Mop
By designing limiting teeth and adjusting the relative position of the drive sleeve and mop handle, the problem of time-consuming and laborious mop strip squeezing is solved, thus simplifying mop operation and improving efficiency.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- XIAN AICHUANGJIA HELPER INTELLIGENT TECH CO LTD
- Filing Date
- 2023-11-28
- Publication Date
- 2026-07-07
AI Technical Summary
Existing mops require prolonged manual force to maintain the relative position of the structural components and the mop handle during the wringing process, which is time-consuming, labor-intensive, and inconvenient to operate.
A mop has been designed, including a mop handle, a sleeve, and a limiting part. The sleeve and the mop handle are fixed or movable by extending or retracting the limiting teeth. The relative position of the sleeve and the mop handle is adjusted by driving the limiting part with a driving component, which simplifies the operation.
This makes the wringing process of the mop strips more convenient, reduces the need for prolonged manual force application, and improves operational efficiency and user experience.
Smart Images

Figure CN224461649U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of household appliance technology, specifically to a mop. Background Technology
[0002] A mop, also known as a floor mop, is a long-handled cleaning tool used for wiping floors, or more generally, any long-handled cleaning tool. A mop has a mop head strip, which needs to be wrung out after washing for reuse.
[0003] In related technologies, some mops are equipped with a structural component that can rotate spirally relative to the mop handle. The two ends of the mop strip can be connected to the mop handle and the structural component respectively. The structural component drives one end of the mop strip away from the other end of the mop strip on the mop handle. The rotation of the structural component and the mop handle allows the mop strip to be twisted and squeezed dry. Alternatively, the structural component drives one end of the mop strip towards the other end of the mop strip on the mop handle. The rotation of the structural component and the mop handle causes the two ends of the mop strip to converge, making the mop strip fluffy, so that the mop strip can be used to wipe the surface to be cleaned.
[0004] However, when squeezing out the mop strips, in order to ensure that the mop strips are fully squeezed dry, it is necessary to manually apply force for a long time to maintain the relative position of the structural components and the mop handle, which is time-consuming, labor-intensive, inconvenient to operate, and affects the user experience. Utility Model Content
[0005] In view of this, the present invention provides a mop to solve the problem that current mops require a long period of manual force to maintain the relative position of the structural components and the mop handle when squeezing the mop strips, which is time-consuming, labor-intensive and inconvenient to operate.
[0006] This utility model provides a mop, comprising: a mop handle with an inlet and outlet; a mounting base connected to the mop handle, the mounting base being connected to a scrubbing part; a sleeve movably fitted onto the mop handle to drive the scrubbing part to move; and a first limiting part disposed on the mop handle, the first limiting part including limiting teeth adapted to be driven to extend or retract the inlet and outlet; wherein, when the limiting teeth extend from the inlet and outlet, they limit the sleeve to fix the sleeve relative to the mop handle; when the limiting teeth retract from the inlet and outlet, they release the limitation on the sleeve to allow the sleeve and the mop handle to move relative to each other.
[0007] In one alternative embodiment, the mop further includes a drive member disposed within the mop handle and connected to the first limiting portion, the drive member being capable of driving the first limiting portion to cause the limiting teeth to extend or retract from the inlet / outlet.
[0008] In one optional embodiment, the mop handle is provided with a mounting port, and the mop further includes a pressing part that extends at least partially from the mounting port out of the mop handle. The pressing part is movably disposed on the mop handle and connected to the driving member, and the pressing part is adapted to drive the driving member so that the driving member drives the first limiting part.
[0009] In one alternative embodiment, the inlet / outlet and the mounting port are disposed on the side wall of the mop handle.
[0010] In one alternative embodiment, the portion of the pressing part that extends out of the mop handle is configured as a control part, which is adapted for the user to apply force to, so that the control part drives the pressing part to move.
[0011] In one optional embodiment, the mop further includes a second limiting part connected to the sleeve. When the limiting tooth extends out of the inlet / outlet, it engages with the second limiting part to fix the sleeve and the mop handle relative to each other. When the limiting tooth retracts into the inlet / outlet, it disengages from the second limiting part to allow the sleeve and the mop handle to move relative to each other.
[0012] In one alternative embodiment, the second limiting portion is disposed on the inner wall of the sleeve.
[0013] In one alternative embodiment, with the first limiting part and the second limiting part fixed, the first limiting part supports the second limiting part axially on the mop handle.
[0014] In one optional embodiment, the sleeve can move along a first direction or a second direction, the first direction and the second direction being opposite to each other and in the same direction as the axial direction of the mop handle; when the sleeve moves along the first direction, the distance between the sleeve and the mounting base decreases; when the sleeve moves along the second direction, the distance between the sleeve and the mounting base increases.
[0015] In one optional embodiment, the driving member can drive the first limiting part to move along a third or fourth direction, so that the first limiting part is misaligned or opposite to the second limiting part, wherein the third and fourth directions are opposite to each other and intersect with the axis of the mop handle.
[0016] In one alternative implementation, the third direction is perpendicular to the axis of the mop handle.
[0017] In one alternative embodiment, the driving member is movably disposed on the mop handle, and the driving member can move along the first direction or the second direction to drive the first limiting portion to move along the third direction or the fourth direction.
[0018] In one optional embodiment, the first limiting portion has a first guide surface that intersects the axial direction of the mop handle. When the driving member moves along the first direction or the second direction, the driving member slides relative to the first limiting portion along the first guide surface to push the first limiting portion to move along the third direction or the fourth direction.
[0019] In one optional embodiment, the first limiting part has a first guide groove, the first guide surface is the inner wall of the first guide groove, the driving member includes a rod body and a first movable part connected to each other, the first movable part is embedded in the first guide groove, and the first movable part can slide along the first guide surface.
[0020] In one optional embodiment, when the mop includes a pressing part, the pressing part is movably disposed on the side wall of the mop handle, and the pressing part is connected to the driving member. The pressing part can move along the third direction or the fourth direction to drive the driving member to move along the first direction or the second direction.
[0021] In one optional embodiment, the pressing part has a second guide surface that intersects the axial direction of the mop handle, and the driving member slides along the second guide surface to push the driving member to move in the first direction or the second direction.
[0022] In one optional embodiment, the pressing part has a second guide groove, the second guide surface is the inner wall of the second guide groove, the driving member includes a rod body and a second movable part connected to each other, the second movable part is embedded in the second guide groove, and the second movable part can slide along the second guide surface.
[0023] In one optional embodiment, the first limiting portion has a first guide surface, which is parallel to the second guide surface.
[0024] In one alternative embodiment, the drive member includes a rod and an elastic portion connected to the rod and the mop handle. When the rod moves in the first direction, the elastic portion deforms, and the restoring deformation force of the elastic portion can drive the rod to move in the second direction.
[0025] In one alternative embodiment, the elastic part is fixedly sleeved on the rod body, and one end of the elastic part abuts against the mop handle.
[0026] In one optional embodiment, the mop handle is provided with an abutment platform, the drive component further includes a positioning post, the positioning post is connected to the handle body, the elastic part is engaged with the positioning post, and one end of the elastic part abuts against the abutment platform.
[0027] In an alternative embodiment, the first limiting portion further has a fifth guide surface, and when the sleeve moves in the second direction, the second limiting portion slides along the fifth guide surface to push the first limiting portion to move in the third direction.
[0028] In one alternative embodiment, the sleeve is rotatable relative to the mop handle in the circumferential direction of the mop handle.
[0029] In one alternative embodiment, the mop further includes a third limiting portion, wherein the sleeve is rotatable about the mop handle in a fifth direction, and the third limiting portion restricts the rotation of the sleeve about the mop handle in a sixth direction, wherein the fifth direction and the sixth direction are opposite to each other.
[0030] In one optional embodiment, the third limiting part is disposed on the sleeve, and the third limiting part can be fixed relative to the first limiting part in the sixth direction.
[0031] In one optional embodiment, the third limiting part is a limiting groove disposed on the inner wall of the sleeve. When the sleeve and the mop handle are fixed relative to each other, the first limiting part is located in the limiting groove, and the inner wall of the limiting groove abuts against the first limiting part.
[0032] In one optional embodiment, the limiting groove has a first limiting surface and a third guiding surface, and the first limiting portion has a second limiting surface and a fourth guiding surface facing away from each other. When the sleeve is subjected to a force in the sixth direction or the mop handle is subjected to a force in the fifth direction, the first limiting surface abuts against the second limiting surface. When the sleeve is subjected to a force in the fifth direction, the third guiding surface slides along the fourth guiding surface.
[0033] In one alternative embodiment, when the sleeve rotates relative to the mop handle in the circumferential direction of the mop handle, the sleeve causes one end of the mop strip to rotate relative to the mop handle, thereby deforming the mop strip and storing power.
[0034] Beneficial effects: This utility model provides a mop where the wiping part is connected to the sleeve and mounting base, thus fixing the wiping part. The limiting teeth of the first limiting part can be driven to extend out of the inlet and outlet, so that the sleeve and the mop handle are relatively fixed in the axial direction of the mop handle, thereby fixing the distance between the two ends of the wiping part and keeping the shape of the wiping part unchanged, so that the wiping part can continuously perform the wringing operation. The limiting teeth of the first limiting part can be driven to retract into the inlet and outlet, so that the sleeve and the mop handle can move relatively in the axial direction of the mop handle, thereby adjusting the distance between the two ends of the wiping part and keeping the shape of the wiping part variable, so that the wiping part can perform the cleaning operation. This solves the problem that current mops require long-term manual force to maintain the relative position of the structural components and the mop handle when wringing out the mop strip, which is time-consuming, laborious, and inconvenient to operate. Attached Figure Description
[0035] To more clearly illustrate the specific embodiments of this utility model or the technical solutions in the prior art, the drawings used in the description of the specific embodiments or the prior art will be briefly introduced below. Obviously, the drawings described below are some embodiments of this utility model. For those skilled in the art, other drawings can be obtained from these drawings without creative effort.
[0036] Figure 1 A schematic diagram of the structure of a mop provided by this utility model;
[0037] Figure 2 for Figure 1 An enlarged schematic diagram of the internal structure of A in the diagram;
[0038] Figure 3 A schematic diagram of the structure of a driving component, a first limiting part, and a pressing part in a mop provided by this utility model;
[0039] Figure 4 A schematic diagram of the structure of the first limiting part in a mop provided by this utility model;
[0040] Figure 5 This utility model provides a structural schematic diagram of a mop sleeve.
[0041] Explanation of reference numerals in the attached figures:
[0042] 1. Mop handle; 101. Inlet / outlet; 102. Mounting port; 103. Abutment platform;
[0043] 2. Sleeve; 201. Second limiting part; 202. Third limiting part; 2021. First limiting surface; 2022. Third guide surface;
[0044] 3. Driving component; 301. Rod body; 3011. Positioning post; 302. First movable part; 303. Second movable part; 304. Elastic part;
[0045] 4. First limiting part; 40. Limiting tooth; 401. First guide surface; 402. First guide groove; 403. Second limiting surface; 404. Fourth guide surface; 405. Fifth guide surface;
[0046] 5. Pressing part; 501. Second guide surface; 502. Second guide groove;
[0047] 6. Control Department;
[0048] 7. Mounting bracket;
[0049] 8. Cleaning section. Detailed Implementation
[0050] To make the objectives, technical solutions, and advantages of the embodiments of this utility model clearer, the technical solutions of the embodiments of this utility model will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are only some embodiments of this utility model, not all embodiments. Based on the embodiments of this utility model, all other embodiments obtained by those skilled in the art without creative effort are within the protection scope of this utility model.
[0051] The following is combined Figures 1-5 The following describes embodiments of the present invention.
[0052] According to an embodiment of the present invention, a mop is provided, such as... Figure 1 , Figure 2 As shown, it includes: mop handle 1, inlet / outlet 101, sleeve 2, first limiting part 4, and mounting base 7.
[0053] The mop handle 1 is provided with an inlet and outlet 101; the mounting base 7 is connected to the mop handle 1 and the mounting base 7 is connected to the scrubbing part 8; the sleeve 2 is movably sleeved on the mop handle 1 to drive the scrubbing part 8 to move; the first limiting part 4 is provided on the mop handle 1, and the first limiting part 4 includes a limiting tooth 40 adapted to be driven to extend or retract the inlet and outlet 101; wherein, when the limiting tooth 40 extends out of the inlet and outlet 101, it limits the sleeve 2 so that the sleeve 2 is relatively fixed to the mop handle 1; when the limiting tooth 40 retracts out of the inlet and outlet 101, it releases the limitation on the sleeve 2 so that the sleeve 2 and the mop handle 1 can move relative to each other.
[0054] Specifically, such as Figure 1As shown, the mop handle 1 is the basic component of the mop. The mop handle 1 provides a mounting base for at least some other parts of the mop. The mop handle 1 is a rod-shaped structure, which the user can hold to operate the mop. The mounting base 7 is connected to the mop handle 1 and can be used to install the scrubbing part 8. The scrubbing part 8 can be used to scrub the surface to be cleaned. When the user uses the mop, they can hold the mop handle 1 and drive the scrubbing part 8 to move relative to the surface to be cleaned, thereby achieving the purpose of cleaning the surface. The scrubbing part 8 can specifically be a sponge or a mop cloth; this embodiment does not limit the specific type of the scrubbing part 8. Furthermore, the scrubbing part 8 can be detachably installed on the mounting base 7, making it replaceable. This allows for replacement of the scrubbing part 8 after long-term use and damage, thus extending the service life of the mop.
[0055] Furthermore, such as Figure 1 As shown, the sleeve 2 can be fitted onto the mop handle 1 and is connected to the scrubbing part 8. Specifically, the mounting base 7 can be connected to one end of the mop handle 1. The scrubbing part 8 can be a mop strip, and the two ends of multiple mop strips can be connected to the mounting base 7 and the sleeve 2 respectively. This embodiment includes a limiting mechanism located between the mop handle 1 and the sleeve 2. The limiting mechanism restricts the relative axial movement of the mop handle 1 and the sleeve 2. The limiting mechanism includes a first limiting part 4, with limiting teeth 40 adapted to be driven to extend or retract from the inlet / outlet 101. When the limiting teeth 40 extend from the inlet / outlet 101, they engage with the sleeve 2 to restrict the relative axial movement of the sleeve 2 and the mop handle 1, thus fixing the relative positional relationship between the sleeve 2 and the mop handle 1. This allows the external shape of the scrubbing part 8, connected to the mounting base 7 and the sleeve 2 at both ends, to be fixed. When the limiting teeth 40 retract from the inlet / outlet 101, they separate from the sleeve 2, releasing the restriction on the relative axial movement of the sleeve 2 and the mop handle 1, allowing the relative positional relationship between the sleeve 2 and the mop handle 1 to move. This allows the external shape of the scrubbing part 8, connected to the mounting base 7 and the sleeve 2 at both ends, to be changed.
[0056] Furthermore, such as Figure 1As shown, when the scrubbing section 8 uses mop strips, multiple mop strips can be set, and these multiple mop strips can be distributed circumferentially along the mop handle 1. One end of each mop strip is connected to a circumferential part of the sleeve 2, and the other end is connected to a circumferential part of the mounting base 7. When the mop handle 1 and the sleeve 2 are relatively fixed axially along the mop handle 1, both ends of the mop strips are fixed. When the distance between the sleeve 2 and the mounting base 7 is relatively minimum, minimizing the relative distance between the two ends of the mop strips, the two ends of the scrubbing section 8 are concentrated and fluffy, allowing the scrubbing section 8 to thoroughly scrub the surface to be cleaned. When the distance between the sleeve 2 and the mounting base 7 is relatively maximum, maximizing the distance between the two ends of the mop strips, the scrubbing section 8 is stretched and opened, making it easier to squeeze out the water from the scrubbing section 8.
[0057] This embodiment provides a mop, in which the scrubbing part 8 is connected to the sleeve 2 and the mounting base 7, thereby fixing the scrubbing part 8. The limiting tooth 40 of the first limiting part 4 can be driven to extend out of the inlet and outlet 101, so that the sleeve 2 and the mop handle 1 are relatively fixed in the axial direction of the mop handle 1, thereby fixing the distance between the two ends of the scrubbing part 8, so that the scrubbing part 8 can maintain its shape and continuously perform the wringing operation. The limiting tooth 40 of the first limiting part 4 can be driven to retract into the inlet and outlet 101, so that the sleeve 2 and the mop handle 1 can move relatively in the axial direction of the mop handle 1, thereby adjusting the distance between the two ends of the scrubbing part 8, so that the scrubbing part 8 can maintain its shape and perform the cleaning operation. This solves the problem that current mops require long-term manual force to maintain the relative position of the structural components and the mop handle when wringing out the mop strip, which is time-consuming, laborious, and inconvenient to operate.
[0058] In one embodiment, such as Figure 2 , Figure 3 As shown, the mop also includes a drive member 3 disposed inside the mop handle 1 and connected to the first limiting part 4. The drive member 3 can drive the first limiting part 4 to cause the limiting teeth 40 to extend or retract from the inlet and outlet 101.
[0059] Specifically, such as Figure 2 , Figure 3 As shown, the driving component 3 is disposed on the mop handle 1. The driving component 3 is connected to the first limiting part 4 of the limiting mechanism. The driving component 3 can be used to drive the first limiting part 4 of the limiting mechanism, thereby releasing the relative fixed relationship between the sleeve 2 and the mop handle 1, so that the sleeve 2 can move relative to the mop handle 1 along the axial direction of the mop handle 1. This allows the distance between the two ends of the scrubbing part 8 to be adjusted.
[0060] Furthermore, such as Figure 2 , Figure 3As shown, the state of the wiping section 8 is adjusted by controlling the limiting mechanism through the driving component 3, making the mop control operation convenient. Furthermore, since the driving component 3 is located on the mop handle 1, the user's hand can be close to the driving component 3 when holding the mop handle 1, allowing the user to directly operate the driving component 3 while holding the mop handle 1, thus adjusting the relative movement relationship between the sleeve 2 and the mop handle 1. More specifically, the driving component 3 can drive the first limiting part 4 of the limiting mechanism to release the fixed relationship between the sleeve 2 and the mop handle 1 along the axial direction of the mop handle 1, allowing the sleeve 2 to move along the axial direction of the mop handle 1. This allows the distance between the two ends of the wiping section 8 to be adjusted, thereby changing the shape of the wiping section 8. The driving component 3's location on the mop handle makes it easy for the user to operate the driving component 3 while holding the mop handle 1, simplifying and facilitating the adjustment of the shape of the mop's wiping section 8, thus making the mop operation simple and convenient.
[0061] In one embodiment, such as Figure 2 , Figure 3 As shown, the mop handle 1 is provided with a mounting port 102. The mop also includes a pressing part 5 that extends at least partially from the mounting port 102 out of the mop handle 1. The pressing part 5 is movably disposed on the mop handle 1 and connected to the driving member 3. The pressing part 5 is adapted to drive the driving member 3 so that the driving member 3 drives the first limiting part 4.
[0062] Specifically, in order to make the mop easier to operate, the part of the pressing part 5 that extends out of the mounting port 102 from the mop handle 1 is adapted to be manually pressed and driven to drive the driving member 3 to move, so that the driving member 3 drives the first limiting part 4 to be fixed or moved relative to the sleeve 2, thereby allowing the sleeve 2 to be separated or fixed relative to the mop handle 1 in the axial direction of the mop handle 1.
[0063] In one embodiment, such as Figure 2 As shown, the inlet / outlet 101 and the mounting port 102 are located on the side wall of the mop handle 1.
[0064] Specifically, such as Figure 2 As shown, the driving member 3 is disposed inside the mop handle 1, and the inlet / outlet 101 and the mounting port 102 are disposed on the side wall of the mop handle 1, so that the limiting teeth 40 of the first limiting part 4 can pass through the side wall of the mop handle through the inlet / outlet 101, and so that a part of the structure of the first limiting part 4 located inside the mop handle 1 can be connected to the driving member 3; at the same time, it is convenient for at least a part of the structure of the pressing part 5 to pass through the side wall of the mop handle through the mounting port 102, and so that a part of the structure of the pressing part 5 located inside the mop handle 1 can be connected to the driving member 3.
[0065] In one embodiment, such as Figure 2 As shown, the part of the pressing part 5 that extends out of the mop handle 1 is configured as the control part 6, which is suitable for the user to apply force to the control part 6 so that the control part 6 drives the pressing part 5 to move.
[0066] Specifically, such as Figure 2 As shown, the control part 6 extends out of the outer wall of the mop handle 1 from the mounting port 102, so that the user can apply force to the control part 6 to press the pressing part 5, so that the control part 6 of the pressing part 5 passes through the side wall of the mop handle from the mounting port 102.
[0067] Furthermore, such as Figure 2 As shown, this embodiment does not limit the connection method between the control unit 6 and the pressing unit 5, as long as it ensures that the control unit 6 does not detach from the outer wall of the mop handle 1 when it extends from the mounting port 102. As one implementation method, such as... Figure 2 As shown, the control part 6 is configured to abut against the pressing part 5. A limiting flange is provided at the mounting port 102 on the outer wall of the mop handle 1, and a limiting boss is provided on the control part 6. The locking fit between the limiting boss and the limiting flange prevents the control part 6 from detaching from the mop handle 1. In another embodiment, the control part 6 is configured to be threadedly connected to the pressing part 5. That is, a threaded rod and a threaded hole are provided at a position close to the control part 6 and the pressing part 5 for threaded connection. The fixed fit of the threaded connection prevents the control part 6 from detaching from the mop handle 1.
[0068] In one embodiment, such as Figure 2 As shown, the mop also includes a second limiting part 201 connected to the sleeve 2. When the limiting tooth 40 extends out of the inlet / outlet 101, it engages with the second limiting part 201 to fix the sleeve 2 and the mop handle 1 relative to each other. When the limiting tooth 40 retracts into the inlet / outlet 101, it separates from the second limiting part 201 to allow the sleeve 2 and the mop handle 1 to move relative to each other.
[0069] Specifically, such as Figure 2 As shown, a second limiting part 201 is provided on the sleeve 2. The first limiting part 4 and the second limiting part 201 can be fixed to each other or separated. When the first limiting part 4 and the second limiting part 201 are separated, the first limiting part 4 and the second limiting part 201 can move relative to each other. Therefore, the driving member 3 connected to the first limiting part 4 can move relative to the second limiting part 201, thereby allowing the driving member 3 to move relative to the sleeve 2. Since the driving member 3 is provided on the mop handle 1, the sleeve 2 can also move relative to the mop handle 1. In this way, the sleeve 2 can move relative to the mop handle 1 in the axial direction. When the first limiting part 4 and the second limiting part 201 are fixed, the driving member 3 can be fixed relative to the sleeve 2. Since the driving member 3 is provided on the mop handle 1, the mop handle 1 can be fixed relative to the sleeve 2.
[0070] Furthermore, such as Figure 2As shown, the pressing part 5 is adapted to be manually pressed and driven to drive the driving member 3 to move, so that the driving member 3 drives the first limiting part 4 and the second limiting part 201 to be relatively fixed or relatively movable, thereby allowing the sleeve 2 to be relatively separated from or relatively fixed to the mop handle 1 in the axial direction of the mop handle 1.
[0071] In one embodiment, such as Figure 2 , Figure 5 As shown, the second limiting part 201 is provided on the inner wall of the sleeve 2.
[0072] In one embodiment, such as Figure 2 As shown, when the first limiting part 4 and the second limiting part 201 are fixed, the first limiting part 4 supports the second limiting part 201 axially on the mop handle 1.
[0073] Specifically, such as Figure 2 As shown, to fix the first limiting part 4 and the second limiting part 201 to each other, the first limiting part 4 can be supported on the second limiting part 201. When the user holds the mop, specifically, the mop can be in a posture where the axis of the mop handle 1 is in the same direction as the direction of gravity, or the axis of the mop handle 1 is close to the direction of gravity. At this time, the first limiting part 4 supported on the second limiting part 201 allows the first limiting part 4 to bear the second limiting part 201, thereby allowing the first limiting part 4 to bear the sleeve 2 connected to the second limiting part 201, thus overcoming the weight of the sleeve 2 itself. When the first limiting part 4 and the second limiting part 201 can move relative to each other, the first limiting part 4 is no longer supported on the second limiting part 201. Thus, the first limiting part 4 no longer bears the sleeve 2, and the sleeve 2 can move along the axis of the mop handle 1 under its own weight, thereby adjusting the distance between the sleeve 2 and the mounting base 7, and thus adjusting the distance between the two ends of the scrubbing part 8.
[0074] Furthermore, such as Figure 2 As shown, when the sleeve 2 needs to be reset after moving under the action of gravity, the user can hold the sleeve 2 and move it in the opposite direction of gravity, so that the sleeve 2 can be reset. At this time, the first limiting part 4 can support the second limiting part 201 again, so that the sleeve 2 can return to the initial position.
[0075] In one embodiment, such as Figure 1 As shown, the sleeve 2 can move along a first direction or a second direction, the first direction and the second direction are opposite to each other and in the same direction as the axis of the mop handle 1; when the sleeve 2 moves along the first direction, the distance between the sleeve 2 and the mounting base 7 decreases; when the sleeve 2 moves along the second direction, the distance between the sleeve 2 and the mounting base 7 increases.
[0076] Specifically, such as Figure 1As shown, when the sleeve 2 moves along the first direction, the distance between the sleeve 2 and the mounting base 7 is reduced, allowing the two ends of the scrubbing part 8 to be relatively concentrated, resulting in a concentrated and fluffy state for easy scrubbing of the surface to be cleaned. When the sleeve 2 moves along the second direction, the distance between the sleeve 2 and the mounting base 7 is increased, allowing the two ends of the scrubbing part 8 to be relatively far apart, resulting in a stretched state for the scrubbing part 8. This allows the scrubbing part 8 to be twisted by rotating the sleeve 2 relative to the mop handle 1, ensuring that the water in the scrubbing part 8 is thoroughly squeezed out.
[0077] In one embodiment, such as Figure 2 , Figure 3 As shown, the driving member 3 can drive the first limiting part 4 to move along a third or fourth direction, so that the first limiting part 4 is misaligned or opposite to the second limiting part 201, and the third and fourth directions are opposite to each other and intersect with the axis of the mop handle 1.
[0078] Specifically, such as Figure 2 , Figure 3 As shown, the driving member 3 can specifically drive the first limiting part 4 to move along the fourth direction, so that the first limiting part 4 can be opposite to the second limiting part 201, thereby allowing the first limiting part 4 to be supported on the second limiting part 201, and thus fixing the sleeve 2 and the mop handle 1 relative to each other in the axial direction of the mop handle 1. The driving member 3 can also drive the first limiting part 4 to move along the third direction, so that the first limiting part 4 and the second limiting part 201 are misaligned, so that the first limiting part 4 is no longer supported on the second limiting part 201, allowing the first limiting part 4 and the second limiting part 201 to move relative to each other, and thus allowing the sleeve 2 and the mop handle 1 to move relative to each other in the axial direction of the mop handle 1. When the first limiting part 4 and the second limiting part 201 are misaligned, the first limiting part 4 no longer blocks the second limiting part 201 in the direction of movement of the second limiting part 201, so that the distance that the second limiting part 201 can move in the axial direction of the mop handle 1 is not limited, thereby allowing the sleeve 2 to move a longer distance relative to the axial direction of the mop handle 1.
[0079] Furthermore, such as Figure 2 , Figure 3 As shown, the third and fourth directions intersect with the axis of the mop handle 1. When the mop is in an upright position, the first limiting part 4 can move in the horizontal direction so that the first limiting part 4 is opposite to or misaligned with the second limiting part 201. The third and fourth directions are also opposite to each other. This makes the range of motion of the first limiting part 4 relatively smaller during the adjustment of the connection relationship between the first limiting part 4 and the second limiting part 201, so that the structure of the mop is more compact.
[0080] In one embodiment, such as Figure 2 , Figure 3 As shown, the third direction is perpendicular to the axis of the mop handle 1.
[0081] Specifically, such as Figure 2 , Figure 3 As shown, the third direction can be set to be perpendicular to the axis of the mop handle 1, so that the fourth direction is also perpendicular to the axis of the mop handle 1. In this way, during the movement of the first limiting part 4 along the third or fourth direction, the first limiting part 4 can move radially along the mop handle 1, so that the first limiting part 4 can move the shortest distance to make the first limiting part 4 opposite or misaligned with the second limiting part 201, thereby making the structure of the mop compact.
[0082] In one embodiment, such as Figure 2 , Figure 3 As shown, the driving component 3 is movably disposed on the mop handle 1. The driving component 3 can move along the first direction or the second direction to drive the first limiting part 4 to move along the third direction or the fourth direction.
[0083] Specifically, such as Figure 2 , Figure 3 As shown, the driving member 3 is movably disposed on the mop handle 1, allowing the driving member 3 to move relative to the mop handle 1. Specifically, the driving member 3 can move along a first direction or a second direction. When the driving member 3 moves along the first direction, it can drive the first limiting part 4 to move along a third direction, thereby allowing the first limiting part 4 to be misaligned with the second limiting part 201. When the driving member 3 moves along the second direction, the first limiting part 4 can move along a fourth direction, thereby making the first limiting part 4 opposite to the second limiting part 201.
[0084] In one embodiment, such as Figure 2 , Figure 3 As shown, the first limiting part 4 has a first guide surface 401, which intersects the axis of the mop handle 1. When the driving member 3 moves along the first direction or the second direction, the driving member 3 slides relative to the first limiting part 4 along the first guide surface 401 to push the first limiting part 4 to move along the third direction or the fourth direction.
[0085] Specifically, such as Figure 2 , Figure 3As shown, the first limiting part 4 may have a first guide surface 401. The extension direction of the first guide surface 401 of the first limiting part 4 is inclined relative to the axial direction of the mop handle 1, that is, it intersects with the first direction and the second direction but is not perpendicular to them. The first guide surface 401 of the first limiting part 4 cooperates with the driving member 3. When the driving member 3 moves along the first direction, the driving member 3 can slide along the first guide surface 401 of the first limiting part 4, thereby pushing the first limiting part 4 to move along the third direction. When the driving member 3 moves along the second direction, the driving member 3 can also slide along the first guide surface 401 of the first limiting part 4, thereby causing the first limiting part 4 to move along the fourth direction. Specifically, when the mop is standing upright on a horizontal surface, the first guide surface 401 of the first limiting part 4 is inclined relative to the horizontal surface. Therefore, when the driving member 3 moves from the initial position along the first direction, the force formed by the driving member 3 on the first guide surface 401 of the first limiting part 4 can be decomposed into a component force along the first direction and a component force along a third direction. The component force in the first direction can cause the driving member 3 to slide along the first guide surface 401 of the first limiting part 4, and the component force in the third direction can cause the first limiting part 4 to move along the third direction, so that the first limiting part 4 and the second limiting part 201 are misaligned.
[0086] Furthermore, such as Figure 2 , Figure 3 As shown, when the driving member 3 moves along the second direction, the force formed by the driving member 3 on the first guide surface 401 of the first limiting part 4 can be decomposed into a component force along the second direction and a component force along the fourth direction. The component force in the second direction can cause the driving member 3 to slide relative to the first guide surface 401 of the first limiting part 4 and return to the initial position. The component force in the fourth direction can cause the first limiting part 4 to move along the fourth direction so that the first limiting part 4 can be opposite to the second limiting part 201.
[0087] In one embodiment, such as Figure 2 , Figure 3 As shown, the first limiting part 4 has a first guide groove 402, and the first guide surface 401 is the inner wall of the first guide groove 402. The driving member 3 includes a rod 301 and a first movable part 302 connected to each other. The first movable part 302 is embedded in the first guide groove 402 and can slide along the first guide surface 401.
[0088] Specifically, such as Figure 2 , Figure 3As shown, in order to keep the first limiting part 4 stable in the direction of movement when it moves in a third or fourth direction, the first limiting part 4 may also be provided with a first guide groove 402, wherein the first guide surface 401 of the first limiting part 4 is located in the first guide groove 402, specifically, the first guide surface 401 is the inner wall of the first guide groove 402. The driving member 3 may be specifically configured to include a rod body 301 and a first movable part 302, wherein the first movable part 302 is connected to the rod body 301 and is embedded in the first guide groove 402 of the first limiting part 4. The first movable part 302 can move along the first guide groove 402 of the first limiting part 4, so that the first limiting part 4 can move in a third or fourth direction.
[0089] Furthermore, such as Figure 2 , Figure 3 As shown, the first guide groove 402 of the first limiting part 4 extends in the same direction as the first guide surface 401. There are two first guide surfaces 401, which form two opposing inner walls within the first guide groove 402. When the first movable part 302 is embedded in the first guide groove 402 of the first limiting part 4, the first movable part 302 is sandwiched between the two first guide surfaces 401 within the first guide groove 402. This achieves the purpose of limiting the first movable part 302, so that the first movable part 302 can always be in contact with the first guide surface 401 when it moves in its moving direction, so that the first guide surface 401 of the first guide groove 402 can guide the first movable part 302 to move. In this way, the first limiting part 4 can move in a third or fourth direction.
[0090] Furthermore, such as Figure 2 , Figure 3 As shown, the first guide groove 402 of the first limiting part 4 also has two side walls connected to the first guide surface 401. The two side walls are arranged opposite to each other. When the first movable part 302 moves within the first guide groove 402 of the first limiting part 4, the two side walls of the first guide groove 402 can limit the first movable part 302. When the first movable part 302 moves along the first direction to the point where the first limiting part 4 and the second limiting part 201 are misaligned, the first movable part 302 can just contact one side inner wall of the first guide groove 402. When the first movable part 302 moves along the second direction to the point where the first limiting part 4 is supported by the second limiting part 201, the first movable part 302 can just contact the other side wall of the first guide groove 402. This ensures that the first movable part 302 can always move within the first guide groove 402 of the first limiting part 4, preventing the first movable part 302 from separating from the first limiting part 4.
[0091] Furthermore, such as Figure 2 , Figure 3As shown, it should also be understood that during the movement of the first movable part 302 along the first or second direction, the first limiting part 4 moves in the third or fourth direction, so that the first limiting part 4 and the first movable part 302 have relative displacement in the third or fourth direction.
[0092] In one embodiment, such as Figure 2 , Figure 3 As shown, when the mop includes a pressing part 5, the pressing part 5 is movably disposed on the side wall of the mop handle 1, and the pressing part 5 is connected to the driving member 3. The pressing part 5 can move along a third or fourth direction to drive the driving member 3 to move along a first or second direction.
[0093] Specifically, such as Figure 2 , Figure 3 As shown, when the user holds the mop handle 1, since the pressing part 5 is provided on the side wall of the mop handle 1, the user's fingers can easily touch the pressing part 5, so that the pressing part 5 can move in the third or fourth direction. This allows the user to easily operate the mop, and the sleeve 2 can be relatively separated from or relatively fixed to the mop handle 1 in the axial direction of the mop handle 1.
[0094] Furthermore, such as Figure 2 , Figure 3 As shown, the mop handle 1 can be configured as a rod-shaped structure with a cavity. The driving member 3 can be disposed in the cavity inside the mop handle 1. The first limiting part 4 is specifically movably disposed on the side wall of the mop handle 1. The first limiting part 4 passes through the side wall of the mop handle 1, so that the first limiting part 4 can move along a third or fourth direction. The pressing part 5 can also be disposed through the side wall of the mop handle 1. Specifically, the side wall of the mop handle 1 can be provided with an opening for the pressing part 5 and the first limiting part 4 to pass through. The openings for the pressing part 5 and the first limiting part 4 to pass through are located on the same side of the mop handle 1. When the pressing part 5 moves along the third direction, the pressing part 5 moves toward the mop handle 1. Correspondingly, the first limiting part 4 also moves in the direction toward the mop handle 1. When the pressing part 5 moves along the fourth direction, the pressing part 5 moves in the direction away from the mop handle 1. Correspondingly, the first limiting part 4 also moves in the direction away from the mop handle 1. By placing the drive unit 3 inside the mop handle 1, the internal space of the mop handle 1 can be fully utilized, making the structure of the mop more compact.
[0095] Furthermore, such as Figure 2 , Figure 3As shown, it should be understood that the openings on the mop handle 1 through which the first limiting part 4 and the pressing part 5 pass can also be provided on the opposite sides of the mop handle 1. Accordingly, when the pressing part 5 moves in a third direction, it can drive the first limiting part 4 to move in a fourth direction. When the pressing part 5 moves in a fourth direction, it can drive the first limiting part 4 to move in a third direction. The specific positions of the first limiting part 4 and the pressing part 5 are not limited in this embodiment.
[0096] In one embodiment, such as Figure 2 , Figure 3 As shown, the pressing part 5 has a second guide surface 501, which intersects the axis of the mop handle 1. The driving member 3 slides along the second guide surface 501 to push the driving member 3 to move in the first direction or the second direction.
[0097] Specifically, such as Figure 2 , Figure 3 As shown, the extension direction of the second guide surface 501 of the pressing part 5 is inclined relative to the axial direction of the mop handle 1, that is, it intersects with the first direction and the second direction but is not perpendicular to them. The second guide surface 501 of the pressing part 5 cooperates with the driving member 3. When the pressing part 5 moves in the third direction, the driving member 3 can slide along the second guide surface 501 of the pressing part 5, thereby pushing the driving member 3 to move in the first direction. When the pressing part 5 moves in the fourth direction, the driving member 3 can also slide along the second guide surface 501 of the pressing part 5, thereby causing the driving member 3 to move in the second direction. Specifically, when the mop is standing upright on a horizontal surface, the second guide surface 501 of the pressing part 5 is inclined relative to the horizontal surface. Therefore, when the pressing part 5 moves from the initial position along a third direction, the force formed by the driving member 3 on the second guide surface 501 of the pressing part 5 can be decomposed into a component force along the first direction and a component force along the third direction. The component force along the third direction can cause the driving member 3 to slide relative to the second guide surface 501 of the pressing part 5, and the component force along the first direction can cause the driving member 3 to move along the first direction, so that the first limiting part 4 can also move along the third direction.
[0098] Furthermore, such as Figure 2 , Figure 3 As shown, when the pressing part 5 moves along the fourth direction, the force formed by the driving member 3 on the second guide surface 501 of the pressing part 5 can be decomposed into a component force along the second direction and a component force along the fourth direction. The component force in the second direction can cause the driving member 3 to move along the second direction, so that the first limiting part 4 can move along the fourth direction, thereby achieving the purpose of controlling the movement of the first limiting part 4 by applying a force to the pressing part 5.
[0099] In one embodiment, such as Figure 2 , Figure 3As shown, the pressing part 5 has a second guide groove 502, and the second guide surface 501 is the inner wall of the second guide groove 502. The driving member 3 includes a rod 301 and a second movable part 303 connected to each other. The second movable part 303 is embedded in the second guide groove 502 and can slide along the second guide surface 501.
[0100] Specifically, such as Figure 2 , Figure 3 As shown, in order to keep the pressing part 5 stable in the direction of movement when it moves in the third or fourth direction, the pressing part 5 may also be provided with a second guide groove 502, wherein the second guide surface 501 of the pressing part 5 is located in the second guide groove 502, specifically, the second guide surface 501 is the inner wall of the second guide groove 502. The driving member 3 may also be provided with a second movable part 303, wherein the second movable part 303 is connected to the rod 301, the second movable part 303 is embedded in the second guide groove 502 of the pressing part 5, and the second movable part 303 can move along the second guide groove 502 of the pressing part 5, so that the second movable part 303 can move in the first or second direction.
[0101] Furthermore, such as Figure 2 , Figure 3 As shown, the second guide groove 502 of the pressing part 5 extends in the same direction as the second guide surface 501. There are two second guide surfaces 501, which form two opposing inner walls within the second guide groove 502. When the second movable part 303 is embedded in the second guide groove 502 of the pressing part 5, the second movable part 303 is sandwiched between the two second guide surfaces 501 within the second guide groove 502. This achieves the purpose of limiting the second movable part 303, so that the second movable part 303 can always be in contact with the second guide surface 501 when it moves in its moving direction, so that the second guide surface 501 of the second guide groove 502 can guide the movement of the second movable part 303. In this way, the pressing part 5 can move stably and reliably along a third or fourth direction.
[0102] Furthermore, such as Figure 2 , Figure 3As shown, the second guide groove 502 of the pressing part 5 also has two side walls connected to the second guide surface 501. The two side walls are arranged opposite to each other. When the second movable part 303 moves in the second guide groove 502 of the pressing part 5, the two side walls of the second guide groove 502 can limit the second movable part 303. When the second movable part 303 moves along the first direction to the point where the first limiting part 4 and the second limiting part 201 are misaligned, the second movable part 303 can just contact one side inner wall of the second guide groove 502. When the second movable part 303 moves along the second direction to the point where the first limiting part 4 is supported by the second limiting part 201, the second movable part 303 can just contact the other side wall of the second guide groove 502. This ensures that the second movable part 303 can always move in the second guide groove 502 of the pressing part 5, preventing the second movable part 303 from separating from the pressing part 5.
[0103] Furthermore, such as Figure 2 , Figure 3 As shown, it should also be understood that during the movement of the second movable part 303 along the first or second direction, the pressing part 5 moves in the third or fourth direction, so that the pressing part 5 and the second movable part 303 are relatively displaced in the third or fourth direction. In some embodiments, it should be understood that when the mop is vertically mounted and the sleeve 2 and the mop handle 1 are relatively fixed in the axial direction of the mop handle 1, the second limiting part 201 is located above the first limiting part 4, so that the first limiting part 4 can support the second limiting part 201. When the first limiting part 4 and the second limiting part 201 are misaligned, the sleeve 2 and the mop handle 1 move relatively in the axial direction of the mop handle 1, and the sleeve 2 can move along the first direction under its own weight, so that the second limiting part 201 can move to the lower side of the first limiting part 4. When the sleeve 2 moves along the second direction to fix the sleeve 2 relative to the mop handle 1 in the axial direction of the mop handle 1 again, the second limiting part 201 needs to move again above the first limiting part 4 so that the first limiting part 4 can be supported by the second limiting part 201.
[0104] In one embodiment, such as Figure 2 , Figure 3 As shown, the first limiting part 4 has a first guide surface 401, which is parallel to the second guide surface 501.
[0105] In one embodiment, such as Figure 2 , Figure 3 As shown, the driving member 3 includes a rod body 301 and an elastic part 304. The elastic part 304 is connected to the rod body 301 and the mop handle 1. When the rod body 301 moves in the first direction, the elastic part 304 deforms, and the restoring deformation force of the elastic part 304 can drive the rod body 301 to move in the second direction.
[0106] Specifically, such as Figure 2 , Figure 3 As shown, the elastic part 304 can be connected to the rod body 301 and the mop handle 1. When the user presses the pressing part 5, causing the rod body 301 to move relative to the mop handle 1 in the first direction, the elastic part 304 can deform under the force of the rod body 301, thereby giving the elastic part 304 elastic potential energy, or increasing the elastic potential energy of the elastic part 304. The restoring deformation force of the elastic part 304 can drive the rod body 301 to move in the second direction, thereby causing the pressing part 5 to move in the fourth direction, so that the pressing part 5 can protrude again from the side wall of the mop handle 1. When the sleeve 2 needs to move along the second direction to the first limiting part 4 and be supported by the second limiting part 201 again, the first limiting part 4 and the second limiting part 201 can be misaligned by pressing the pressing part 5. In this way, when the sleeve 2 moves along the second direction, the second limiting part 201 can move above the first limiting part 4. At this time, the pressing part 5 is released, and the rod 301 moves the first limiting part 4 along the fourth direction under the restoring deformation force of the elastic part 304, so that the first limiting part 4 can be opposite to the second limiting part 201 and supported by the second limiting part 201.
[0107] In one embodiment, such as Figure 2 , Figure 3 As shown, the elastic part 304 is fixedly sleeved on the rod body 301, and one end of the elastic part 304 abuts against the mop handle 1.
[0108] Specifically, such as Figure 2 , Figure 3 As shown, in order to facilitate the installation of the elastic part 304 on the rod body 301 and its connection with the mop handle 1, the elastic part 304 can be a spring, and the elastic part 304 can be sleeved and fixed to the rod body 301. One end of the elastic part 304 can abut against the mop handle 1, so that the elastic part 304 can be fixed between the rod body 301 and the mop handle 1.
[0109] In one embodiment, such as Figure 2 , Figure 3 As shown, the mop handle 1 is provided with an abutment platform 103, and the drive component 3 also includes a positioning post 3011. The positioning post 3011 is connected to the handle body 301, and the elastic part 304 is engaged with the positioning post 3011, with one end of the elastic part 304 abutting against the abutment platform 103.
[0110] Specifically, such as Figure 2 , Figure 3As shown, the positioning post 3011 is connected to the rod body 301 and is specifically disposed on the side wall of the rod body 301. When the elastic part 304 is sleeved on the rod body 301, the positioning post 3011 can pass through the gap of the elastic part 304, so that the elastic part 304 is engaged with the rod body 301. The inner wall of the mop handle 1 can be provided with an abutment platform 103, and one end of the elastic part 304 can abut against the abutment platform 103. The abutment platform 103 can specifically be an annular structure on the inner wall of the mop handle 1. The abutment platform 103 can be provided with a through hole for the rod body 301 to pass through. When the rod body 301 moves in the first direction, the elastic part 304 is compressed between the abutment platform 103 and the positioning post 3011. The elastic part 304 is sleeved on the rod body 301, which also serves to limit the movement of the rod body 301, preventing it from tilting during movement. Furthermore, it should be understood that the rod body 301 is fixed to the elastic part 304 by the positioning post 3011, and the elastic part 304 abuts against the abutment platform 103, further limiting the movement of the rod body 301 and preventing it from moving too far relative to the mop handle 1, thus preventing the rod body 301 from detaching from the mop handle 1.
[0111] Furthermore, in other embodiments, the elastic part 304 may be configured such that one end is connected to the outer wall of the rod 301, and the other end is connected to the inner wall of the mop handle 1. This way, when the rod 301 moves relative to the mop handle 1, the elastic part 304 can be compressed, thereby giving the elastic part 304 elastic potential energy, or increasing the elastic potential energy of the elastic part 304. Alternatively, the elastic part 304 may be stretched when the rod 301 moves along the first direction, thus still possessing elastic potential energy. Multiple elastic parts 304 can also be provided, and these multiple elastic parts 304 can be distributed circumferentially along the rod 301, making the connection between the rod 301 and the mop handle 1 more stable and reliable.
[0112] In one embodiment, such as Figures 2-5 As shown, the first limiting part 4 also has a fifth guide surface 405. When the sleeve 2 moves in the second direction, the second limiting part 201 slides along the fifth guide surface 405 so that the second limiting part 201 pushes the first limiting part 4 to move in the third direction.
[0113] Specifically, such as Figure 4 , Figure 5As shown, when the drive member 3 moves along the first direction until the first limiting part 4 separates from the second limiting part 201, the first limiting part 4 protrudes from the side wall of the mop handle 1 under the action of the elastic part 304 and is disposed opposite to the second limiting part 201. When the sleeve 2 moves along the second direction, the second limiting part 201 moves along the second direction with the sleeve 2. If the first limiting part 4 is still opposite to the second limiting part 201, the first limiting part 4 will block the second limiting part 201, making it impossible for the second limiting part 201 to move to the upper side of the first limiting part 4. As a result, the first limiting part 4 cannot support the second limiting part 201. Therefore, the user needs to press the pressing part 5 to make the first limiting part 4 move along the third direction to avoid the second limiting part 201. In order to simplify the user's operation, the first limiting part 4 can also be provided with a fifth guide surface 405. When the first limiting part 4 is opposite to the second limiting part 201, and the second limiting part 201 moves along the second direction to contact the first limiting part 4, the second limiting part 201 can slide along the fifth guide surface 405 of the first limiting part 4, so that the second limiting part 201 can push the first limiting part 4 to move along the third direction, so that the first limiting part 4 can avoid the second limiting part 201. In this way, the second limiting part 201 can move above the first limiting part 4. Under the restoring deformation force of the elastic part 304, the first limiting part 4 can move again to be opposite to the second limiting part 201, so that the first limiting part 4 can be supported by the second limiting part 201. In this way, during the process of the sleeve 2 moving and resetting along the second direction, the user does not need to press the pressing part 5, thus making the mop operation simpler and more convenient.
[0114] Furthermore, such as Figures 2-5 As shown, the fifth guide surface 405 of the first limiting part 4 can be configured to intersect with the axis of the mop handle 1, so that when the mop is erected on a horizontal surface, the fifth guide surface 405 of the first limiting part 4 is inclined relative to the horizontal surface. When the second limiting part 201 moves along the second direction, during the process of the second limiting part 201 contacting the first limiting part 4 and sliding along the fifth guide surface 405, the second limiting part 201 can form a force on the first limiting part 4 in the third direction, thereby allowing the second limiting part 201 to push the first limiting part 4 to move in the third direction, and then allowing the second limiting part 201 to push away the first limiting part 4 so that the second limiting part 201 can continue to move in the second direction to the upper side of the first limiting part 4. At this time, the second limiting part 201 no longer blocks the first limiting part 4 in the fourth direction, and the first limiting part 4 can move in the fourth direction under the action of the restoring deformation force of the elastic part 304, so that the first limiting part 4 and the second limiting part 201 are opposite to each other to support the second limiting part 201, and finally the sleeve 2 can be fixed relative to the mop handle 1 in the axial direction.
[0115] In one embodiment, such as Figure 1 As shown, the sleeve 2 can rotate relative to the mop handle 1 in the circumferential direction of the mop handle 1.
[0116] Specifically, such as Figure 1 As shown, when the sleeve 2 moves to its limit position along the second direction, the distance between the two ends of the scrubbing part 8 is maximized. At this point, the scrubbing part 8 can be twisted to squeeze out the water by rotating the sleeve 2 and the mop handle 1 relative to each other along the circumference of the mop handle 1. Specifically, the user can rotate the mop handle 1 relative to the sleeve 2 by holding the sleeve 2 and rotating the mop handle 1, or by holding the mop handle 1 and rotating the sleeve 2. It should be understood that when the scrubbing part 8 is twisted, as the degree of twisting of the scrubbing part 8 gradually increases, the counterforce formed by the toughness of the scrubbing part 8 itself becomes stronger. If the torque applied by the user to the mop handle 1 decreases or disappears, the scrubbing part 8 will automatically rotate back in the opposite direction to the twisting direction under its own toughness, thus preventing the scrubbing part 8 from being fully squeezed out of the water.
[0117] In one embodiment, such as Figure 1 , Figure 4 , Figure 5 As shown, the mop also includes a third limiting part 202. The sleeve 2 can rotate around the mop handle 1 in the fifth direction, and the third limiting part 202 can restrict the sleeve 2 from rotating around the mop handle 1 in the sixth direction. The fifth direction and the sixth direction are opposite to each other.
[0118] In one embodiment, such as Figure 1 , Figure 4 , Figure 5 As shown, the third limiting part 202 is provided on the sleeve 2, and the third limiting part 202 can be fixed relative to the first limiting part 4 in the sixth direction.
[0119] Specifically, such as Figure 1 , Figure 4 , Figure 5As shown, to solve the problems in the above embodiments, the mop can also be provided with a third limiting part 202. The third limiting part 202 is disposed between the mop handle 1 and the sleeve 2. The sleeve 2 can rotate in either the fifth or sixth direction. The fifth and sixth directions are both circumferential directions of the mop handle 1 and are opposite to each other. The third limiting part 202 can restrict the relative rotation of the sleeve 2 and the mop handle 1 in the sixth direction, so that the sleeve 2 can only rotate relative to the mop handle 1 in the fifth direction, thereby achieving the purpose of unidirectional rotation of the sleeve 2. In this way, when the user rotates the mop handle 1 to make the mop handle 1 and the sleeve 2 rotate relative to each other in the fifth direction, so that the scrubbing part 8 is twisted, if the user needs to rest or Adjusting the user's grip on the mop handle 1 will reduce the torque applied to the mop handle 1 or cause the user to stop applying torque to the mop handle 1. The third limiting part 202 can restrict the relative rotation of the sleeve 2 and the mop handle 1 in the sixth direction, so that the scrubbing part 8 will not rotate in the opposite direction under its own torsional force, so that the scrubbing part 8 can be kept in a twisted state, which makes it convenient for the user to rest or adjust the grip on the mop handle 1. After the user has rested or adjusted the grip on the mop handle 1, the user can apply torque to the mop handle 1 again to make the mop handle 1 and the sleeve 2 rotate relative to each other in the fifth direction, so that the scrubbing part 8 can continue to be twisted, ultimately making the scrubbing part 8 of the mop more efficient at wringing out.
[0120] In one embodiment, such as Figure 1 , Figure 4 , Figure 5 As shown, the third limiting part 202 is a limiting groove provided on the inner wall of the sleeve 2. When the sleeve 2 and the mop handle 1 are fixed relative to each other, the first limiting part 4 is located in the limiting groove, and the inner wall of the limiting groove abuts against the first limiting part 4.
[0121] Specifically, such as Figure 1 , Figure 4 , Figure 5 As shown, when the sleeve 2 is subjected to a force in the sixth direction, or the mop handle 1 is subjected to a force in the fifth direction, with the sleeve 2 and the mop handle 1 relatively fixed, the third limiting part 202 can be relatively fixed to the first limiting part 4, thereby preventing the sleeve 2 from rotating relative to the mop handle 1 in the sixth direction. Specifically, the third limiting part 202 can be configured as a limiting groove formed in the inner wall of the sleeve 2, and the first limiting part 4 can be located within the limiting groove. When the first limiting part 4 is located within the limiting groove, the inner wall of the limiting groove can limit the first limiting part 4 in the fifth direction.
[0122] In one embodiment, such as Figure 1 , Figure 4 , Figure 5As shown, the limiting groove has a first limiting surface 2021 and a third guiding surface 2022, and the first limiting part 4 has a second limiting surface 403 and a fourth guiding surface 404 facing away from each other. When the sleeve 2 is subjected to a force in the sixth direction or the mop handle 1 is subjected to a force in the fifth direction, the first limiting surface 2021 abuts against the second limiting surface 403. When the sleeve 2 is subjected to a force in the fifth direction, the third guiding surface 2022 slides along the fourth guiding surface 404.
[0123] Specifically, such as Figure 1 , Figure 4 , Figure 5 As shown, the limiting groove can be provided with a first limiting surface 2021. Specifically, the first limiting surface 2021 of the limiting groove is the side wall of the limiting groove. When the sleeve 2 or the mop handle 1 is subjected to an external force, causing the first limiting part 4 to be subjected to a force in the fifth direction within the limiting groove, the first limiting part 4 has a tendency to rotate relative to the sleeve 2 in the fifth direction. At this time, the first limiting part 4 can abut against the first limiting surface 2021 of the limiting groove. The first limiting surface 2021 of the limiting groove can block the first limiting part 4, so that the first limiting part 4 cannot rotate in the fifth direction, thereby preventing the sleeve 2 and the mop handle 1 from rotating relative to each other in the sixth direction.
[0124] Furthermore, such as Figure 1 , Figure 4 , Figure 5 As shown, when the sleeve 2 or the mop handle 1 is subjected to an external force, causing the first limiting part 4 to be subjected to a force in the sixth direction within the limiting groove, the first limiting part 4 can slide within the limiting groove, allowing it to rotate relative to the mop handle 1 in the sixth direction. Multiple limiting grooves can be provided, arranged sequentially along the circumference of the sleeve 2. Correspondingly, a third guide surface 2022 can be provided within the limiting groove. When the first limiting part 4 rotates in the sixth direction, it can slide along the third guide surface 2022 of the limiting groove, allowing it to slide from any limiting groove into an adjacent limiting groove, thus enabling continuous rotation of the first limiting part 4 in the sixth direction.
[0125] Furthermore, such as Figure 1 , Figure 4 , Figure 5As shown, the third guide surface 2022 of the limiting groove is an inclined surface extending from the bottom wall of the limiting groove to the opening of the limiting groove. When the first limiting part 4 slides along the third guide surface 2022 of the limiting groove, the force exerted on the first limiting part 4 by the third guide surface 2022 moves the first limiting part 4 in the third direction. This allows the first limiting part 4 to slide out of the limiting groove from the third guide surface 2022. At this time, the elastic part 304 is compressed. When the first limiting part 4 moves to the opening of an adjacent limiting groove, the restoring deformation force of the elastic part 304 can drive the first limiting part 4 to move in the fourth direction, so that the first limiting part 4 can enter the adjacent limiting groove. Subsequently, the first limiting part 4 can continue to slide along the third guide surface 2022 of the limiting groove, and repeat the above steps so that the first limiting part 4 can slide into each limiting groove in the sixth direction and slide out of each limiting groove in turn.
[0126] Furthermore, such as Figure 1 , Figure 4 , Figure 5 As shown, the first limiting part 4 may specifically be provided with a second limiting surface 403 and a fourth guiding surface 404. When the first limiting part 4 abuts against the limiting groove, the second limiting surface 403 of the first limiting part 4 abuts against the first limiting surface 2021 of the limiting groove, so that the first limiting part 4 is fixed in the limiting groove. The fourth guiding surface 404 of the first limiting part 4 may be configured to cooperate with the third guiding surface 2022 of the limiting groove. When the first limiting part 4 slides along the third guiding surface 2022 of the limiting groove, the fourth guiding surface 404 of the first limiting part 4 can slide and cooperate with the third guiding surface 2022 of the limiting groove, so that the first limiting part 4 can slide more smoothly along the third guiding surface 2022 of the limiting groove.
[0127] In one embodiment, such as Figure 1 , Figure 4 , Figure 5 As shown, when the sleeve 2 rotates relative to the mop handle 1 in the circumferential direction of the mop handle 1, the sleeve 2 drives one end of the mop strip to rotate relative to the mop handle 1, causing the mop strip to deform and store power.
[0128] Specifically, such as Figure 1 , Figure 4 , Figure 5 As shown, when the second limiting part 201 is not provided, the sleeve 2 and the mop handle 1 are fixed by the third limiting part 202.
[0129] Although embodiments of the present invention have been described in conjunction with the accompanying drawings, those skilled in the art can make various modifications and variations without departing from the spirit and scope of the present invention, and such modifications and variations all fall within the scope defined by the appended claims.
Claims
1. A mop, characterized in that, include: The mop handle (1) is equipped with an inlet and outlet (101). Mounting base (7) is connected to the mop handle (1), and the mounting base (7) is connected to a scrubbing part (8). The sleeve (2) is movably sleeved on the mop handle (1) to drive the scrubbing part (8) to move; A first limiting part (4) is provided on the mop handle (1). The first limiting part (4) includes a limiting tooth (40) adapted to be driven to extend or retract the inlet and outlet (101). When the limiting tooth (40) extends out of the inlet / outlet (101), it limits the sleeve (2) so that the sleeve (2) and the mop handle (1) are relatively fixed; when the limiting tooth (40) retracts into the inlet / outlet (101), it releases the limitation on the sleeve (2) so that the sleeve (2) and the mop handle (1) can move relative to each other.
2. The mop according to claim 1, characterized in that, It also includes a drive member (3) disposed inside the mop handle (1) and connected to the first limiting part (4), the drive member (3) can drive the first limiting part (4) so that the limiting tooth (40) extends or retracts from the inlet and outlet (101).
3. The mop according to claim 2, characterized in that, The mop handle (1) is provided with an installation port (102). The mop also includes a pressing part (5) that extends at least partially from the installation port (102) of the mop handle (1). The pressing part (5) is movably disposed on the mop handle (1) and connected to the driving member (3). The pressing part (5) is adapted to drive the driving member (3) so that the driving member (3) drives the first limiting part (4).
4. The mop according to claim 3, characterized in that, The inlet / outlet (101) and the mounting port (102) are located on the side wall of the mop handle (1).
5. The mop according to claim 3, characterized in that, The portion of the pressing part (5) extending out of the mop handle (1) is configured as a control part (6), which is suitable for the user to apply force to the control part (6) so that the control part (6) drives the pressing part (5) to move.
6. The mop according to any one of claims 2-5, characterized in that, It also includes a second limiting part (201) connected to the sleeve (2). When the limiting tooth (40) extends out of the inlet and outlet (101), it connects with the second limiting part (201) so that the sleeve (2) and the mop handle (1) are relatively fixed. When the limiting tooth (40) retracts into the inlet and outlet (101), it separates from the second limiting part (201) so that the sleeve (2) and the mop handle (1) can move relative to each other.
7. The mop according to claim 6, characterized in that, The second limiting part (201) is disposed on the inner wall of the sleeve (2).
8. The mop according to claim 7, characterized in that, With the first limiting part (4) and the second limiting part (201) fixed, the first limiting part (4) supports the second limiting part (201) axially on the mop handle (1).
9. The mop according to claim 7 or 8, characterized in that, The sleeve (2) can move along a first direction or a second direction, the first direction and the second direction being opposite to each other and in the same direction as the axial direction of the mop handle (1); when the sleeve (2) moves along the first direction, the distance between the sleeve (2) and the mounting base (7) decreases; when the sleeve (2) moves along the second direction, the distance between the sleeve (2) and the mounting base (7) increases.
10. The mop according to claim 9, characterized in that, The driving member (3) can drive the first limiting part (4) to move along a third or fourth direction so that the first limiting part (4) is misaligned or opposite to the second limiting part (201), the third and fourth directions are opposite to each other and intersect with the axis of the mop handle (1).
11. The mop according to claim 10, characterized in that, The third direction is perpendicular to the axis of the mop handle (1).
12. The mop according to claim 10, characterized in that, The driving member (3) is movably disposed on the mop handle (1). The driving member (3) can move along the first direction or the second direction to drive the first limiting part (4) to move along the third direction or the fourth direction.
13. The mop according to any one of claims 10-12, characterized in that, The first limiting part (4) has a first guide surface (401) which intersects the axis of the mop handle (1). When the driving member (3) moves along the first direction or the second direction, the driving member (3) slides relative to the first limiting part (4) along the first guide surface (401) to push the first limiting part (4) to move along the third direction or the fourth direction.
14. The mop according to claim 13, characterized in that, The first limiting part (4) has a first guide groove (402), and the first guide surface (401) is the inner wall of the first guide groove (402). The driving member (3) includes a rod (301) and a first movable part (302) connected to each other. The first movable part (302) is embedded in the first guide groove (402), and the first movable part (302) can slide along the first guide surface (401).
15. The mop according to any one of claims 10-12, 14, characterized in that, When the mop includes a pressing part (5), the pressing part (5) is movably disposed on the side wall of the mop handle (1), and the pressing part (5) is connected to the driving member (3). The pressing part (5) can move along the third direction or the fourth direction to drive the driving member (3) to move along the first direction or the second direction.
16. The mop according to claim 15, characterized in that, The pressing part (5) has a second guide surface (501) which intersects the axis of the mop handle (1). The driving member (3) slides along the second guide surface (501) to push the driving member (3) to move along the first direction or the second direction.
17. The mop according to claim 16, characterized in that, The pressing part (5) is provided with a second guide groove (502), and the second guide surface (501) is the inner wall of the second guide groove (502). The driving member (3) includes a rod (301) and a second movable part (303) connected to each other. The second movable part (303) is embedded in the second guide groove (502) and can slide along the second guide surface (501).
18. The mop according to claim 17, characterized in that, The first limiting part (4) has a first guide surface (401), which is parallel to the second guide surface (501).
19. The mop according to any one of claims 10-12, 14, 16-18, characterized in that, The driving member (3) includes a rod (301) and an elastic part (304). The elastic part (304) is connected to the rod (301) and the mop handle (1). When the rod (301) moves in the first direction, the elastic part (304) deforms, and the restoring deformation force of the elastic part (304) can drive the rod (301) to move in the second direction.
20. The mop according to claim 19, characterized in that, The elastic part (304) is fixedly sleeved on the rod body (301), and one end of the elastic part (304) abuts against the mop handle (1).
21. The mop according to claim 20, characterized in that, The mop handle (1) is provided with an abutment platform (103), and the drive component (3) also includes a positioning post (3011). The positioning post (3011) is connected to the handle body (301), and the elastic part (304) is engaged with the positioning post (3011), with one end of the elastic part (304) abutting against the abutment platform (103).
22. The mop according to any one of claims 10-12, 14, 16-18, 20, and 21, characterized in that, The first limiting part (4) also has a fifth guide surface (405). When the sleeve (2) moves in the second direction, the second limiting part (201) slides along the fifth guide surface (405) so that the second limiting part (201) pushes the first limiting part (4) to move in the third direction.
23. The mop according to any one of claims 10-12, 14, 16-18, 20, and 21, characterized in that, The sleeve (2) can rotate relative to the mop handle (1) in the circumferential direction of the mop handle (1).
24. The mop according to claim 23, characterized in that, It also includes a third limiting part (202), the sleeve (2) can rotate around the mop handle (1) in a fifth direction, and the third limiting part (202) can restrict the sleeve (2) from rotating around the mop handle (1) in a sixth direction, the fifth direction and the sixth direction being opposite to each other.
25. The mop according to claim 24, characterized in that, The third limiting part (202) is disposed on the sleeve (2), and the third limiting part (202) can be fixed relative to the first limiting part (4) in the sixth direction.
26. The mop according to claim 24, characterized in that, The third limiting part (202) is a limiting groove provided on the inner wall of the sleeve (2). When the sleeve (2) and the mop handle (1) are fixed relative to each other, the first limiting part (4) is located in the limiting groove, and the inner wall of the limiting groove abuts against the first limiting part (4).
27. The mop according to claim 26, characterized in that, The limiting groove has a first limiting surface (2021) and a third guiding surface (2022). The first limiting part (4) has a second limiting surface (403) and a fourth guiding surface (404) facing away from each other. When the sleeve (2) is subjected to the force in the sixth direction or the mop handle (1) is subjected to the force in the fifth direction, the first limiting surface (2021) abuts against the second limiting surface (403). When the sleeve (2) is subjected to the force in the fifth direction, the third guiding surface (2022) slides along the fourth guiding surface (404).
28. The mop according to any one of claims 25-27, characterized in that, When the sleeve (2) rotates relative to the mop handle (1) in the circumferential direction of the mop handle (1), the sleeve (2) drives one end of the mop strip to rotate relative to the mop handle (1), causing the mop strip to deform and store power.