface of the upper portion of the other end of the flexible annular band portion, and the lower edge of the leg portion 618 is formed not higher than the upper surface of the lower portion of the other end of the flexible annular band portion, so that the leg portion 618 can close the other end of the flexible annular band portion.

Thus, the installation of the mounting portion 651 and the bracket portion 618 can effectively prevent foreign matter from entering the interior of the flexible annular band portion.

More preferably, in some implementations, an upper edge of the mounting portion 651 may be located below a lower surface of an upper portion of one end of the flexible annular band portion, and one end of the flexible annular band portion is closed by engagement of the mounting portion 651 with a lower edge of the upper shell 670.

Accordingly, the upper edge of the leg portion 618 may also be located below the lower surface of the upper portion of the other end of the flexible annular band portion, and the other end of the flexible annular band portion is closed by the engagement of the leg portion 618 with the lower edge of the upper case 670.

Fig. 61 shows a schematic cross-sectional view of a cleaning base 600 according to one embodiment of the present disclosure. As shown in fig. 61, when the cleaning assembly is an endless belt type cleaning device, the diameter of the first rotating portion 6111 or the second rotating portion 6113 located in front of the endless belt type cleaning device is small. That is, when the first rotating portion 6111 is located in front of the second rotating portion 6113, the diameter of the first rotating portion 6111 is smaller than the diameter of the second rotating portion 6113, and when the second rotating portion 6113 is located in front of the first rotating portion 6111, the diameter of the second rotating portion 6113 is smaller than the diameter of the second rotating portion 6113.

Figure 62 illustrates a bottom view of a cleaning base according to one embodiment of the present disclosure. Figure 63 illustrates a partial structural schematic of a cleaning base according to one embodiment of the present disclosure.

In the present disclosure, the dirt suction module 630 is connected to the sewage storage portion through a return line so that when a negative pressure is provided to the dirt suction module 630 through the sewage storage portion, the dirt after the cleaning module 610 cleans the surface to be cleaned can be sucked into the sewage storage portion through the dirt suction module 630. The soil suction module 630 includes a suction port portion 631, the suction port portion 631 is located at the rear of the cleaning module 610, and the suction port portion 631 may be integrally formed with the housing module 650, in other words, the housing module 650 forms the suction port portion 631. The dirt suction module 630 further includes a scraper portion 632, and the scraper portion 632 is in contact with the flexible annular belt portion so that the scraper portion 632 can scrape dirt on the flexible annular belt portion off the flexible annular belt portion and further, so that the dirt enters the suction port portion 631.

The scraper portion 632 may be fixed to the housing module 650, disposed adjacent to the suction port portion 631, and located above the suction port portion 631.

In the present disclosure, the lower surface of the housing module is further provided with support wheels 680, and in the present disclosure, the number of the support wheels 680 may be two, and both the support wheels 680 are located at the rear of the soil suction module, so that the support wheels 680 rotate when the cleaning base moves forward or backward.

The present disclosure also provides a control method of a surface cleaning apparatus for performing a cleaning operation and a recovery operation of a surface to be cleaned by a cleaning liquid, the surface cleaning apparatus including: a suction source that generates a suction airstream in the recovery flow path; a cleaning base that performs a cleaning operation and a recovery operation based on the suction airflow; a cleaning liquid reservoir in fluid communication with the cleaning base to provide cleaning liquid to the cleaning base; and a recovery storage portion for receiving recovered solids and/or recovered liquid recovered by the cleaning base in a recovery operation, a gas-liquid separation device being provided within the recovery storage portion, the gas-liquid separation device performing gas-liquid separation on at least gas and recovered liquid in the suction gas flow; the control method comprises the following steps: after the gas-liquid separation device is activated, the suction source is allowed to be activated so that the cleaning base of the surface cleaning apparatus performs a cleaning operation and a recovery operation based on a suction airflow generated by the suction source; the suction source is not allowed to be activated before the gas-liquid separation device is activated.

According to the control method of the surface cleaning apparatus of the preferred embodiment of the present disclosure, the gas-liquid separation device is allowed to stop to perform the gas-liquid separation after the suction source is stopped to stop generating the suction airflow, and the gas-liquid separation device is not allowed to stop to perform the gas-liquid separation before the suction source is stopped to stop generating the suction airflow.

According to a control method of a surface cleaning apparatus of a preferred embodiment of the present disclosure, the surface cleaning apparatus further includes a control circuit part capable of generating at least a suction source start control signal, a suction source stop control signal, a gas-liquid separation device start control signal, and a gas-liquid separation device stop control signal; the suction source is started based on the suction source starting control signal, the suction source is stopped based on the suction source stopping control signal, the gas-liquid separation device is started based on the gas-liquid separation device starting control signal, and the gas-liquid separation device is stopped based on the gas-liquid separation device stopping control signal.

According to the control method of the surface cleaning apparatus of the preferred embodiment of the present disclosure, the control circuit section generates the suction source start-up control signal based on at least the gas-liquid separating device start-up control signal, and the control circuit section generates the gas-liquid separating device stop control signal based on at least the suction source stop control signal.

According to the control method of the surface cleaning apparatus of the preferred embodiment of the present disclosure, the control circuit section generates the suction source start-up control signal based on at least the gas-liquid separating device start-up control signal and over a first preset time period, and the control circuit section generates the gas-liquid separating device stop-down control signal based on at least the suction source stop-down control signal and over a second preset time period.

According to a preferred embodiment of the present disclosure, the surface cleaning apparatus further includes a control command receiving device, the control circuit part is in communication connection with the control command receiving device, the control command receiving device is at least used for receiving a control command, and the control circuit part generates a gas-liquid separation device start control signal and a suction source stop control signal based on at least the corresponding control command transmitted by the control command receiving device.

According to the control method of the surface cleaning apparatus of the preferred embodiment of the present disclosure, the control circuit section generates the gas-liquid separation device start control signal and the suction source stop control signal based on the control command received from the remote; preferably, the control instruction receiving means comprises a control portion provided to the surface cleaning apparatus and/or a display portion provided to the surface cleaning apparatus.

It will be understood by those skilled in the art that the foregoing embodiments are merely for clarity of illustration of the disclosure and are not intended to limit the scope of the disclosure. Other variations or modifications may be made to those skilled in the art, based on the above disclosure, and still be within the scope of the present disclosure.

Claims

1. A method of manufacturing a flexible endless belt for surface cleaning, which is applied to a cleaning base, and by which a surface to be cleaned is cleaned while the flexible endless belt is driven to move, characterized by comprising:

maintaining the substrate in tension;

after the adhesive is cured, fixing at least one end of the cleaning body and at least one end of the base material again by sewing with a sewing thread;

wherein a groove is formed on the inner peripheral surface of the base material so that the suture line is positioned in the groove; such that the head of the suture is located within the recess; the groove is formed into an annular mounting groove along the circumferential direction of the base material, and the sewing line is sewed for a circle along the circumferential direction of the cleaning body.

2. The method of manufacturing a flexible endless belt according to claim 1, wherein an axial direction restricting portion is formed on an inner wall surface of the base material in a circumferential direction of the base material, and when the flexible endless belt is engaged with a rotating portion that drives the flexible endless belt, a position of the flexible endless belt in an axial direction of the rotating portion is restricted by the axial direction restricting portion.

3. The method of manufacturing a flexible annular band according to claim 2, wherein the axial stopper portion includes an annular groove and an annular protrusion formed in a circumferential direction of the inner surface of the base material.

4. A flexible endless belt for surface cleaning manufactured by the method for manufacturing a flexible endless belt according to any one of claims 1 to 3, comprising:

the base material is made of a flexible material; and

a cleaning body bonded to the substrate such that a cleaning surface of the cleaning body forms a portion of an outer surface of the flexible endless belt.

5. The flexible endless belt according to claim 4, wherein an axial direction restricting portion is formed on an inner wall surface of the base material in a circumferential direction of the base material, and a position of the flexible endless belt in an axial direction of the rotating portion is restricted by the axial direction restricting portion when the flexible endless belt is engaged with the rotating portion that drives the flexible endless belt.

6. The flexible annular band according to claim 5, wherein the axial stopper portion includes an annular groove and an annular protrusion formed in a circumferential direction of the inner surface of the base material.

7. A cleaning base, comprising:

a housing module forming an accommodating portion;

the rotating shaft assembly is rotatably arranged on the shell module and is positioned in the accommodating part; and

the flexible endless belt of any one of claims 4-6, wrapping around and driven in motion by a spindle assembly to clean a surface to be cleaned by the flexible endless belt;

wherein the flexible annular band is located at the receiving portion of the housing module.