CN111110131B - Mounting structure of sink cleaning machine - Google Patents

Abstract

The invention relates to a mounting structure of a water tank cleaning machine, which comprises a supporting plate, a first telescopic component, a second telescopic component, a first adjusting component and a second adjusting component, wherein the supporting plate is used for supporting the bottom of a water tank, the upper end of the first telescopic component is connected with the edge of the lower wall surface of the supporting plate, and the lower end of the first telescopic component is supported on a mounting plane; the upper end of the second telescopic component is connected with the edge of the lower wall surface of the supporting plate and is symmetrically arranged relative to the center of the supporting plate with the first telescopic component, and the lower end of the second telescopic component is supported on the installation plane; the first adjusting component and the second adjusting component are used for adjusting the compression amount of the first telescopic component and the second telescopic component. According to the invention, the bottom of the water tank is directly supported on the supporting plate to mount the water tank cleaning machine, the weighing of the water tank is not needed depending on the upper edge of the top of the water tank, the mounting requirement of the water tank cleaning machine is reduced, and the mounting is more convenient; the invention can also finely adjust the heights of the symmetrical edges of the supporting plates, thereby improving the installation precision of the water tank cleaning machine.

Description

Mounting structure of sink cleaning machine

Technical Field

The invention relates to a mounting structure of a water tank cleaning machine.

Background

With the increasing level of living of people, dish washers are increasingly entering home as household electrical appliances for kitchen use. The dish-washing machines on the market are generally divided into three types of a desk type dish-washing machine, a cabinet type dish-washing machine and a trough type dish-washing machine, wherein the desk type dish-washing machine is of an integral independent structure and is generally placed on a desk for use; the cabinet type dish washer is also an independent structure, but needs to be embedded into a kitchen cabinet for use; the tub dishwasher is combined with a tub and is generally installed in a kitchen cabinet.

At present, the structure of a relatively mature water tank type cleaning machine in the market is mainly described in China patent No. CN104224074B (application number: CN 201310750968.1), namely, the water tank type cleaning machine comprises a tank body forming a cleaning space and a cover plate rotatably connected to the tank body, wherein the bottom of the tank body is provided with a concave draining area at least at the central part, a water pump for discharging a water pump in the draining area to the cleaning space above the draining area is arranged in the draining area, the draining area is covered with a draining plate with draining holes, and a rotary spray arm which is in fluid communication with the water pump and provided with water outlet holes is arranged above the draining plate. Through setting up the waterlogging caused by excessive rainfall area that is covered with the waterlogging caused by excessive rainfall board to set up the water pump in the waterlogging caused by excessive rainfall area, thereby keep apart water pump and washing district, make the filtration of water that flows back into the water pump through the waterlogging caused by excessive rainfall board earlier.

When the water tank type cleaning machine is installed, the water tank body is generally directly placed on the installation opening of the cabinet from top to bottom, and the water tank body bears the weight through the upper edge of the water tank body. The installation mode not only requires the upper edge of the water tank body to have a wide enough bearing supporting edge, but also requires the cabinet table top to have better bearing capacity, and has higher installation requirement; moreover, the situation that the water tank is inconsistent with the horizontal plane after being installed is easy to occur, the installation accuracy is poor, and the spray arm is easy to be worn for a long time.

Disclosure of Invention

The invention aims to solve the technical problem of providing a mounting structure of a water tank cleaning machine, which can be supported at the bottom of the water tank so as to reduce the mounting requirement of the water tank cleaning machine and is convenient to mount.

Another technical problem to be solved by the invention is to provide a mounting structure of a sink cleaner, which can level a sink during a mounting process to improve mounting accuracy.

The technical scheme adopted for solving the technical problems is as follows: the utility model provides a mounting structure of basin cleaning machine which characterized in that: comprising

The supporting plate is used for supporting the bottom of the water tank;

the upper end of the first telescopic component is connected with the edge of the lower wall surface of the supporting plate, and the lower end of the first telescopic component is supported on the installation plane;

the upper end of the second telescopic component is connected with the edge of the lower wall surface of the supporting plate and is symmetrically arranged relative to the center of the supporting plate with the first telescopic component, and the lower end of the second telescopic component is supported on the installation plane;

the first adjusting component is used for adjusting the compression amount of the first telescopic component and/or the second telescopic component; and

and the second adjusting assembly is used for adjusting the compression amount of the first telescopic assembly and/or the second telescopic assembly.

In order to realize the upper and lower regulation of layer board, the structure of first flexible subassembly is the same with the flexible subassembly of second, all including telescopic link, elastic component and bracing piece, the upper end and the layer board lower wall of telescopic link rotate to be connected, the lower extreme of telescopic link can be telescopic from top to bottom locate on the bracing piece, the elastic component makes the telescopic link remain the trend of upwards moving for the bracing piece throughout, the lower extreme of bracing piece supports on the mounting plane.

Preferably, the first adjusting component comprises a first motor and a first steel wire rope, a first rotating shaft capable of rotating under the drive of the first motor or external force is connected to the output end of the first motor, the first end of the first steel wire rope is connected with the first rotating shaft, and the second end of the first steel wire rope is connected with the lower end of the telescopic rod in the first telescopic component. The second adjusting component comprises a second motor and a second steel wire rope, a second rotating shaft capable of rotating under the drive of the second motor or external force is connected to the output end of the second motor, the first end of the second steel wire rope is connected with the second rotating shaft, and the second end of the second steel wire rope is connected with the lower end of the telescopic rod in the second telescopic component. The motor rotates and can pull the telescopic rod to move downwards through the steel wire rope, so that the compression amount of the first telescopic assembly and the second telescopic assembly is adjusted, and the supporting plate is kept horizontal.

As an improvement, the mounting structure of the water tank cleaning machine further comprises a transmission component which can drive the first telescopic component and the second telescopic component to compress synchronously when any one of the first motor and the second motor works, and the compression amount of the first telescopic component is different from that of the second telescopic component. Because the first telescopic component and the second telescopic component are symmetrically arranged on the lower wall surface of the supporting plate, when the heights of the first telescopic component and the second telescopic component are inconsistent, the telescopic quantity of the first telescopic component and the second telescopic component can be adjusted only through the operation of one motor.

The transmission assembly comprises a first transmission wheel, a second transmission wheel, a third transmission wheel and a fourth transmission wheel, wherein the first transmission wheel is arranged on the first rotating shaft and synchronously rotates along with the first rotating shaft, the second transmission wheel is arranged on the second rotating shaft and synchronously rotates along with the second rotating shaft, the diameter of the second transmission wheel is larger than that of the first transmission wheel, the second transmission wheel is meshed with the first transmission wheel in a clockwise rotation state, and the second transmission wheel is disengaged from the first transmission wheel in a anticlockwise rotation state;

the third driving wheel is arranged on the second rotating shaft and rotates synchronously with the second rotating shaft, the fourth driving wheel is arranged on the first rotating shaft and rotates synchronously with the first rotating shaft, the diameter of the fourth driving wheel is larger than that of the third driving wheel, the third driving wheel is meshed with the fourth driving wheel in a counterclockwise rotating state, and the third driving wheel is disengaged from the fourth driving wheel in a clockwise rotating state.

When the compression amount of the first telescopic component and the second telescopic component is regulated, the first motor and the second motor are operated in one direction, and the first motor is operated clockwise and the second motor is operated anticlockwise. For example, when the height of the supporting plate corresponding to the first telescopic component is higher than that of the supporting plate corresponding to the second telescopic component, the first motor is operated clockwise, the second motor is not operated, the first rotating shaft drives the first driving wheel and the third driving wheel to rotate, and the first driving wheel is meshed with the second driving wheel and the third driving wheel is disengaged from the fourth driving wheel, so that the first driving wheel drives the second driving wheel to rotate, the third driving wheel does not drive the fourth driving wheel to rotate, the first driving wheel rotates clockwise, and the second driving wheel rotates anticlockwise, so that the winding direction of the first steel wire rope on the first rotating shaft is required to be opposite to the winding direction of the second steel wire rope on the second rotating shaft, but the diameter of the first driving wheel is smaller than that of the second driving wheel, and therefore the compression amount of the first motor on the first telescopic component is adjusted to be greater than that on the second telescopic component until the positions corresponding to the first telescopic component and the second telescopic component are relatively horizontal; conversely, when the height of the supporting plate corresponding to the second telescopic component is higher than that of the supporting plate corresponding to the first telescopic component, the second motor is operated anticlockwise, the first motor does not operate, the second rotating shaft drives the second driving wheel and the fourth driving wheel to rotate, and the first driving wheel is disengaged from the second driving wheel and the third driving wheel is meshed with the fourth driving wheel, so that the second driving wheel does not drive the first driving wheel to rotate, the third driving wheel drives the fourth driving wheel to rotate, and the third driving wheel rotates anticlockwise, the fourth driving wheel rotates clockwise, but the diameter of the third driving wheel is smaller than that of the fourth driving wheel, and therefore the compression amount of the second motor on the second telescopic component is adjusted to be larger than that on the first telescopic component until the supporting plate corresponding to the first telescopic component and the second telescopic component is relatively horizontal.

In order to realize the matching relationship among the first driving wheel, the second driving wheel, the third driving wheel and the fourth driving wheel, the peripheral wall of the first driving wheel is recessed inwards along the circumferential direction to form a first annular groove, a plurality of first teeth which are arranged at intervals are arranged in the first annular groove along the circumferential direction, each first tooth is rotatably connected to two side walls of the first annular groove through a third rotating shaft which is arranged along the axial direction of the first driving wheel, and a torsion spring which can enable the first tooth to be always hidden in the first annular groove is arranged on the third rotating shaft;

the outer peripheral wall of the second driving wheel is inwards recessed along the circumferential direction to form a second annular groove, a plurality of second teeth are circumferentially arranged in the second annular groove at intervals, each second tooth is rotatably connected to two side walls of the second annular groove through a fourth rotating shaft axially arranged along the second driving wheel, a torsion spring capable of enabling the second teeth to be always hidden to the trend in the second annular groove is arranged on the fourth rotating shaft, and the arrangement direction of the second teeth in the second annular groove is opposite to the arrangement direction of the first teeth in the first annular groove.

The outer peripheral wall of the third driving wheel is recessed inwards along the circumferential direction to form a third annular groove, a plurality of third teeth which are arranged at intervals are arranged in the third annular groove along the circumferential direction, each third tooth is rotatably connected to two side walls of the third annular groove through a fifth rotating shaft which is arranged along the axial direction of the third driving wheel, and a torsion spring which can enable the third teeth to be hidden to the trend in the third annular groove all the time is arranged on the fifth rotating shaft;

the outer peripheral wall of the fourth driving wheel is inwards recessed along the circumferential direction to form a fourth annular groove, a plurality of fourth teeth which are arranged at intervals are arranged in the fourth annular groove along the circumferential direction, each fourth tooth is rotatably connected to two side walls of the fourth annular groove through a sixth rotating shaft which is arranged along the axial direction of the fourth driving wheel, a torsion spring which can enable the fourth teeth to be always hidden to the trend in the fourth annular groove is arranged on the sixth rotating shaft, and the arrangement direction of the fourth teeth in the fourth annular groove is opposite to the arrangement direction of the third teeth in the third annular groove.

In order to improve the levelness of the water tank after installation, the installation structure of the water tank cleaning machine further comprises a third telescopic component and a fourth telescopic component which are identical to the first telescopic component and the second telescopic component in structure, the supporting plate is shaped into a square structure matched with the bottom of the water tank cleaning machine, and the upper ends of the first telescopic component, the second telescopic component, the third telescopic component and the fourth telescopic component are respectively connected to one corner of the lower wall surface of the supporting plate.

In order to facilitate adjustment, the third telescopic component and the fourth telescopic component are also connected with the first adjusting component, the second adjusting component and the corresponding transmission component which can adjust the telescopic quantity of the third telescopic component and the fourth telescopic component.

In order to facilitate connection, the connecting arm extending downwards is arranged on the lower wall surface of the supporting plate, the upper end of the telescopic rod is rotationally connected to the connecting arm through a rotating shaft, an inserting hole for inserting the telescopic rod therein is formed in at least the upper part of the supporting rod, the elastic piece is a spring sleeved on the periphery of the telescopic rod, the upper end of the spring abuts against the upper end edge of the telescopic rod, and the lower end of the spring abuts against the upper edge of the supporting rod.

In order to improve stability, the outer wall of the telescopic rod is provided with a guide groove extending along the axial direction, and correspondingly, the upper part of the supporting rod is provided with a guide block capable of being matched with the guide groove in a guide way.

Preferably, an adjusting port which is arranged along the axial direction and connected with the jack is formed in the outer wall of the supporting rod, a hook is arranged at the lower end of the telescopic rod, and the second ends of the first steel wire rope and the second steel wire rope respectively penetrate through the corresponding adjusting ports to be connected with the corresponding hooks.

Preferably, pressure sensors are respectively arranged at the corners of the supporting plate. The pressure sensor can transmit signals to the controller to know the height conditions of all the positions, so that the first motor or the second motor is driven to operate, and leveling is carried out.

Compared with the prior art, the invention has the advantages that: according to the invention, the bottom of the water tank is directly supported on the supporting plate to mount the water tank cleaning machine, the upper edge of the top of the water tank is not required to be relied on to bear the weight of the water tank, the mounting requirement of the water tank cleaning machine is reduced, and the water tank cleaning machine is more convenient to mount; meanwhile, the height of the symmetrical edge of the supporting plate can be finely adjusted through the first telescopic assembly, the second telescopic assembly, the first adjusting assembly and the second adjusting assembly, so that the installation accuracy of the water tank cleaning machine is improved.

Drawings

FIG. 1 is a schematic diagram of an embodiment of the present invention;

FIG. 2 is a schematic structural view of the first and second telescopic assemblies of FIG. 1;

FIG. 3 is a schematic diagram illustrating the assembly relationship between the first and second adjustment assemblies and the transmission assembly in FIG. 1;

FIG. 4 is an enlarged schematic view of the portion A in FIG. 3;

FIG. 5 is a schematic view of the structure of FIG. 3 at another angle;

FIG. 6 is an enlarged schematic view of the portion B of FIG. 5;

fig. 7 is a schematic structural view of a first tooth according to an embodiment of the present invention.

Detailed Description

The invention is described in further detail below with reference to the embodiments of the drawings.

As shown in fig. 1 to 7, the mounting structure of the sink cleaning machine of the present embodiment includes a pallet 1, a first telescopic unit 2, a second telescopic unit 3, a first adjusting unit 4, and a second adjusting unit 5. The support plate 1 is used for supporting the bottom of the water tank, and the edge of the support plate 1 is at least provided with an upward extending surrounding edge 11 so as to prevent the water tank from sliding off the support plate 1. The upper end of the first telescopic component 2 is connected with the edge of the lower wall surface of the supporting plate 1, the lower end of the first telescopic component 2 is supported on the installation plane, the upper end of the second telescopic component 3 is connected with the edge of the lower wall surface of the supporting plate 1 and is symmetrically arranged relative to the center of the supporting plate 1 with the first telescopic component 2, and the lower end of the second telescopic component 3 is supported on the installation plane. The first adjusting component 4 and the second adjusting component 5 are used for adjusting the compression amount of the first telescopic component 2 and the second telescopic component 3 so as to keep the supporting plate 1 horizontal.

The first adjusting component 4 comprises a first motor 41 and a first steel wire rope 42, a first rotating shaft 43 capable of rotating under the drive of the first motor 41 or external force is connected to the output end of the first motor 41, the first end of the first steel wire rope 42 is connected with the first rotating shaft 43, and the second end of the first steel wire rope 42 is connected with the lower end of the telescopic rod 21 in the first telescopic component 2. The second adjusting component 5 comprises a second motor 51 and a second steel wire rope 52, a second rotating shaft 53 capable of rotating under the drive of the second motor 51 or external force is connected to the output end of the second motor 51, the first end of the second steel wire rope 52 is connected with the second rotating shaft 53, and the second end of the second steel wire rope 52 is connected with the lower end of the telescopic rod 21 in the second telescopic component 3. The rotation of the motor can pull the telescopic rod to move downwards through the steel wire rope, so that the compression amount of the first telescopic assembly 2 and the second telescopic assembly 3 is adjusted, and the supporting plate is kept horizontal.

The first telescopic assembly 2 and the second telescopic assembly 3 of this embodiment have the same structure, and each of the first telescopic assembly 2 and the second telescopic assembly comprises a telescopic rod 21, an elastic member 22 and a supporting rod 23, wherein the upper end of the telescopic rod 21 is rotatably connected with the lower wall surface of the supporting plate 1, the lower end of the telescopic rod 21 can be vertically telescopic and arranged on the supporting rod 23, the elastic member 22 enables the telescopic rod 21 to always keep a trend of moving upwards relative to the supporting rod 23, and the lower end of the supporting rod 23 is supported on an installation plane. Specifically, the lower wall surface of the supporting plate 1 is provided with a connecting arm 12 extending downwards, the upper end of the telescopic rod 21 is rotationally connected to the connecting arm 12 through a rotating shaft, an insertion hole 231 for inserting the telescopic rod 21 therein is formed in the upper portion of the supporting rod 23, the elastic piece 22 is a spring sleeved on the periphery of the telescopic rod 21, the upper end of the spring abuts against the upper end edge of the telescopic rod 21, and the lower end of the spring abuts against the upper edge of the supporting rod 23. In order to improve stability, the outer wall of the telescopic rod 21 is provided with a guide groove 211 extending along the axial direction, and correspondingly, the upper part of the supporting rod 23 is provided with a guide block 232 capable of being in guide fit with the guide groove 211. The outer wall of the supporting rod 23 is provided with an adjusting opening 233 which is axially arranged and connected with the jack 231, the lower end of the telescopic rod 21 is provided with a hook 212, and the second ends of the first steel wire rope 42 and the second steel wire rope 52 respectively penetrate through the corresponding adjusting openings 233 to be connected with the corresponding hooks 212.

In this embodiment, the mounting structure of the sink cleaning machine further includes a transmission assembly 6 capable of driving the first and second telescopic assemblies 2 and 3 to compress synchronously when any one of the first and second motors 41 and 51 is operated, and the first and second telescopic assemblies 2 and 3 compress synchronously no matter the first and second motors 41 and 51 are operated, but the compression amounts of the first and second telescopic assemblies 2 and 3 are different. The compression amount of the first telescopic assembly 2 is larger than the compression amount of the second telescopic assembly 3 in the working state of the first motor 41, and the compression amount of the second telescopic assembly 3 is larger than the compression amount of the first telescopic assembly 2 in the working state of the second motor 51. Because the first telescopic component 2 and the second telescopic component 3 are symmetrically arranged on the lower wall surface of the supporting plate 1, when the heights of the first telescopic component and the second telescopic component are inconsistent, the telescopic quantity of the first telescopic component and the second telescopic component can be adjusted only by the operation of one motor; of course, if the overall height of the pallet 1 is to be adjusted, the first motor 41 and the second motor 51 need to be operated separately.

Specifically, the transmission assembly 6 includes a first transmission wheel 61, a second transmission wheel 62, a third transmission wheel 63 and a fourth transmission wheel 64, the first transmission wheel 61 is arranged on the first rotating shaft 43 and rotates synchronously with the first rotating shaft 43, the second transmission wheel 62 is arranged on the second rotating shaft 52 and rotates synchronously with the second rotating shaft 52, the diameter of the second transmission wheel 62 is larger than that of the first transmission wheel 61, in a state that the first transmission wheel 61 is used as a driving wheel to rotate clockwise, the second transmission wheel 62 is meshed with the first transmission wheel 61, and in a state that the second transmission wheel 62 is used as a driving wheel to rotate anticlockwise, the second transmission wheel 62 is disengaged with the first transmission wheel 61; the third driving wheel 63 is arranged on the second rotating shaft 53 and rotates synchronously with the second rotating shaft 53, the fourth driving wheel 64 is arranged on the first rotating shaft 43 and rotates synchronously with the first rotating shaft 43, the diameter of the fourth driving wheel 64 is larger than that of the third driving wheel 63, the third driving wheel 63 is kept meshed with the fourth driving wheel 64 when being used as a driving wheel in a counterclockwise rotating state, and the third driving wheel 63 is disengaged from the fourth driving wheel 64 when the fourth driving wheel 64 rotates clockwise.

In order to realize the above-mentioned matching relationship among the first driving wheel 61, the second driving wheel 62, the third driving wheel 63 and the fourth driving wheel 64, the outer peripheral wall of the first driving wheel 61 is recessed inwards along the circumferential direction to form a first annular groove 611, a plurality of first teeth 612 are arranged in the first annular groove 611 along the circumferential direction at intervals, each first tooth 612 is rotatably connected to two side walls of the first annular groove 611 through a third rotating shaft 613 arranged along the axial direction of the first driving wheel 61, and a torsion spring 614 capable of keeping the first teeth 612 hidden in the first annular groove 611 all the time is arranged on the third rotating shaft 613. The outer peripheral wall of the second driving wheel 62 is concavely formed with a second annular groove 621 along the circumferential direction inwards, a plurality of second teeth 622 are arranged in the second annular groove 621 along the circumferential direction at intervals, each second tooth 622 is rotatably connected to two side walls of the second annular groove 621 through a fourth rotating shaft 623 arranged along the axial direction of the second driving wheel 62, a torsion spring which can enable the second teeth 622 to be always hidden to the trend in the second annular groove 621 is arranged on the fourth rotating shaft 623, and the arrangement direction of the second teeth 622 in the second annular groove 621 is opposite to the arrangement direction of the first teeth 612 in the first annular groove 611. The outer peripheral wall of the third driving wheel 63 is concavely formed with a third annular groove 631 along the circumferential direction, a plurality of third teeth 632 arranged at intervals are arranged in the third annular groove 631 along the circumferential direction, each third tooth 632 is rotatably connected to two side walls of the third annular groove 631 through a fifth rotating shaft 633 arranged along the axial direction of the third driving wheel 63, and a torsion spring which can enable the third teeth 632 to be hidden to the trend in the third annular groove 631 all the time is arranged on the fifth rotating shaft 633. The outer circumferential wall of the fourth driving wheel 64 is formed with a fourth annular groove 641 recessed inward in the circumferential direction, a plurality of fourth teeth 642 are circumferentially arranged in the fourth annular groove 641 at intervals, each fourth tooth 642 is rotatably connected to both side walls of the fourth annular groove 641 by a sixth rotating shaft 643 arranged in the axial direction of the fourth driving wheel 64, a torsion spring is provided on the sixth rotating shaft 643, which enables the fourth teeth 642 to remain hidden to the trend in the fourth annular groove 641 all the time, and the arrangement direction of the fourth teeth 642 in the fourth annular groove 641 is opposite to the arrangement direction of the third teeth 632 in the third annular groove 631.

In order to improve the levelness of the water tank after installation, the installation structure of the water tank cleaning machine further comprises a third telescopic component 7 and a fourth telescopic component 8 which are identical in structure with the first telescopic component 2 and the second telescopic component 3, the supporting plate 1 is shaped into a square structure matched with the bottom shape of the water tank cleaning machine, and the upper ends of the first telescopic component 2, the second telescopic component 3, the third telescopic component 7 and the fourth telescopic component 8 are respectively connected to one corner of the lower wall surface of the supporting plate 1. In order to facilitate adjustment, the third telescopic assembly 7 and the fourth telescopic assembly 8 are also connected with a first adjusting assembly 4, a second adjusting assembly 5 and a corresponding transmission assembly 6 which can adjust the telescopic amount of the first telescopic assembly and the second telescopic assembly. Pressure sensors 13 are respectively arranged at the corners of the supporting plate 1. The pressure sensor 13 can transmit a signal to the controller to know the height condition everywhere, so as to drive the first motor 41 or the second motor 51 to operate for leveling.

When the mounting structure of this embodiment is used, the sink cleaning machine is directly placed on the supporting plate 1, and then the compression amounts of the first telescopic component 2, the second telescopic component 3, the third telescopic component 7 and the fourth telescopic component 8 are adjusted as required until the height meets the requirements, and the supporting plate 1 is kept horizontal. Specifically, when the compression amounts of the first and second expansion modules 2 and 3 are adjusted, the first and second motors 41 and 51 are operated in one direction, and the first motor 41 is operated clockwise and the second motor 51 is operated counterclockwise. For example, when the height of the pallet 1 corresponding to the first telescopic assembly 2 is higher than the height of the pallet 1 corresponding to the second telescopic assembly 3, the first motor 41 is operated clockwise, the second motor 51 is not operated, the first rotating shaft 43 drives the first driving wheel 61 and the third driving wheel 63 to rotate, the first driving wheel 61 is meshed with the second driving wheel 62, the third driving wheel 63 is disengaged from the fourth driving wheel 64, thus the first driving wheel 61 drives the second driving wheel 62 to rotate, the third driving wheel 63 does not drive the fourth driving wheel 64 to rotate, the first driving wheel 61 rotates clockwise, the second driving wheel 62 rotates anticlockwise, the winding direction of the first steel wire rope 42 on the first rotating shaft 43 is required to be opposite to the winding direction of the second steel wire rope 52 on the second rotating shaft 53, but the compression amount of the first motor 41 is adjusted to be greater than the compression amount of the second telescopic assembly 3 due to the fact that the diameter of the first driving wheel 61 is smaller than the diameter of the second driving wheel 62, and the compression amount of the first motor 41 adjusts to the second telescopic assembly 2 until the corresponding position of the first telescopic assembly 2 and the second telescopic assembly 3 is horizontal; conversely, when the height of the pallet 1 corresponding to the second telescopic assembly 3 is higher than the height of the pallet corresponding to the first telescopic assembly 2, the second motor 51 is operated anticlockwise, the first motor 41 is not operated, the second rotating shaft 53 drives the second driving wheel 62 and the fourth driving wheel 64 to rotate, the first driving wheel 61 is disengaged from the second driving wheel 62, and the third driving wheel 63 is meshed with the fourth driving wheel 64, so that the second driving wheel 63 does not drive the first driving wheel 62 to rotate, the third driving wheel 63 drives the fourth driving wheel 64 to rotate, the third driving wheel 63 rotates anticlockwise, and the fourth driving wheel 64 rotates clockwise, but the diameter of the third driving wheel 63 is smaller than that of the fourth driving wheel 64, and therefore the compression amount of the second motor 52 on the second telescopic assembly 3 is adjusted to be greater than that on the first telescopic assembly 2 until the positions of the first telescopic assembly 2 and the second telescopic assembly 3 correspond to the 1. The compression amount adjustment of the third telescopic assembly 7 and the fourth telescopic assembly 8 is the same as the compression amount adjustment method of the first telescopic assembly 2 and the second telescopic assembly 3, and will not be described herein.

Claims (11)

1. The utility model provides a mounting structure of basin cleaning machine which characterized in that: comprising

A supporting plate (1) for supporting the bottom of the water tank;

the upper end of the first telescopic component (2) is connected with the edge of the lower wall surface of the supporting plate (1), and the lower end of the first telescopic component (2) is supported on the installation plane;

the upper end of the second telescopic component (3) is connected with the edge of the lower wall surface of the supporting plate (1) and is symmetrically arranged relative to the center of the supporting plate (1) with the first telescopic component (2), and the lower end of the second telescopic component (3) is supported on the installation plane;

a first adjusting component (4) for adjusting the compression amount of the first telescopic component (2) and/or the second telescopic component (3); and

a second adjusting assembly (5) for adjusting the compression of the first telescopic assembly (2) and/or the second telescopic assembly (3);

the first telescopic components and the second telescopic components are symmetrically arranged on the lower wall surface of the supporting plate, and the first adjusting components and the second adjusting components operate simultaneously when the overall height of the supporting plate is adjusted; when the heights of the first telescopic component and the second telescopic component are inconsistent, only one of the first adjusting component and the second adjusting component is operated to adjust the compression amount of the first telescopic component and the second telescopic component;

when the compression amount of the first telescopic component (2) and the compression amount of the second telescopic component (3) are regulated, the regulation of the compression amount of the first telescopic component (2) by the first regulating component (4) is larger than the regulation of the compression amount of the second telescopic component (3), and the regulation of the compression amount of the second telescopic component (3) by the second regulating component (5) is larger than the regulation of the compression amount of the first telescopic component (2) until the relative level of the supporting plates (1) corresponding to the first telescopic component (2) and the second telescopic component (3) is reached;

the structure of the first telescopic component (2) is the same as that of the second telescopic component (3), the telescopic component comprises a telescopic rod (21), an elastic piece (22) and a supporting rod (23), the upper end of the telescopic rod (21) is rotationally connected with the lower wall surface of the supporting plate (1), the lower end of the telescopic rod (21) can be arranged on the supporting rod (23) in a vertically telescopic way, the elastic piece (22) enables the telescopic rod (21) to always keep a trend of moving upwards relative to the supporting rod (23), and the lower end of the supporting rod (23) is supported on an installation plane;

the first adjusting component (4) comprises a first motor (41) and a first steel wire rope (42), a first rotating shaft (43) capable of rotating under the drive of the first motor (41) or external force is connected to the output end of the first motor (41), the first end of the first steel wire rope (42) is connected with the first rotating shaft (43), and the second end of the first steel wire rope (42) is connected with the lower end of the telescopic rod (21) in the first telescopic component (2);

the second adjusting component (5) comprises a second motor (51) and a second steel wire rope (52), a second rotating shaft (53) capable of rotating under the drive of the second motor (51) or external force is connected to the output end of the second motor (51), the first end of the second steel wire rope (52) is connected with the second rotating shaft (53), and the second end of the second steel wire rope (52) is connected with the lower end of the telescopic rod (21) in the second telescopic component (3).

2. The mounting structure of a sink cleaner according to claim 1, wherein: still including can drive first flexible subassembly (2), the synchronous compressed drive assembly (6) of second flexible subassembly (3) in arbitrary motor during operation in first motor (41), second motor (51), and the compression volume of first flexible subassembly (2) and second flexible subassembly (3) is different, under first motor (41) operating condition, the compression volume of first flexible subassembly (2) is greater than the compression volume of second flexible subassembly (3), under second motor (51) operating condition, the compression volume of second flexible subassembly (3) is greater than the compression volume of first flexible subassembly (2).

3. The mounting structure of a sink cleaner according to claim 2, wherein: the transmission assembly (6) comprises a first transmission wheel (61), a second transmission wheel (62), a third transmission wheel (63) and a fourth transmission wheel (64), wherein the first transmission wheel (61) is arranged on the first rotating shaft (43) and synchronously rotates along with the first rotating shaft (43), the second transmission wheel (62) is arranged on the second rotating shaft (53) and synchronously rotates along with the second rotating shaft (53), the diameter of the second transmission wheel (62) is larger than that of the first transmission wheel (61), the second transmission wheel (62) is meshed with the first transmission wheel (61) under the clockwise rotation state of the first transmission wheel (61), and the second transmission wheel (62) is disengaged from the first transmission wheel (61) under the anticlockwise rotation state of the first transmission wheel (61);

the third driving wheel (63) is arranged on the second rotating shaft (53) and rotates synchronously with the second rotating shaft (53), the fourth driving wheel (64) is arranged on the first rotating shaft (43) and rotates synchronously with the first rotating shaft (43), the diameter of the fourth driving wheel (64) is larger than that of the third driving wheel (63), in the anticlockwise rotating state of the third driving wheel (63), the third driving wheel (63) is meshed with the fourth driving wheel (64), and in the clockwise rotating state of the third driving wheel (63), the third driving wheel (63) is disengaged from the fourth driving wheel (64).

4. The mounting structure of a sink cleaner according to claim 3, wherein: the outer peripheral wall of the first driving wheel (61) is recessed inwards along the circumferential direction to form a first annular groove (611), a plurality of first teeth (612) are arranged in the first annular groove (611) at intervals along the circumferential direction, each first tooth (612) is rotatably connected to two side walls of the first annular groove (611) through a third rotating shaft (613) arranged along the axial direction of the first driving wheel (61), and a torsion spring which can enable the first teeth (612) to be always hidden in the first annular groove (611) is arranged on the third rotating shaft (613);

the outer peripheral wall of the second driving wheel (62) is recessed inwards along the circumferential direction to form a second annular groove (621), a plurality of second teeth (622) are arranged in the second annular groove (621) at intervals along the circumferential direction, each second tooth (622) is rotatably connected to two side walls of the second annular groove (621) through a fourth rotating shaft (623) arranged along the axial direction of the second driving wheel (62), a torsion spring which enables the second teeth (622) to be always hidden in the second annular groove (621) is arranged on the fourth rotating shaft (623), and the arrangement direction of the second teeth (622) in the second annular groove (621) is opposite to the arrangement direction of the first teeth (612) in the first annular groove (611).

5. The mounting structure of a sink cleaner according to claim 3, wherein: the outer peripheral wall of the third driving wheel (63) is recessed inwards along the circumferential direction to form a third annular groove (631), a plurality of third teeth (632) are arranged in the third annular groove (631) at intervals along the circumferential direction, each third tooth (632) is rotatably connected to two side walls of the third annular groove (631) through a fifth rotating shaft (633) axially arranged along the third driving wheel (63), and the fifth rotating shaft (633) is provided with a torsion spring which can enable the third teeth (632) to be always hidden in the third annular groove (631);

the outer peripheral wall of the fourth driving wheel (64) is recessed inwards along the circumferential direction to form a fourth annular groove (641), a plurality of fourth teeth (642) are arranged in the fourth annular groove (641) at intervals along the circumferential direction, each fourth tooth (642) is rotatably connected to two side walls of the fourth annular groove (641) through a sixth rotating shaft (643) axially arranged along the fourth driving wheel (64), a torsion spring which can enable the fourth teeth (642) to be always hidden to the trend in the fourth annular groove (641) is arranged on the sixth rotating shaft (643), and the arrangement direction of the fourth teeth (642) in the fourth annular groove (641) is opposite to the arrangement direction of the third teeth (632) in the third annular groove (631).

6. The mounting structure of a sink cleaner according to any one of claims 1 to 5, wherein: the water tank cleaning machine is characterized by further comprising a third telescopic component (7) and a fourth telescopic component (8) which are identical in structure with the first telescopic component (2) and the second telescopic component (3), wherein the supporting plate (1) is shaped into a square structure matched with the bottom of the water tank cleaning machine, and the upper ends of the first telescopic component (2), the second telescopic component (3), the third telescopic component (7) and the fourth telescopic component (8) are respectively connected to one corner of the lower wall surface of the supporting plate (1).

7. The mounting structure of a sink cleaner of claim 6, wherein: the first adjusting component (4), the second adjusting component (5) and the corresponding transmission component (6) which can adjust the expansion amount of the third telescopic component (7) and the fourth telescopic component (8) are also connected.

8. The mounting structure of a sink cleaner according to any one of claims 1 to 5, wherein: the connecting arm (12) extending downwards is arranged on the lower wall surface of the supporting plate (1), the upper end of the telescopic rod (21) is rotationally connected to the connecting arm (12) through a rotating shaft, at least the upper portion of the supporting rod (23) is provided with an inserting hole (231) for inserting the telescopic rod (21) therein, the elastic piece (22) is a spring sleeved on the periphery of the telescopic rod (21), the upper end of the spring is propped against the upper end edge of the telescopic rod (21), and the lower end of the spring is propped against the upper edge of the supporting rod (23).

9. The mounting structure of a sink cleaner of claim 8, wherein: the outer wall of the telescopic rod (21) is provided with a guide groove (211) extending along the axial direction, and correspondingly, the upper part of the supporting rod (23) is provided with a guide block (232) which can be in guide fit with the guide groove (211).

10. The mounting structure of a sink cleaner of claim 8, wherein: an adjusting port (233) which is axially arranged and connected with the jack (231) is formed in the outer wall of the supporting rod (23), a hook (212) is arranged at the lower end of the telescopic rod (21), and the second ends of the first steel wire rope (42) and the second steel wire rope (52) respectively penetrate through the corresponding adjusting port (233) to be connected with the corresponding hook (212).

11. The mounting structure of a sink cleaner according to any one of claims 1 to 5, wherein: pressure sensors (13) are respectively arranged at the corners of the supporting plate (1).