Disclosure of Invention
The invention aims to solve the problems in the prior art and provides a cleaning device which can reasonably utilize the washing space for automatically cleaning tableware and avoid resource waste.
The purpose of the invention can be realized by the following technical scheme: a multi-function sink cleaning apparatus, comprising: the washing machine comprises a shell, a washing space and a water tank, wherein a water cup assembly integrating a water inlet channel and a water drainage channel is arranged at the bottom of the shell, and a spraying assembly is movably connected to the water cup assembly; the water-resisting component is detachably connected in the washing space and divides the washing space into an upper cavity and a lower cavity which are respectively an upper cavity and a lower cavity, wherein the spraying component is positioned in the lower cavity, and a layer of decontamination coating is sprayed on the inner side surface of the washing space.
In the above multifunctional water tank cleaning equipment, the water-resisting component comprises two detachably connected cover plates, namely an upper cover plate and a lower cover plate, wherein the lower cover plate is provided with a plurality of layers of concentric annular grooves, and the position of each concentric annular groove on the lower cover plate corresponds to the position of the spray hole on the spray component.
In the multifunctional water tank cleaning equipment, any layer of concentric annular groove on the lower cover plate is formed by splicing a plurality of sectional arc-shaped grooves.
In the above multifunctional water tank cleaning device, the connection lines at the intervals on each layer of concentric annular grooves are arranged in a straight line.
In the above multifunctional water tank cleaning device, the water outlet mode of the spraying assembly adopts pulse type water outlet, and the time interval between two adjacent water outlets in the spraying assembly is just equal to the time interval between two adjacent arc-shaped grooves when the spraying holes pass through the same layer of annular groove.
In the above multifunctional water tank cleaning device, the spraying assembly comprises a spraying arm, and a pulse structure is arranged in the spraying arm, wherein the pulse structure sequentially comprises an upper shell, a rotating disk and a bottom cover which are nested with one another from top to bottom, the water inlet is arranged on the bottom cover, and the water outlet is arranged on the upper shell.
In the above multifunctional water tank cleaning device, the upper cover plate is provided with a plurality of scattering bar-shaped grooves, wherein the width of each bar-shaped groove is not greater than the width of the space between two adjacent arc-shaped grooves.
In the above multifunctional water tank cleaning device, the upper cover plate and the lower cover plate are connected in a buckling manner.
In the above multifunctional water tank cleaning device, a buckle structure is arranged between the upper cover plate and the lower cover plate, wherein the buckle structure comprises an upper buckle mounted on the upper cover plate and a lower buckle mounted on the lower cover plate.
In the above multifunctional water tank cleaning device, the upper buckle and the lower buckle are in concave-convex fit.
In the above multifunctional water tank cleaning device, the upper buckle is arranged in a rotary body structure, a plurality of notches are arranged along the axis direction of the upper buckle, the lower buckle is arranged in a rotary body structure, and a plurality of raised lines matched with the notches are arranged along the axis direction of the lower buckle.
In the above multifunctional sink cleaning apparatus, an elastic plate is disposed at each notch, and the area of the elastic plate is not smaller than the area of the notch.
In the above multifunctional sink cleaning apparatus, the bottom portion close to the housing is arranged in a step-like structure, wherein the water isolating assembly is placed at the step portion of the housing.
In the above multifunctional water tank cleaning device, the casing is further provided with a water falling assembly, and the water falling assembly is detachably connected to the bottom of the casing.
In the above multifunctional water tank cleaning apparatus, a door panel assembly is movably connected to an opening of the washing space, and a wave-shaped water ridge is disposed on an inner side surface of the door panel assembly.
Compared with the prior art, the multifunctional water tank cleaning equipment provided by the invention has the advantages that the water-resisting component is detachably arranged in the cleaning space, so that the cleaning with different functions is realized, and the utilization rate of the cleaning space is further improved.
Detailed Description
The following are specific embodiments of the present invention and are further described with reference to the drawings, but the present invention is not limited to these embodiments.
As shown in fig. 1 to 8, the present invention provides a multifunctional sink cleaning apparatus, including: a housing 100 having a washing space therein, wherein a cup assembly 200 having a water inlet passage 210 and a water discharge passage 220 integrated therein is provided at the bottom of the housing 100, and a spray assembly 300 is movably connected to the cup assembly 200; the water-stop assembly 400 is detachably connected to the washing space, and divides the washing space into an upper cavity 110 and a lower cavity 120, wherein the upper cavity 110 and the lower cavity 120 are respectively formed by the spraying assembly 300, and the inner surface of the washing space is coated with a decontamination coating.
When the washing apparatus is used for washing dishes, the water blocking assembly 400 is detached from the washing space, so that the upper chamber 110 is communicated with the lower chamber 120, and the dishes are washed by the water sprayed from the spray assembly 300; when the cleaning equipment is used for ordinary cleaning, the water-stop assembly 400 is placed in the washing space to form an upper cavity and a lower cavity, wherein the upper cavity 110 is used as the washing space during ordinary cleaning, and after cleaning is finished, the water directly passes through the lower cavity 120 and enters the sewer pipeline.
The decontamination coating in this embodiment can be washed with clean water to complete the cleaning operation of the washing space. The micromolecule substance in the coating can react with the metal surface, especially, the low-energy surface which is not easy to be soaked by liquid can be formed on the metal surface by the fluorine polymer, and the low-energy fluorine polymer coating has the characteristics of smooth surface, small friction coefficient and the like.
The processing technology of the decontamination coating in the embodiment comprises the following steps: before spraying, preheating the surface of a washing space at 50-90 ℃, spraying a coating, putting the coating into an oven for drying at 100 ℃ for 20 minutes, spraying once, putting the coating into a high-temperature oven at 400 ℃ for drying for 30 minutes, taking out, and aging and cooling to room temperature to finish the processing of the coating.
According to the multifunctional water tank cleaning equipment provided by the invention, the water-resisting component 400 is detachably arranged in the cleaning space, so that cleaning with different functions is realized, and the utilization rate of the cleaning space is further improved.
Preferably, as shown in fig. 1 to 8, the water-stop assembly 400 includes two detachably connected cover plates, namely an upper cover plate 410 and a lower cover plate 420, wherein, a plurality of layers of concentric annular grooves are formed on the lower cover plate 420, when the washing device is used for washing dishes, the upper cover plate 410 is directly detached from the lower cover plate 420, and the lower cover plate 420 is left in the washing space, at this time, the lower cover plate 420 not only serves as a carrier for washing the dishes, but also serves as a flow channel for water in the spray assembly 300, i.e., the water can be sprayed to the dishes on the lower cover plate 420 through the concentric annular grooves on the lower cover plate 420, and no additional carrier is required to be provided for containing the dishes, so that the washing of the dishes becomes more convenient; when the cleaning device is used for ordinary cleaning, the upper cover plate 410 is connected to the lower cover plate 420, so that the upper cavity 110 forms a structure with a sealed bottom, water storage during ordinary cleaning is realized, and after cleaning is finished, the upper cover plate 410 is directly disassembled and lowered, so that the upper cavity 110 and the lower cavity 120 are communicated, and sewage discharge is realized.
Further preferably, as shown in fig. 1 to 8, any one layer of concentric annular grooves on the lower cover plate 420 is formed by splicing a plurality of segmented arc-shaped grooves 421, that is, in each concentric annular groove, two adjacent arc-shaped grooves 421 are not communicated, that is, two adjacent arc-shaped grooves 421 are divided by a flat plate 422, wherein the position of each concentric annular groove on the lower cover plate 420 corresponds to the position of the spraying hole 311 on the spraying assembly 300, and since the spraying assembly 300 performs circular motion when spraying water, each spraying hole 311 on the spraying assembly 300 performs circular motion according to the fixed radius (the distance from the spraying hole 311 to the center of the spraying assembly 300), so that the water body sprayed from the spraying hole 311 can reach the surface of the tableware through the corresponding concentric annular groove all the time, thereby ensuring the cleaning effect of the tableware.
Further preferably, as shown in fig. 1 to 8, the connection lines at the intervals (i.e. the positions of the flat plates 422) on each layer of concentric annular grooves are arranged in a straight line structure, so that the water body ejected from each spraying hole 311 of the spraying assembly 300 can always synchronously pass through the corresponding arc-shaped groove 421 and can also be synchronously blocked by the flat plates 422, thereby forming a water spraying manner similar to the "pulse structure 320". Further preferably, the spraying assembly 300 is set to be in a pulsed water outlet mode, and the time interval between two adjacent water outlets in the spraying assembly 300 is exactly equal to the time interval when the spraying holes 311 pass through two adjacent arc-shaped grooves 421 in the same layer of annular groove, that is, in the time period when the spraying assembly 300 does not discharge water, the spraying holes 311 on the spraying assembly just pass through the flat plate 422, so that the utilization rate of water resources is improved, and the cleaning effect of tableware is ensured.
Further preferably, as shown in fig. 1 to 8, the spray assembly 300 includes a spray arm 310, and a pulse structure 320 is disposed in the spray arm 310, wherein the pulse structure 320 sequentially includes an upper shell 321, a rotating disc 322, and a bottom cover 323 that are nested into each other from top to bottom, wherein the water inlet 324 is disposed on the bottom cover 323, the water outlet 325 is disposed on the upper shell 321, and when water flows into the pulse structure 320 from the water inlet 324, the rotating disc 322 is pushed to rotate in a cavity formed by splicing the upper shell 321 and the bottom cover 323 due to a certain flow velocity of the water flow, so as to form a pulse water flow, thereby achieving an effect of saving water consumption. Because the rotating power of the rotating disk 322 comes from the water flow and strikes the rotating disk 322 after entering the pulse structure 320, the rotation of the rotating disk 322 is realized, an additional power structure is not needed to be added for driving the rotating disk 322 to rotate, the components and the volume of the pulse structure 320 are reduced, and the structure of the pulse structure 320 becomes compact and the assembly is simple.
Preferably, as shown in fig. 1 to 8, the upper casing 321, the rotating disc 322 and the bottom cover 323 are coaxially arranged, further preferably, a plurality of circular holes 326 are formed in the rotating disc 322 and are used in cooperation with the water outlets 325 on the upper casing 321, and when the rotating disc 322 rotates between the upper casing 321 and the bottom cover 323, pulse water flow is formed by changing the number and the communication sequence of the circular holes 326 and the water outlets 325. Further preferably, the water outlets 325 are arranged in a circular array along the axial direction of the upper casing 321, and the circular holes 326 are arranged in a circular array along the axial direction of the rotating disk 322. Further preferably, the number of the water outlets 325 is equal to the number of the circular holes 326, and the two adjacent water outlets 325 and the two adjacent circular holes 326 are arranged in equal arc lengths, when the circular hole 326 on the rotating disk 322 is communicated with the water outlet 325 on the upper shell 321 (the circular hole 326 is concentric with the water outlet 325), the connection between the base and the spray arm 310 is conducted, that is, a water column is obtained at the spray hole 311 of the spray arm 310, and when the circular hole 326 on the rotating disk 322 is not communicated with the water outlet 325 on the upper shell 321 (the circular hole 326 is misaligned with the water outlet 325), the connection between the base and the spray arm 310 is not conducted, that is, no water column is obtained at the spray hole 311 of the spray arm 310, so that the circular hole 326 and the water outlet 325 are alternately concentric and misaligned through the circumferential rotation of the rotating disk 322, thereby forming a pulse water flow, and further obtaining a pulse water column at the spray hole 311 of the spray arm 310.
Preferably, as shown in fig. 1 to 8, a plurality of impellers 327 are arranged in a divergent manner along the axial direction of the rotating disk 322, wherein the plurality of impellers 327 face one side of the bottom cover 323 as impact positions where the water flow impacts the rotating disk 322 and pushes the rotating disk 322 to rotate. Further preferably, the pulsator 327 is provided in an integrated structure with the rotating disk 322. Further preferably, the circular hole 326 is disposed between two adjacent impellers 327, that is, one impeller 327 is disposed between two adjacent circular holes 326, that is, the impellers 327 on the rotating disk 322 and the circular holes 326 are alternately disposed, so as to improve the reliability of the pulse structure 320.
Further preferably, as shown in fig. 1 to 8, each of the impellers 327 is arranged in an arc structure, the bending curvatures of two adjacent impellers 327 are equal, and the impellers 327 having a curvature are adopted, so that the rotation of the rotating disk 322 is smoother, the contact area between the impeller 327 having a curvature and the water flow is larger, and the force required for pushing the rotating disk 322 to rotate is smaller, so as to accelerate the rotation rate of the rotating disk 322, form a cyclic pulse-type water flow, obtain a cyclic pulse-type water column at the spraying holes 311 of the spraying arm 310, reduce the consumption of water resources, and improve the cleaning effect.
Preferably, as shown in fig. 1 to 8, the thickness of each impeller 327 is gradually changed, the impeller 327 near the center of the rotating disk 322 has a thicker thickness, and the impeller 327 far from the center of the rotating disk 322 has a thinner thickness, so that the mass center of gravity of the rotating disk 322 is located at the center of the rotating disk and is gradually decreased radially toward the periphery, so that the rotating disk 322 has better stability during rotation, and the edge warping phenomenon is avoided, and on the other hand, the water flow can more laborsavingly push the rotating disk 322 to rotate, so as to increase the rotating speed of the rotating disk 322, and form a cyclic pulse water flow, thereby obtaining a cyclic pulse water column at the spraying holes 311 of the spraying arm 310, reducing the consumption of water resources, and improving the cleaning effect.
Preferably, as shown in fig. 1 to 8, two through grooves 328 are respectively disposed on the upper side and the lower side of the rotating disc 322, and the two through grooves 328 are respectively located at the central position of the rotating disc 322, wherein the two through grooves 328 are respectively used as connecting portions when the rotating disc 322 is nested with the upper shell 321 and the bottom cover 323, that is, the upper through groove 328 of the rotating disc 322 is nested with the convex column 329 at the center of the upper shell 321, the lower through groove 328 of the rotating disc 322 is connected with the convex column 329 at the center of the bottom cover 323, and the connecting portions at the two positions are used as rotating fulcrums when the rotating disc 322 rotates, so that the rotating disc 322 reliably rotates, the rotating disc 322 is prevented from being eccentric, and the reliability of the spraying device in use is improved.
Preferably, as shown in fig. 1 to 8, the bottom cover 323 is arranged in a stepped structure, wherein, two sides of the bottom cover 323 are respectively provided with a gradual water inlet 324, and the opening aperture of the side close to the rotating disc 322 is smaller, and the opening aperture of the side far from the rotating disc 322 is larger, when water flows from the side with the larger opening aperture to the side with the smaller opening aperture, the speed thereof becomes faster, the pressure per unit area increases, thereby increasing the spraying distance thereof, thus obtaining a pulse water column with higher pressure at the spraying holes 311 of the spraying arm 310, further enlarging the washing area generated by the collision of the water body and the surface of the dishware, and making the cleaning of the dishware cleaner and more effective.
Preferably, as shown in fig. 1 to 8, the cross section of the water inlet 324 is a trapezoid structure, which may be a general trapezoid, a right trapezoid or an isosceles trapezoid, so that the trapezoid structure is adopted, and the oblique side of the trapezoid may be used as a guiding portion when water flows, and on the other hand, the aperture of the water inlet 324 may be changed to form a gradually changing water inlet 324, thereby implementing the pulse structure 320 with increased effect.
Preferably, as shown in fig. 1 to 8, both side end surfaces of the water inlet 324 (the carrier on which the water inlet 324 is located has a certain thickness) have slopes. Further preferably, the slopes of the end faces on both sides are the same, i.e. the slopes on both sides are equal. Due to the arrangement, when the water flow is sprayed out from the water inlet 324, a certain angle is formed, the water flow can effectively impact the impeller 327 on the rotating disk 322, so that the impeller 327 can be conveniently pushed to rotate, and if the water flow is vertically sprayed upwards, the rotating speed of the rotating disk 322 is slower, and the cleaning time of tableware is prolonged.
Further preferably, as shown in fig. 1 to 8, a plurality of scattering bar-shaped grooves 411 are disposed on the upper cover plate 410, wherein the width of the bar-shaped grooves 411 is not greater than the interval width between two adjacent arc-shaped grooves 421. When the position of the strip-shaped groove 411 on the upper cover plate 410 corresponds to the position of the upper flat plate 422 on the lower cover plate 420, water storage of the upper cavity 110 can be realized, and when the position of the strip-shaped groove 411 on the upper cover plate 410 corresponds to the position of the arc-shaped groove 421 on the lower cover plate 420, water drainage of the upper cavity 110 can be realized, that is, water storage and water drainage of the upper cavity 110 can be realized by rotating the upper cover plate 410, so that the operation of a user is facilitated, and the use flexibility of the water-stop component 400 is improved.
Further preferably, as shown in fig. 1 to 8, the upper cover plate 410 is connected to the lower cover plate 420 by means of a snap. It is further preferable that a snap structure is provided between the upper cover plate 410 and the lower cover plate 420, wherein the snap structure comprises an upper snap 430 mounted on the upper cover plate 410, and a lower snap 440 mounted on the lower cover plate 420. Further preferably, the upper latch 430 is integrally disposed with the upper cover plate 410, and the lower latch 440 is integrally disposed with the lower cover plate 420. Further preferably, the upper buckle 430 and the lower buckle 440 are in concave-convex fit. Further preferably, the upper buckle 430 is arranged in a revolving body-shaped structure, a plurality of notches 431 are arranged along the axial direction of the upper buckle 430, the lower buckle 440 is arranged in a revolving body-shaped structure, a plurality of raised lines 441 matched with the notches 431 are arranged along the axial direction of the lower buckle 440, and the upper buckle 430 and the lower buckle 440 can be connected through the insertion and the matching between the notches 431 and the raised lines 441, so that the connection between the upper cover plate 410 and the lower cover plate 420 can be completed. Further preferably, an elastic plate 432 is disposed at each notch 431, and the area of the elastic plate 432 is not smaller than that of the notch 431, so that when the upper cover plate 410 and the lower cover plate 420 need to be detached, the convex strip 441 can be disengaged from the notch 431 by pressing the elastic plate 432, and the detachment between the upper cover plate 410 and the lower cover plate 420 is completed, and the operation is simple and convenient.
Preferably, as shown in fig. 1 to 8, the water blocking assembly 400 is disposed near the bottom of the casing 100 in a stepped structure, wherein the water blocking assembly 400 is placed at a stepped portion of the casing 100, in this embodiment, since the position of each layer of concentric annular groove on the lower cover plate 420 corresponds to the position of the spray hole 311 on the spray arm 310, the water can smoothly pass through the concentric annular groove and reach the upper cavity 110 where the tableware is located, and the water cannot be sprayed to the flat plate 422, so that the water blocking assembly 400 is prevented from being displaced or being jacked up by the water to make a sound, and the reliability of the use of the cleaning apparatus is further improved.
Preferably, as shown in fig. 1 to 8, a water falling assembly 500 is further provided on the housing 100, and the water falling assembly 500 is detachably connected to the bottom of the housing 100, so that when the cleaning apparatus is used for ordinary cleaning, sewage drained from the upper chamber 110 into the lower chamber 120 can be drained into the sewer pipe through the water falling assembly 500 without entering the sewer pipe through the drainage channel 220 in the water cup assembly 200, thereby forming two independent drainage systems at the bottom of the housing 100, and further improving the reliability of the use of the cleaning apparatus.
Preferably, as shown in fig. 1 to 8, a door panel assembly 600 is movably connected to the opening of the washing space, and a wave-shaped water ridge is disposed on the inner side of the door panel assembly 600, so as to reduce vibration noise generated when water pressure sprayed from the spraying holes 311 rushes to the inner side of the door panel assembly 600, and simultaneously avoid water drops from accumulating on the inner side of the door body assembly, thereby ensuring dryness of the inner side of the door body assembly.
The specific embodiments described herein are merely illustrative of the spirit of the invention. Various modifications or additions may be made to the described embodiments or alternatives may be employed by those skilled in the art without departing from the spirit or ambit of the invention as defined in the appended claims.