CN213787236U - Switch for mop bucket and mop bucket - Google Patents

Abstract

The application provides a switch and mop bucket for mop bucket, switch for mop bucket include slider and installed part, the installed part is used for installing on the mop bucket, the slider with installed part sliding connection, slider one end is for pressing the end, and the other end is for promoting the end, the promotion end of slider is used for promoting the last break-make valve of mop bucket inhalant canal, in order to control break-make valve break-make. The mop bucket includes the staving and as above switch for the mop bucket, the staving is provided with inhalant canal, the inhalant canal of staving is provided with the on-off valve, switch for the mop bucket is installed on the staving and be used for control the on-off valve break-make. The switch for the mop bucket and the mop bucket adopted by the application control the on-off valve to be switched on and off in a linear sliding mode, so that the structure is more compact, and the size of the mop bucket is favorably reduced.

Description

Switch for mop bucket and mop bucket

Technical Field

The application belongs to the technical field of cleaning supplies, and more specifically relates to a switch for a mop bucket and the mop bucket.

Background

Clean and tidy home environments allow one to relax while working, and therefore require constant cleaning including floor cleaning in life. The mop is one of the most widely used floor cleaning products in daily life, a plurality of types such as a water-wringing mop, a collodion mop, a rotary mop and a flat mop are gradually evolved from the early traditional mop, and the mop bucket is greatly convenient for people to clean the mop.

In order to clean the mop, some mop barrels for cleaning the mop by using running water are available on the market at present, a water inlet channel is arranged on a barrel body of each mop barrel, an on-off valve for controlling the on-off of water flow in each water inlet channel is arranged on each water inlet channel, the on-off valve is connected with a control switch, each control switch is of a seesaw structure, when the mop needs to be cleaned, one end of each seesaw structure is trampled to enable the seesaw structure to rotate, the other end of each seesaw structure can control the on-off valve to be opened, so that the running water in each water inlet channel is flushed towards the mop, and the mop is cleaned more cleanly. However, the control switch of the "seesaw structure" generally has a large length and requires a large space of the mop bucket, which results in an increase in the volume of the mop bucket.

Disclosure of Invention

An object of the embodiment of the application is to provide a switch for a mop bucket and the mop bucket, so that the technical problem that the switch of the mop bucket occupies more space and the size of the mop bucket is increased in the prior art is solved.

In order to achieve the purpose, the technical scheme adopted by the application is as follows: the utility model provides a switch for mop bucket, includes slider and installed part, the installed part is used for installing on the mop bucket, the slider with installed part sliding connection, slider one end is for pressing the end, and the other end is the promotion end, the promotion end of slider is used for promoting the last break-make valve of mop bucket inhalant canal, with control break-make valve break-make.

Optionally, the device further comprises a swing rod, wherein a rotating part is arranged at one end of the swing rod, and a sliding part is arranged at the other end of the swing rod; the mounting piece is provided with a connecting structure which is rotatably connected with the rotating part, and the sliding part is provided with an annular sliding groove for the sliding part to be embedded and slide; or the sliding part is provided with a connecting structure which is rotationally connected with the rotating part, and the mounting part is provided with an annular sliding groove for the sliding part to be embedded and slide; annular spout is annular lift guide way, fixed slot and return stroke guide way including the end to end intercommunication in proper order, the inboard cell wall of fixed slot court the sunken setting of direction of rotation portion.

Optionally, a joint between a groove wall of the lift guide groove and a groove wall of the fixing groove, a joint between a groove wall of the return guide groove and a groove wall of the fixing groove, and a joint between a groove wall of the return guide groove and a groove wall of the lift guide groove all have a step surface.

Optionally, the mounting member is provided as a cylindrical structure, and the sliding member is slidably inserted into the mounting member.

Optionally, the connection structure is a jack for inserting and rotating the rotating part, the jack is provided on the outer surface of the mounting part, the annular chute is provided on the sliding part, the switch for the mop bucket further comprises a limiting part for preventing the rotating part from coming off the jack and preventing the sliding part from coming off the annular chute.

Optionally, the limiting member is an annular structure, and an annular groove for accommodating the limiting member is formed in the outer circumferential surface of the mounting member.

Optionally, the inner peripheral surface of the mounting member is provided with a guide sliding block, the sliding member is of a rod-shaped structure, a guide sliding groove extending along the axial direction of the sliding member is formed in the surface of the sliding member, and the guide sliding block is slidably disposed in the guide sliding groove.

Optionally, the guide sliding block has a first arc-shaped sliding surface, the guide sliding chute has a second arc-shaped sliding surface, and the first arc-shaped sliding surface of the guide sliding block is in sliding fit with the second arc-shaped sliding surface of the guide sliding chute along the axis direction of the sliding member.

Optionally, the sliding device further comprises an elastic member, one end of the elastic member is connected to the pressing end of the sliding member, and the other end of the elastic member is connected to the mounting member.

Optionally, the pressing end of the sliding part is fixedly connected with a top cover, a fixing column is arranged on the inner surface of the top cover, and a fixing hole in interference fit with the fixing column is formed in the pressing end of the sliding part.

Optionally, the sliding device further comprises a housing and a fixing sleeve, the housing is provided with a mounting hole, the mounting part is located on the inner side of the housing, the fixing sleeve is located on the outer side of the housing, the mounting part and the fixing sleeve are mutually sleeved at the mounting hole, the wall of the housing around the mounting hole is clamped between the clamping part of the mounting part and the clamping part of the fixing sleeve, and the sliding part is movably inserted into the fixing sleeve.

Optionally, the housing is rotatably connected with a swinging member, the on-off valve is fixedly mounted on the housing, one side surface of the swinging member is in butt fit with the pushing end of the sliding member, and the other side surface of the swinging member, which is opposite to the swinging member, is in butt fit with the on-off valve.

Optionally, a clamping block is arranged on the hole wall of the mounting hole of the housing, and a clamping groove for the clamping block to be embedded into is formed in the outer peripheral surface of the mounting piece.

The embodiment of the application still provides a mop bucket, include the staving and as above switch for the mop bucket, the staving is provided with inhalant canal, the inhalant canal of staving is provided with the on-off valve, switch mounting for the mop bucket is in be used for controlling on the staving on-off valve break-make.

This application embodiment has following beneficial effect at least, and through the structural design of slider and installed part, the user can make the slider slide on the installed part through trampling or pressing the end of pressing of slider, and then makes the promotion end of slider promote the on-off valve on the mop bucket inhalant canal, makes the inhalant canal intercommunication. The user loosens the pressing end of the sliding part, the on-off valve pushes the pushing end of the sliding part to slide reversely under the action of the spring structure of the on-off valve, so that the sliding part returns to the original position, and the water inlet channel is closed at the moment. Compare in prior art's the control switch of "seesaw structure", the switch for the mop bucket that this application adopted controls the break-make of break-make valve through the mode that the straight line slided, and the structure is compacter, consequently occupies the less space of mop bucket to be favorable to dwindling the volume of mop bucket.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present application, the drawings needed to be used in the embodiments or the prior art descriptions will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present application, and it is obvious for those skilled in the art to obtain other drawings based on these drawings without inventive exercise.

FIG. 1 is a schematic view of the structure of a switch, a swing member and an on-off valve for a mop bucket in an embodiment of the present application;

FIG. 2 is a schematic view showing the assembly of the switch, the swing member and the on-off valve for the mop bucket in the embodiment of the present application;

FIG. 3 is a cross-sectional view of a switch for a mop bucket in an embodiment of the present application;

FIG. 4 is a schematic structural diagram of a slider according to an embodiment of the present application;

FIG. 5 is a schematic structural view of a mounting member in an embodiment of the present application;

FIG. 6 is a schematic structural diagram of another lift guide groove, fixed groove and return guide groove in the embodiment of the present application;

FIG. 7 is a schematic view of the switch for the mop bucket of the embodiment of the present application installed in the housing;

FIG. 8 is a structural sectional view of the on-off valve in the embodiment of the present application;

FIG. 9 is a schematic view of the structure of a mop bucket in an embodiment of the present application.

Wherein, each mark in the figure is:

1. a switch for the mop bucket; 11. a slider; 111. a lift guide groove; 112. fixing grooves; 113. a return guide groove; 114. a step surface; 1151. a first guide slope; 1152. a second guide slope; 1153. a third guide slope; 116. a first convex ring; 117. a guide chute; 118. a fixing hole; 119. a second guide chute; 12. a mounting member; 121. a jack; 122. a second convex ring; 123. a limiting member; 124. an annular groove; 125. a guide slider; 126. an external thread; 127. a card slot; 128. a second guide slider; 13. a swing rod; 131. a rotating part; 132. a sliding part; 14. an elastic member; 15. a top cover; 151. fixing a column; 2. a housing; 21. mounting holes; 3. fixing a sleeve; 31. an internal thread; 4. a swinging member; 5. an on-off valve; 51. a deflector rod; 52. a valve stem; 53. a valve core; 54. a pressure spring; 55. a water inlet; 56. a water outlet; 6. and (5) a barrel body.

Detailed Description

In order to make the technical problems, technical solutions and advantageous effects to be solved by the present application clearer, the present application is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the present application and are not intended to limit the present application.

It will be understood that when an element is referred to as being "secured to" or "disposed on" another element, it can be directly on the other element or be indirectly on the other element. When an element is referred to as being "connected to" another element, it can be directly or indirectly connected to the other element. The terms "upper", "lower", "left", "right", and the like, indicate orientations or positional relationships based on those shown in the drawings, are merely for convenience of description, and do not indicate or imply that the referred devices or elements must have a specific orientation, be constructed in a specific orientation, and operate, and thus are not to be construed as limiting the patent, and the specific meanings of the above terms will be understood by those skilled in the art according to specific situations. The terms "first", "second" and "first" are used merely for descriptive purposes and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features. The meaning of "plurality" is two or more unless specifically limited otherwise.

The embodiment of the application provides a switch for mop bucket, as shown in fig. 1-5, including slider 11 and installed part 12, installed part 12 is used for installing on the mop bucket, slider 11 and installed part 12 sliding connection, and slider 11 one end is for pressing the end, and the other end is the catch, and the catch of slider 11 is used for promoting the on-off valve 5 on the mop bucket inhalant canal to control the on-off valve 5 break-make.

Through the structural design of slider 11 and installed part 12, the user can make slider 11 slide on installed part 12 through stepping on or pressing the end of pressing of slider 11, and then makes the promotion end of slider 11 promote the on-off valve 5 on the mop bucket inhalant canal, makes the inhalant canal intercommunication. When the user releases the pressing end of the sliding part 11, the on-off valve 5 pushes the pushing end of the sliding part 11 to slide reversely under the action of the spring structure of the on-off valve, so that the sliding part 11 returns to the original position, and the water inlet channel is closed. Compare in the control switch of among the prior art "seesaw structure", switch 1 for the mop bucket that this application adopted controls the break-make valve through the gliding mode of straight line, and the structure is compacter, consequently occupies the less space of mop bucket to be favorable to dwindling the volume of mop bucket.

In one embodiment, the switch 1 for a mop bucket further includes a swing lever 13, and one end of the swing lever 13 is provided with a rotating part 131 and the other end is provided with a sliding part 132. The mounting member 12 is provided with a connecting structure rotatably connected with the rotating part 131, and the sliding member 11 is provided with an annular sliding groove for the sliding part 132 to be embedded and slide; alternatively, the slider 11 is provided with a connecting structure rotatably connected to the rotating portion 131, and the mounting member 12 is provided with an annular sliding groove into which the sliding portion 132 is inserted and slides. The annular sliding groove includes a lift guide groove 111, a fixing groove 112 and a return guide groove 113 which are sequentially connected end to form an annular shape, and an inner groove wall of the fixing groove 112 is recessed toward the rotating portion 131.

In the initial state, the sliding portion 132 of the rocker 13 is located at the lower end of the lift guide groove 111, the user steps on the foot or presses the pressing end of the slider 11 with the hand to slide the slider 11 downward in the mounting member 12 along the axial direction thereof, and the sliding portion 132 of the rocker 13 slides upward relative to the slider 11 along the lift guide groove 111; the user's foot is released from the slider 11 and the sliding portion 132 slides relatively leftward within the fixed slot 112 to the depression in the inner slot wall of the fixed slot 112, so that the sliding portion 132 is "caught" in the depression in the inner slot wall of the fixed slot 112 and is fixed. When the slide part 132 is fixed at the position of the depression of the inner wall of the fixed groove 112, the slider 11 is extended downward relative to the mounting member 12 by a distance (i.e., the distance between the lower end of the lift guide groove 111 and the depression of the inner wall of the fixed groove 112) as compared with the position where the slide part 132 is located at the lower end of the lift guide groove 111, so that the push end of the slider 11 can continuously give a pressing force to the on-off valve 5 to keep the on-off valve 5 open.

The user's foot steps on the slider 11 again, and the sliding portion 132 relatively continues to slide leftward in the fixed groove 112 to a position where the fixed groove 112 communicates with the return guide groove 113; the user's foot is released from the slider 11 again, and the pushing end of the slider 11 slides upward by the spring structure of the on-off valve 5, so that the sliding portion 132 slides relatively downward in the return guide groove 113, and finally enters the lower end of the lift guide groove 111. In the process that the sliding part 132 relatively slides downwards to the lower end of the lifting guide groove 111, the sliding piece 11 slides upwards in the mounting piece 12 along the axial direction of the sliding piece, so that the on-off valve 5 loses the pressing force of the sliding piece 11, and the on-off valve 5 of the mop bucket is changed from the opening state to the closing state.

This application embodiment is through slider 11, installed part 12, the structural design of pendulum rod 13, the user is opening and the in-process of closing through the on-off valve 5 of switch 1 control mop bucket for the mop bucket, only need trample once just can let on-off valve 5 open, it just can let on-off valve 5 close once to trample again, and need not step on switch 1 for the mop bucket with the foot always, consequently can reduce the tired sense of foot in switch 1's for the mop bucket use, it is more convenient to use.

In one embodiment, as shown in fig. 4, a junction of a groove wall of the lift guide groove 111 and a groove wall of the fixing groove 112, a junction of a groove wall of the fixing groove 112, a groove wall of the return guide groove 113 and a groove wall of the fixing groove 112, and a junction of a groove wall of the return guide groove 113 and a groove wall of the lift guide groove 111 have a step surface 114. The arrangement of the four step surfaces 114 can make the sliding part 132 generate vibration feedback in the sliding process of the sliding part 132, so that a user can sense the position to which the sliding part 132 slides; on the other hand, the slide portion 132 may be configured to be slidable only from the lift guide groove 111 to the fixed groove 112, from the connection between the fixed groove 112 and the lift guide groove 111 to the connection between the fixed groove 112 and the return guide groove 113, from the fixed groove 112 to the return guide groove 113, and from the return guide groove 113 to the lift guide groove 111, but not slidable from the lift guide groove 111 to the return guide groove 113, from the return guide groove 113 to the fixed groove 112, from the connection between the fixed groove 112 and the return guide groove 113 to the connection between the fixed groove 112 and the lift guide groove 111, and from the fixed groove 112 to the lift guide groove 111.

When the user's foot steps on the slider 11 to slide downward, the step surface 114 at the junction between the groove wall of the return guide groove 113 and the groove wall of the lift guide groove 111 prevents the sliding portion 132 of the rocker 13 from entering the return guide groove 113 (i.e., blocks the reverse sliding of the sliding portion 132), and the sliding portion 132 of the rocker 13 can only slide upward along the lift guide groove 111 relative to the slider 11 and enter the fixed groove 112 after passing through the step surface 114 at the junction between the groove wall of the lift guide groove 111 and the groove wall of the fixed groove 112. The sliding portion 132 passes through the step surface 114 at the junction of the groove wall of the lift guide groove 111 and the groove wall of the fixing groove 112 to be vibrated, and the vibration can be fed back to the user to allow the user to determine that the sliding portion 132 has entered the fixing groove 112, and the user's foot is released from the slider 11.

The step surface 114 at the junction of the groove wall of the lift guide groove 111 and the groove wall of the fixing groove 112 blocks the sliding portion 132 from sliding into the lift guide groove 111 (i.e., blocks the reverse sliding of the sliding portion 132), so that the sliding portion 132 can only slide relatively leftward in the fixing groove 112 to the recess of the inner groove wall of the fixing groove 112 and then be fixed in the fixing groove 112. The sliding portion 132 may vibrate when passing through the step surface 114 of the groove wall of the fixing groove 112, and the vibration may be fed back to a user so that the user may determine that the sliding portion 132 has slid to the recess of the inner groove wall of the fixing groove 112 and is fixed.

When the user's foot steps on the slider 11 again, the sliding portion 132 slides to the right to the connection between the lift guide groove 111 and the fixed groove 112 (i.e., the reverse sliding of the sliding portion 132 is blocked) due to the step surface 114 of the groove wall of the fixed groove 112, so that the sliding portion 132 can only slide to the left relatively in the fixed groove 112 to the connection between the fixed groove 112 and the return guide groove 113. When the sliding portion 132 relatively slides leftward to the junction between the bottom of the fixed groove 112 and the bottom of the return guide groove 113 and enters the return guide groove 113 via the step surface 114 of the junction, vibration is given back to the user so that the user can determine that the sliding portion 132 has entered the return guide groove 113.

The user's foot is released from the slider 11 again, and since the stepped surface 114 at the junction of the groove wall of the return guide groove 113 and the groove wall of the fixed groove 112 blocks the sliding of the sliding portion 132 to the fixed groove 112 (i.e., blocks the reverse sliding of the sliding portion 132), the sliding portion 132 can only relatively slide downward in the return guide groove 113 under the elastic restoring force of the spring structure of the on-off valve 5, then passes through the stepped surface 114 at the junction of the groove wall of the return guide groove 113 and the groove wall of the lift guide groove 111, and finally enters the lower end of the lift guide groove 111. When the sliding portion 132 relatively slides down to the connection between the groove wall of the lift wire groove and the groove wall of the return guide groove 113 and enters the lower end of the lift guide groove 111 through the step surface 114 of the connection, vibration is generated, and the vibration can be fed back to the user so that the user can determine that the sliding portion 132 has entered the lower end of the lift guide groove 111.

In one embodiment, as shown in fig. 3 and 5, the mounting part 12 is configured as a cylindrical structure, and the sliding part 11 is slidably inserted into the mounting part 12, so that the structure is simple and the installation is convenient.

In one embodiment, as shown in fig. 2 and 3, the connection structure is a receptacle 121 for insertion and rotation of the rotating portion 131, the receptacle 121 being opened on the outer surface of the mounting member 12; the annular sliding groove is formed in the sliding member, and the switch 1 for a mop bucket further includes a stopper 123 for preventing the rotating portion from coming off the insertion hole and for preventing the sliding portion from coming off the annular sliding groove. By arranging the limiting member 123, the rotating portion 131 of the swing link 13 is not easily separated from the insertion hole 121 in the moving process, and the sliding portion 132 is not easily separated from the lift guide groove 111, the fixing groove 112 and the return guide groove 113, so that the structure is more stable.

In one embodiment, as shown in fig. 2 and 5, the limiting member 123 is an annular structure, such as an elastic rubber ring, a rope tied structure, and the like, and the mounting member 12 has an annular groove 124 formed on an outer peripheral surface thereof for receiving the limiting member 123. The limiting member 123 is sleeved in the annular groove 124 of the mounting member 12 and applies a downward pressure to the swing rod 13, so that the structure of the swing rod is more stable; the annular groove 124 on the outer peripheral surface of the mounting part 12 prevents the limiting part 123 from greatly deviating or separating from the mounting part 12 in the axial direction of the mounting part 12, and has a better limiting effect on the swing rod 13.

In one embodiment, as shown in fig. 3 and 4, the inner circumferential surface of the mounting member 12 is provided with a guide slider 125, the sliding member 11 is a rod-shaped structure, the surface of the sliding member 11 is provided with a guide sliding groove 117 extending along the axial direction of the sliding member 11, and the guide slider 125 is slidably disposed in the guide sliding groove 117. Through the sliding fit of the guide slider 125 and the guide chute 117, the sliding of the sliding member 11 along the axial direction thereof can be ensured without rotation around the axis thereof, so that the sliding member 11 and the swing link 13 can move more stably and reliably.

In one embodiment, as shown in fig. 3 and 4, the guide slider 125 has a first arc-shaped sliding surface, the guide chute 117 has a second arc-shaped sliding surface, and the first arc-shaped sliding surface of the guide slider 125 is slidably engaged with the second arc-shaped sliding surface of the guide chute 117 in the axial direction of the sliding member 11, so that the sliding member 11 slides more smoothly in the mounting member 12.

In one embodiment, as shown in fig. 2 and 3, the switch 1 for a mop bucket further includes an elastic member 14, and one end of the elastic member 14 is connected to the pressing end of the sliding member 11 and the other end is connected to the mounting member 12. The elastic member 14 may be a spring or the like, and the elastic member 14 is connected between the pressing end of the slider 11 and the mounting member 12, whereby the return operation of the slider 11 can be more flexible and reliable.

In one embodiment, as shown in fig. 2 and 3, the pressing end of the sliding member 11 has a first convex ring 116, the inner circumferential surface of the mounting member 12 has a second convex ring 122, one end of the elastic member 14 is in abutting engagement with the first convex ring 116, and the other end of the elastic member 14 is in abutting engagement with the second convex ring 122, so that the elastic member 14 can be compressed by the sliding member 11 and the mounting member 12, and the structure is simple and the installation is convenient.

In one embodiment, the connection between the groove wall of the lift guide groove 111 and the groove wall of the fixed groove 112, the connection between the groove wall of the fixed groove 112, the groove wall of the return guide groove 113 and the groove wall of the fixed groove 112, and the connection between the groove wall of the return guide groove 113 and the groove wall of the lift guide groove 111 may not have the step surface 114, and the sliding portion 132 may be slid only from the lift guide groove 111 to the fixed groove 112, from the connection between the fixed groove 112 and the lift guide groove 111 to the connection between the fixed groove 112 and the return guide groove 113, from the fixed groove 112 to the return guide groove 113, from the return guide groove 113 to the lift guide groove 111, and may not be slid from the lift guide groove 111 to the return guide groove 113, from the return guide groove 113 to the fixed groove 112, from the connection between the lift guide groove 112 and the return guide groove 113 to the connection between the fixed groove 112 and the guide groove 111, Sliding from the fixing groove 112 to the lift guide groove 111.

For example, as shown in fig. 6, the lower end of the inner side wall of the lift guide groove 111 has a first guide slope 1151 inclined toward the upper right, so that the slide portion 132 can slide only toward the upper right and cannot slide toward the upper left when relatively sliding upward in the lift guide groove 111 and enter the return guide groove 113; the upper end of the outer side wall of the lift guide groove 111 is provided with a second guide inclined surface 1152 inclined towards the upper left, so that the sliding part 132 can continue to slide towards the upper left for a distance and enter the fixing groove 112 after reaching the upper end of the lift guide groove 111, and the sliding part 132 falls to the inner side groove wall of the fixing groove 112 under the action of the elastic element 14 after the foot is released so as not to reversely slide towards the right to the lift guide groove 111; the outer side wall of the fixing groove 112 has a third guide slope 1153 which is located above the recess of the inner side wall thereof and is inclined toward the upper left, so that the sliding portion 132 can only slide along the third guide slope 1153 toward the upper left and into the return guide groove 113, and then relatively slide down to the lower end of the lift guide groove 111 during the step of the slider 11 by the foot.

In one embodiment, as shown in fig. 1 and 3, a top cover 15 is fixedly connected to the pressing end of the slider 11, a fixing post 151 is disposed on the inner surface of the top cover 15, and a fixing hole 118 that is in interference fit with the fixing post 151 is disposed on the end surface of the slider 11. The top cover 15 is arranged at one end of the sliding piece 11, the end face of the top cover 15 has a larger stress area, and the sliding piece 11 can be pressed by stepping on the end face of the top cover 15 through feet, so that stepping is more convenient; the top cover 15 is installed on the sliding part 11 through interference fit of the fixing column 151 and the fixing hole 118, and the structure is simple and the installation is convenient.

In one embodiment, as shown in fig. 2, 3 and 7, the switch 1 for mop bucket further comprises a housing 2 and a fixing sleeve 3, the housing 2 is provided with a mounting hole 21, the mounting member 12 is located inside the housing 2, the fixing sleeve 3 is located outside the housing 2, the mounting member 12 and the fixing sleeve 3 are sleeved with each other at the mounting hole 21, a shell wall around the mounting hole 21 is clamped between a clamping part of the mounting member 12 (i.e. an annular flange at the periphery of the mounting member 12) and a clamping part of the fixing sleeve 3 (i.e. an annular flange at the periphery of the fixing sleeve 3), and the sliding member 11 is movably inserted into the fixing sleeve 3. The inner peripheral surface of the fixing sleeve 3 is provided with an internal thread 31, and the outer peripheral surface of the mounting member 12 is provided with an external thread 126 which is in threaded engagement with the internal thread 31. Through the structural design of the shell 2 and the fixed sleeve 3, the sliding part 11, the mounting part 12, the elastic part 14, the swing rod 13 and other parts can be loaded and mounted on the shell 2, then the shell 2 can be mounted at the corresponding position of the mop, and the installation is more convenient.

In one embodiment, as shown in fig. 1, 2 and 8, the housing 2 is rotatably connected with a swinging member 4, an on-off valve 5 is fixedly mounted on the housing 2, one side surface of the swinging member 4 is in abutting engagement with the pressing end of the sliding member 11, and the other side of the swinging member 4 opposite to the pressing end is in abutting engagement with the on-off valve 5. When the sliding part 11 slides downwards, the sliding part 11 presses the swinging part 4 to enable the swinging part 4 to swing rightwards, so that the shifting lever 51 of the on-off valve 5 is pressed, the shifting lever 51 drives the valve rod 52 and the valve core 53 at the end part of the valve rod 52 to slide leftwards in the pressing process, meanwhile, the compression spring 54 is compressed, the water inlet 55 and the water outlet 56 of the on-off valve 5 are communicated, and the on-off valve 5 is opened; when the sliding member 11 slides upward, the swinging member 4 loses the pressing force of the sliding member 11 and swings leftward, and the valve rod 52 and the valve core 53 at the end of the valve rod 52 slide rightward under the action of the pressure spring 54, so that the valve core 53 is blocked between the water inlet 55 and the water outlet 56 of the on-off valve 5, and the on-off valve 5 is closed. Through the design of the swinging piece 4 and the on-off valve 5, the switch 1 for the mop bucket can easily control the on-off valve 5 to be opened and closed, and has simple structure and convenient operation.

In one embodiment, as shown in fig. 1 and 5, a latch (not shown) is disposed on a hole wall of the mounting hole 21 of the housing 2, and a slot 127 for the latch to be inserted is disposed on an outer circumferential surface of the mounting member 12. Through mutually supporting of fixture block and draw-in groove 127, can avoid installed part 12 to assemble around the axis rotation of self behind the mounting hole 21 of shell 2, the structure is more stable.

The embodiment of the application also provides a mop bucket, as shown in fig. 9, comprising a bucket body 6 and the switch 1 for the mop bucket. The barrel body 6 is provided with a water inlet channel, the water inlet channel of the barrel body is provided with an on-off valve 5, and the switch 1 for the mop barrel is installed on the barrel body 6 and used for controlling the on-off of the on-off valve. The user can make slider 11 slide on installed part 12 through stepping on or pressing the end of pressing of slider 11, and then makes the promotion end of slider 11 promote the on-off valve 5 on the mop bucket inhalant canal, makes the inhalant canal intercommunication. When the user releases the pressing end of the sliding part 11, the on-off valve 5 pushes the pushing end of the sliding part 11 to slide reversely under the action of the spring structure of the on-off valve, so that the sliding part returns to the original position, and the water inlet channel is closed at the moment. The mop bucket provided by the embodiment controls the on-off of the on-off valve in a linear sliding mode, has a more compact structure and is beneficial to reducing the volume of the mop bucket.

The above description is only exemplary of the present application and should not be taken as limiting the present application, as any modification, equivalent replacement, or improvement made within the spirit and principle of the present application should be included in the protection scope of the present application.

Claims (14)

1. The utility model provides a switch for mop bucket, its characterized in that includes slider and installed part, the installed part is used for installing on the mop bucket, the slider with installed part sliding connection, slider one end is for pressing the end, and the other end is for promoting the end, the promotion end of slider is used for promoting the last on-off valve of mop bucket inhalant canal, in order to control the on-off valve break-make.

2. The switch of claim 1, further comprising a swing lever, one end of the swing lever being provided with a rotating portion, the other end of the swing lever being provided with a sliding portion; the mounting piece is provided with a connecting structure which is rotatably connected with the rotating part, and the sliding part is provided with an annular sliding groove for the sliding part to be embedded and slide; or the sliding part is provided with a connecting structure which is rotationally connected with the rotating part, and the mounting part is provided with an annular sliding groove for the sliding part to be embedded and slide; annular spout is annular lift guide way, fixed slot and return stroke guide way including the end to end intercommunication in proper order, the inboard cell wall of fixed slot court the sunken setting of direction of rotation portion.

3. The switch of claim 2, wherein a junction between the wall of the lift guide groove and the wall of the fixing groove, a junction between the wall of the fixing groove and the wall of the return guide groove, and a junction between the wall of the return guide groove and the wall of the lift guide groove have a step surface.

4. The switch of claim 2, wherein the mounting member is configured as a tubular structure and the slider is slidably received within the mounting member.

5. The switch of claim 4, wherein the connection structure is a socket into which the rotation portion is inserted and rotated, the socket is formed on an outer surface of the mounting member, the annular slide groove is formed on the sliding member, and the switch further comprises a stopper for preventing the rotation portion from coming out of the socket and for preventing the sliding portion from coming out of the annular slide groove.

6. The switch of claim 5, wherein the stopper is an annular structure, and the mounting member has an annular groove formed on an outer circumferential surface thereof for receiving the stopper.

7. The switch as claimed in claim 4, wherein the mounting member has a guiding slide block on an inner peripheral surface thereof, the sliding member has a rod-like structure, a guiding groove extending along an axial direction of the sliding member is formed on a surface of the sliding member, and the guiding slide block is slidably disposed in the guiding groove.

8. The switch of claim 7, wherein the guide slider has a first arcuate sliding surface, the guide runner has a second arcuate sliding surface, and the first arcuate sliding surface of the guide slider is slidably engaged with the second arcuate sliding surface of the guide runner in the axial direction of the sliding member.

9. The switch of claim 4, further comprising an elastic member having one end connected to the pressing end of the sliding member and the other end connected to the mounting member.

10. The switch as claimed in claim 1, wherein the sliding member has a top cover fixedly connected to a pressing end thereof, the top cover has a fixing post formed on an inner surface thereof, and the pressing end of the sliding member has a fixing hole in interference fit with the fixing post.

11. The switch as claimed in claim 4, further comprising a housing and a fixing sleeve, wherein the housing has a mounting hole, the mounting member is located inside the housing, the fixing sleeve is located outside the housing, the mounting member and the fixing sleeve are sleeved with each other at the mounting hole, a wall around the mounting hole is clamped between the clamping portion of the mounting member and the clamping portion of the fixing sleeve, and the sliding member is movably inserted into the fixing sleeve.

12. The switch as claimed in claim 11, wherein the housing is rotatably connected with a swing member, the on-off valve is fixedly mounted on the housing, one side surface of the swing member is in abutting engagement with the pushing end of the sliding member, and the other opposite side surface of the swing member is in abutting engagement with the on-off valve.

13. The switch of claim 11, wherein a locking block is disposed on the wall of the mounting hole of the housing, and a locking groove for the locking block to be inserted into is disposed on the outer circumferential surface of the mounting member.

14. A mop bucket, comprising a bucket body and a switch as claimed in any one of claims 1 to 13, wherein the bucket body is provided with a water inlet channel, the water inlet channel of the bucket body is provided with an on-off valve, and the switch for the mop bucket is arranged on the bucket body and is used for controlling the on-off valve to be turned on or off.

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