Patent Application
20150096333
The present invention relates generally to washing machines, and more particularly, to a self-cleaning washing machine in which drum walls between inner and outer drums are automatically cleaned with water flow by using cleaning pellets, and a control method thereof for collecting cleaning pellets.
In existing wave wheel washing machines, the environment between inner and outer drums is closed, and only water can flow therein. Due to the limitation of the washing machine structure and the particularity of the user environment, dirt adheres to the outer wall of the inner drum and the inner wall of the outer drum after 3 to 5 months of use. Consequently, bacteria will breed in different extents, most of which are harmful to human body.
As people's living standards and the requirements of living quality increase, a solution to the sanitation of washing machines seems to be urgent. A survey conducted by a related scientific research institution on the internal environment of washing machines shows that consumers have started paying more and more attention to the severity of internal contamination of washing machines. To fundamentally prevent washing machines from bringing second-time dirt to the laundry and to be more responsible for users' health, the cleaning issue of the internal environment of washing machines needs to be addressed immediately.
Chinese Patent No. 200820183308.4 discloses a sleeve washing machine with walls between the drums cleaned. The washing machine includes an inner drum, an outer drum, and multiple circular silicone balls for cleaning the walls between the inner and outer drums. During washing, the inner drum rotates to drive the water to flow, thereby driving the silicone balls between the inner drum and outer drum of the washing machine to move and continuously collide with the walls between the inner and outer drums, so as to achieve the objective of cleaning the walls between the inner and outer drums.
By using the washing machine structure as described above, however, rubber balls or soft pellets are freely scattered in the drum after water drainage, which causes big noises during the high speed dewatering process, and also increases energy consumption and affects the service life of the washing machine.
In addition, Chinese Application No. 201010160548.4 discloses a washing machine using soft pellets to clean the environment between inner and outer drums of the washing machine and a method thereof. In the washing machine, soft pellets are placed between the inner and outer drums of the washing machine, and when laundry is washed, water flows regularly to drive the soft pellets to collide and rub the walls between the inner and outer drums of the washing machine, so as to clean the environment between the inner and outer drums of the washing machine.
By using the washing machine structure as described above, however, to strengthen the bottom of the inner drum, many reinforcing ribs are distributed at the bottom of the inner drum. The reinforcing ribs divide the external part of the bottom of the inner drum into multiple small grooves. The closer the grooves are to the center of the inner drum, the smaller the grooves are. Because the gap between the bottom of the inner drum and the bottom of the outer drum is small, it is difficult for water to flush between the bottoms of the inner and outer drums after long term use, and a lot of dirt is accumulated and hard to get rid of. Such bottom structure of the inner drum is not suitable for a washing machine with cleaning pellets for the following reasons: firstly, the reinforcing ribs at the bottom of the inner drum are high and the gap between the bottom of the inner drum and the bottom of the outer drum is small, thus it is not easy for cleaning pellets to enter the space between the bottoms of the inner and outer drums. Even though a few pellets could get in with the water flow, they are easily clamped or confined in the grooves and cannot get out, and the pellets between the inner and outer drums will be reduced in quantity, affecting the normal cleaning function of the drum walls. Secondly, because the reinforcing ribs are densely distributed and grooves are small, motions of the cleaning pellets that have entered the space between the bottoms of the inner and outer drums with the water flow fail to provide sufficient acceleration in the small grooves for the pellets to collide with the drum walls to clean the drum walls.
Therefore, a heretofore unaddressed need exists in the art to address the aforementioned deficiencies and inadequacies.
One of the objectives of the present invention is to provide a self-cleaning washing machine with cleaning pellets provide in a chamber defined between the inner and outer drums to perform a drum wall cleaning function so as to solve the foregoing problems and disadvantages.
In one aspect, the present invention relates to a self-cleaning washing machine having an isolating structure for preventing the cleaning pellets from escaping from the chamber between the inner and outer drums.
In another aspect, the present invention relates to a control method for the self-cleaning washing machine to collect the cleaning pellets.
In one embodiment, the self-cleaning washing machine comprises an outer drum, an inner drum, a wave wheel and a water drainage apparatus, wherein a chamber defined between the inner drum and the outer drum is provided with cleaning pellets for cleaning an inner wall of the outer drum and an outer wall of the inner drum. The washing machine also includes an isolating structure for preventing the cleaning pellets from escaping from the chamber. In one embodiment, the isolating structure includes a filtration mechanism arranged in the water drainage apparatus to prevent the cleaning pellets from being flushed away when water is drained, and/or a grid mechanism arranged at the bottom part of the inner drum to prevent the cleaning pellets from entering the inner drum from the bottom of the inner drum.
In one embodiment, the isolating structure further includes a filtration grid arranged at a water overflow port of the outer drum to prevent the cleaning pellets from being flushed with overflowing water. The filtration grid and the outer drum are integrated by injection molding, or are a separable plug-and-pull structure where slots are set up at two sides of the water overflow port and the filtration grid is inserted in the slots, or are a snap-on structure.
In one embodiment, the filtration grid includes a frame matching the water overflow port and stopping ribs arranged in the frame. In certain embodiments, the stopping ribs are divided into two groups, a partition gap smaller than the cleaning pellet is defined between the two groups of stopping ribs, a gap smaller than the cleaning pellet is defined between two adjacent stopping ribs in the same group, and the two groups of stopping ribs corresponding to a filtration surface formed at an inner side of the outer drum is a cambered surface toward, at a position of the partition gap, the other side along a direction of a stopping rib or an inclined surface. In certain embodiments, the two groups of stopping ribs are arranged symmetrically or are arranged with alternate extension directions. In certain embodiments, the filtration grid is a horizontal grid structure, or a vertical grid structure, or a screen structure.
In certain embodiments, the isolating structure further includes an outer drum cover arranged at the top part of the outer drum to cover an annular opening of the chamber, corresponding to the annular opening. The outer drum cover is provided with a pellet inlet for supplementing cleaning pellets to the chamber; in certain embodiments. The pellet inlet is provided with a cover that can be opened or closed.
In certain embodiments, the wave wheel is a self-cleaning wave wheel, including a wave plate and a water stirring piece arranged on an upper surface of the wave plate. In certain embodiments, the top part of the water stirring piece is provided with at least one water permeable hole, which corresponds to and communicates with a groove space of the bottom part of the water stirring piece. Multiple water permeable holes are distributed on the water stirring piece along the circumference close to the edge of the wave plate, and at least two water permeable holes are distributed on the water stirring piece along a radial direction at one end close to the center of the wave wheel.
In certain embodiments, a lower surface of the wave plate has multiple groove spaces formed by reinforcing ribs of the wave plate, corresponding to the area beyond the range of the water stirring piece, each groove space is provided with at least one water permeable hole to form flushing water flowing above and below the groove space.
In one embodiment, at least two rubbing bulges are arranged between each two water stirring pieces at the edge of the basin-shaped wave wheel, which are evenly distributed along the circumference of the wave wheel.
In one embodiment, an antimicrobial mildew proof coat is covered on the lower surface of the wave plate.
In one embodiment, the water drainage apparatus is provided in the self-cleaning washing machine such that cleaning pellets are collected by using draining water during water drainage and dewatering to avoid noise caused by the cleaning pellets colliding with the drum walls in between the inner and outer drums during dewatering, and at the same time, lint, sheet-like objects such as coins and buttons, and other sundries smaller than the cleaning pellets are smoothly discharged, thereby avoiding blockage.
In certain embodiments, the water drainage apparatus includes a pellet container chamber, a pellet receiving chamber for collecting the cleaning pellets under the buoyant force during the water flow to clean the drum walls, and a water drainage chamber. The filtration mechanism is arranged between the pellet receiving chamber and the water drainage chamber. The filtration mechanism can not only prevent the cleaning pellets, but also prevent lint and sundries smaller than the cleaning pellets from being discharged.
In certain embodiments, the filtration mechanism includes multiple stopping ribs to prevent the cleaning pellets, which are divided into two groups by a notch having a width smaller than the cleaning pellets, and a filtration gap smaller than the cleaning pellets is defined between the two adjacent stopping ribs in the same group. The two groups of stopping ribs correspond to a filtration surface formed at one side of the pellet receiving chamber, which is a cambered surface towards, at a position of the notch, the other side or an inclined surface, and the filtration surface is V-shaped with the bottom part opened or trapezoidal-shaped with an upper base longer than the lower base. The notch can not only enable the lint twined on a stopping rib to slide to a tail end of the stopping rib and pass through the notch, but also enable sheet-like objects such as buttons and coins to pass, thereby further reducing the possibility of lint blockage.
In certain embodiments, the notch separates the stopping ribs into two oppositely arranged comb structures, where the extension lines of stopping ribs of the two comb structures are alternate. The structure with the alternate extension lines of stopping ribs enables the passing of the cleaning pellets still be prevented even though the cleaning pellets are fixed in size and the distance between the two adjacent stopping ribs is increased, thereby further reducing the possibility of lint blockage.
In certain embodiments, the two comb structures are arranged oppositely in an up-down or a left-right manner, with a horizontal or vertical notch defined therebetween. The extension lines of stopping ribs of one comb structure are vertically alternated with those of stopping ribs of the other comb structure. The stopping ribs of the two comb structures are parallel to each other, and the spacing between each two adjacent straight lines is the same. End parts of three stopping ribs, adjacent to each other, of the two comb structures form a pellet stopping part of the notch at the triangular area. Tests have found out that compared with the comb structure with upper stopping ribs and lower stopping ribs symmetrically arranged, under the condition that the cleaning pellets and the notch are all fixed in sizes, the distance between the two adjacent stopping ribs of each comb structure can be larger while the passing of the cleaning pellets still be prevented.
In certain embodiments, the water drainage apparatus is arranged below the outer drum, a through port that communicates with a water drainage port at the bottom of the outer drum is arranged on an upper wall of the pellet receiving chamber, and the upper wall of the pellet receiving chamber inclines upward from the periphery to the through port. The inclining direction enables the cleaning pellets to rise with the water level and flow to the through port, and further enter the chamber between the inner and outer drums through the water drainage port. During the water drainage and dewatering processes, the cleaning pellets enter the pellet receiving chamber with the draining water flow. When water is fed again, the cleaning pellets float with the rise of the water level of the pellet receiving chamber, and the cleaning pellets move along the inclining direction, that is, move upward in an inclining manner, to enter the through port more conveniently, and then enter the space between the inner and outer drums through the water drainage port.
In certain embodiments, an opening communicating with outside is arranged at one side of the pellet receiving chamber opposite to the water drainage chamber, with a sealing cover that can be opened or closed, and a circumferential inner wall of the sealing cover is in a conical frustum circumferential wall structure with an aperture gradually enlarged in a direction toward inside of the pellet receiving chamber.
The structure according to this embodiment, when water is fed to the washing machine for the next time, the cleaning pellets can be released in between the inner and outer drums again under the buoyant force of the fed water to continue to clean the drum walls, and the adopted inclined inner wall structure makes it easier to reuse the cleaning pellets, and avoids blockage caused by failure of the cleaning pellets floating upward. The structure according to this embodiment is simple, and the manufacturing and mounting costs are low.
In certain embodiments, a grid mechanism for preventing the cleaning pellets from entering the inner drum from the bottom of the inner drum includes a stop cover that matches a flange plate to prevent the cleaning pellets from entering the inner drum from a hollow area of the bottom of the inner drum. The stop cover has water through holes capable of preventing cleaning pellets from passing.
In certain embodiments, the stop cover comprises a donut-like annular cover body defining a hollow region therein. The main body of the flange plate correspondingly blocks the hollow region of the stop cover. The diameter of the main body of the flange plate is d, the diameter of the hollow area of the bottom part of the inner drum is D, the inner diameter of the stop cover is d1, the outer diameter of the stop cover is d2, which satisfy with d1≦d<D≦d2, or d1≦d<d2<D. The difference between the inner diameter D of the hollow area of the bottom part of the inner drum and the outer diameter d2 of the stop cover satisfies that the cleaning pellets are incapable of passing through the gap between the edge of the hollow area of the bottom part of the inner drum and the periphery of the stop cover.
In certain embodiments, the stop cover is an independent structure clamped or adhered between the bottom of the inner drum and the flange plate, or is integrated with the bottom of the inner drum, or is integrated with the flange plate, or is integrated with the bottom of the inner drum and the flange plate. The stop cover can prevent the cleaning pellets between the inner and outer drums from entering the inner drum, thereby preventing quantity reduction of the cleaning pellets between the inner and outer drums from affecting the drum wall cleaning
In certain embodiments, each water through hole is a straight elongated slit structure or a bent elongated slit structure. Because most lint in washing water is collected by a lint filtration structure, and only a little lint is left and distributed as thin strips, the water through hole will not cause lint blockage.
In certain embodiments, each water through hole is a funnel structure with the size shrinking from up to down. Foreign bodies such as coins and buttons can pass through the structure, thereby reducing the possibility of blockage while preventing the cleaning pellets from entering the inner drum therefrom.
In certain embodiments, multiple grooves formed by reinforcing ribs at the bottom of the inner drum in a surrounding manner are provided outside the drum bottom, the gap between the bottom part of the reinforcing rib and the bottom of the outer drum is larger than that of the cleaning pellet. The grooves formed by reinforcing ribs at the drum bottom in a surrounding manner is capable of receiving at least about 2 cleaning pellets and preferably receiving about 2 to about 5 cleaning pellets. Each groove is accessible to the cleaning pellets, so that the cleaning pellets can move with water flow to obtain acceleration to collide with and rub the drum walls between the inner and outer drums.
In certain embodiments, the grooves include large grooves formed by reinforcing ribs outside the drum bottom in a surrounding manner and small grooves formed by division of reinforcing ribs inside the drum bottom, with the reinforcing ribs outside the drum bottom higher than the reinforcing ribs inside the drum bottom, and the reinforcing ribs inside the drum bottom no higher than about 5 mm. In certain preferable embodiments, corresponding to each groove, at least one water permeable through hole is added to the bottom of the inner drum, which not only reduces dirt adhered on the walls between the inner and outer drums, but also improves the mobility of the cleaning pellets, thereby preventing the cleaning pellets from being clamped at the bottom of the inner drum.
In certain embodiments, the cleaning pellets can float in the water, flows between the inner and outer drums of the washing machine with water flow to impact the walls of the inner and outer drums, in a laundry washing process, water flow drives the cleaning pellets to collide with and rub the walls of the inner and outer drums to clean the drum walls between the inner and outer drums of the washing machine. And after cleaning, washing water is drained from the water drainage apparatus, and the cleaning pellets flow to the pellet receiving chamber with the draining water and are received in the pellet receiving chamber; and when water is fed for rinsing or for washing the next time, with rise of the water level of the fed water, the cleaning pellets flow out of the pellet receiving chamber from the water drainage port and flows into the outer drum.
Utilizing the cleaning pellets between the inner and outer drums to clean walls of the inner and outer drums is the same as that washed objects in the inner drum rubs the inner drum so that the inner drum has no dirt adhered thereon and no bacteria breeding thereon. The cleaning pellets may be sponge typed objects, or may also be rubber or plastic foamed objects, such as foamed rubber, foamed plastic, or foamed composite polyurethane. In certain embodiments, an absorptive material is used so that better drum wall cleaning effects can be achieved. The cleaning pellets should have certain elasticity, have a smaller density than water when dry, have a soakage feature in water, and cheap. After multiple uses, cleaning pellets can be taken out by opening the sealing cover of an opening of a storage chamber and recycled, and then new cleaning pellets can be used.
In certain embodiments, the cleaning pellets are ball-shaped, block-shaped, ellipsoid-shaped, cylinder-shaped, or regular tetrahedron-shaped, or are other irregular mass-like pellet matters, with a quantity of about 3 to about 50. These pellets have a density smaller than water, and have certain elasticity and abrasive resistance.
In another aspect, the present invention further provides a control method for the self-cleaning washing machine to collect cleaning pellets by using draining water during water drainage and dewatering. The method is simple, capable of fully collection of the pellets, and eliminating noises caused by the cleaning pellets from colliding with inner and outer drums during dewatering.
In certain embodiments, in a water-draining and/or a spin-dry process, an inner drum is controlled to carry out different actions, so that the cleaning pellets could flow through a water drainage port with washing water, and are collected by a water drainage valve.
In certain embodiments, during the process of draining water, the inner drum is controlled to rotate at a low speed of about 5 to about 50 rpm, so that the cleaning pellets clamped between walls of the inner and outer drums could fall in between the inner and outer drums, and flow through the water drainage port with water in the outer drum, and are collected by the water drainage valve.
In certain embodiments, during the spin-dry process, the inner drum is controlled to carry out at least one braking action so that the cleaning pellets clamped between the walls of the inner and outer drums could fall into the space in between the inner and outer drums, and flow through the water drainage port with water thrown from laundry, and are collected by the water drainage valve.
In certain embodiments, the spin-dry process includes spinning laundry at a medium speed so that water flushes the cleaning pellets, at least one high speed spin-drying and braking, and spin-drying at a highest rotational speed until the end, where time allocated for each action in the stage is determined according to the total time of the spin-dry process.
In certain embodiments, in the spin-dry process, water is fed for a set time to increase the flushing water flow, and to assist the cleaning pellets to flow through the water drainage port and enter the water drainage valve. The spin-dry stage includes the following steps:
If the amount of the washed laundry is lower than a set value, step (c) is replaced by feeding water for about 5 to about 15 seconds, repeating step (a), and then repeating step (b).
In certain embodiments, during the spin-dry process, the medium speed is in a range of about 200 to about 500 rpm, the high speed is in a range of about 500 to about700 rpm, and the highest rotation speed is in a range of about 700 to about 1600 rpm.
Among other things, the present invention has the following beneficial effects.
In the self-cleaning washing machine, in one embodiment, the cleaning pellets for cleaning drum walls are placed in a chamber defined between the inner and outer drums. The isolating structure for preventing the cleaning pellets from escaping from the chamber is further provided, which includes a filtration mechanism that prevents the cleaning pellets from being flushed away when water is drained, and/or a grid mechanism arranged at the bottom of the inner drum to prevent the cleaning pellets from entering the inner drum from the bottom of the inner drum, and/or a filtration grid arranged at a water overflow port of the outer drum to prevent the cleaning pellets from flowing out with overflow water. The structure is simple and can effectively prevent the cleaning pellets from escaping from the chamber.
The water drainage apparatus in one embodiment is related to the washing machine with the cleaning pellets disposed between the inner and outer drums to perform the function of cleaning walls of the inner and outer drums. The cleaning pellets can be collected during water drainage to avoid noises caused by the cleaning pellets colliding with the drum walls between the inner and outer drums during dewatering, and the cleaning pellets can flow out of the pellet receiving chamber to the outer drum again under the buoyant force during water feeding, to continue to clean the drum walls. The water drainage apparatus is simple in structure and low in cost, and does not affect discharging of lint when stopping and collecting the cleaning pellets, thereby avoiding bacteria breeding caused by blockage of drained water and residual lint.
In one embodiment, the grooves from which the cleaning pellets can enter to move with the water flow to clean walls between the bottoms of the inner and outer drums are provided outside the bottom of the inner drum, so that the cleaning pellets between the inner and outer drums can clean the walls between the bottoms of the inner and outer drums. The structure is simple, and in the injection molding process of the bottom of the inner drum, modifications made to the design and distribution of reinforcing ribs provide space between the bottom parts of the inner and outer drums for the cleaning pellets to move with water flow. No additional material cost is added, and also the strength of the inner drum is not reduced.
In one embodiment, the stop cover is mounted on the bottom part of the inner drum, which can prevent the cleaning pellets of the chamber between the inner and outer drums from entering the inner drum through the bottom part of the inner drum, and prevent quantity reduction of the cleaning pellets between the inner and outer drums from affecting the cleaning effects of the outer wall of the inner drum and the inner wall of the outer drum. The water through hole distributed on the stop cover does not affect the flow of the washing water between the inner drum and the outer drum, and will not be blocked by lint. The structure is simple, and the cost is low.
In one embodiment, during the washing process, since the wave wheel or the inner drum continuously rotate in forward and backward directions, water in the outer drum is exchanged with water in the inner drum to form water flow, in order to drive the cleaning pellets between the inner and outer drums to move with water, collide with and rub the walls of the inner and outer drums, and also remove, with the help of soakage, attachments on the walls of the inner and outer drums and the bottom part of the inner drum, which fundamentally prevent the generation of dirt and bacteria breeding. When a user is doing laundry, the inner and outer drums are cleaned at the same time. Washing and cleaning are simultaneous without dirt remaining, and cleanliness and comfort are provided.
In certain embodiments, after washing, during water drainage, the inner drum rotates at a low speed so that the cleaning ball clamped between the walls of the inner and outer drums falls into space between the inner and outer drums, and the cleaning pellets flow with water and enter the water drainage valve through the water drainage port, and are collected in the pellet receiving chamber by the filtration structure. Even the cleaning pellets left at the bottom part of the inner drum can still be collected by controlling the inner drum during spin-drying to realize fully collection, which avoids noises caused by the cleaning pellets colliding with the drum walls during spin-drying.
These and other aspects of the present invention will become apparent from the following description of the preferred embodiment taken in conjunction with the following drawings.
As shown in
As shown in
In certain embodiments, the left and right groups of stopping ribs are arranged symmetrically or are arranged with alternate extension directions.
In one embodiment, the filtration grid and the outer drum are of a plug-and-pull structure, where slots are arranged at two sides of the water overflow port, and the filtration grid is inserted in the slots (not shown in the figure). In another embodiment, the filtration grid and the outer drum are of a snap-on structure.
The filtration grid and the outer drum are in a separable structure according to the above embodiments. In certain embodiments, the filtration grid and the outer drum may also be integrated by injection molding. In certain embodiments, the filtration grid may also be a horizontal grid structure, or a vertical grid structure, or a screen structure.
As shown in
As shown in
As shown in
In certain embodiments, an antimicrobial mildew proof coat is arranged on the lower surface of the wave plate.
As shown in
The water drainage apparatus 4 includes a pellet receiving chamber 41 that receives the cleaning pellets during dewatering and floats and the cleaning pellets to the chamber 5 to clean the drum walls under the buoyant force during water feeding, and a water drainage chamber 42, and the filtration mechanism 7 arranged between the pellet receiving chamber 41 and the water drainage chamber 42. The filtration mechanism 7 can stop the cleaning pellets, from which lint and sundries smaller than the cleaning pellets can be discharged.
The filtration mechanism 7 includes multiple stopping ribs 70 that stop the cleaning pellets. The stopping ribs 70 are divided into two groups. A notch 71 smaller than the cleaning pellet is defined between the two groups of stopping ribs 70, and a filtration gap 72 smaller than the cleaning pellet is defined between two adjacent stopping ribs 70 in the same group. The two groups of stopping ribs 70 correspond to a filtration surface 73 formed at one side of the pellet receiving chamber 41, which is a cambered surface towards, at a position of the notch 71, the other side or an inclined surface (referring to
In certain embodiments, as shown in
The two comb structures are arranged oppositely in an up-to-down or a left-to-right manner, a horizontal or vertical notch is placed therebetween, extension lines L1s of stopping ribs of one comb structure are vertically alternated with those of stopping ribs of the other comb structure, straight lines on which the stopping ribs of the two comb structures are located are parallel, and the same spacing L is placed between each two adjacent straight lines. End parts of three stopping ribs, adjacent to each other, of the two comb structures form a pellet stopping part of the notch in the triangular area. Tests have found out that compared with the comb structure with upper stopping ribs and lower stopping ribs symmetrically arranged, under the condition that the cleaning pellets and the notch are all fixed in size, a distance between the two adjacent stopping ribs of each comb structure can be larger while the cleaning pellets can still be stopped.
The water drainage apparatus 4, according to certain embodiments, is arranged below the outer drum 1. A through port 43 that communicates with a water drainage port at the bottom of the outer drum is arranged on an upper wall of the pellet receiving chamber 41, and the upper wall of the pellet receiving chamber 41 inclines upward from the periphery to the through port 43. The inclining direction enables the cleaning pellets to rise with the water level and flow to the through port, and further enter the chamber 5 between the inner and outer drums through the water drainage port. During the water drainage and dewatering processes, the cleaning pellets enter the pellet receiving chamber with draining water flow. When water is fed again, the cleaning pellets float upward with rise of the water level of the pellet receiving chamber, and the cleaning pellets move along the inclining direction, that is, move upward in an inclining manner, to enter the through port more conveniently, and then enter the space between the inner and outer drums through the water drainage port.
As shown in
According to this embodiment, when water is fed to the washing machine the next time, the cleaning pellets can be put in between the inner and outer drums again under the buoyant force of the fed water to continue to clean the drum walls, and the used inclined inner wall structure makes it easier to use the cleaning pellets again, which avoids blockage caused by failure of the cleaning pellets in floating upward. The structure is simple, and the manufacturing and mounting costs are low.
As shown in
The water through holes 82 are a straight elongated slit structure or a bent elongated slit structure. Because most lint in washing water is collected by a lint filtration structure, and only a little lint exists and is distributed as thin strips, the water through hole does not cause lint blockage. Further, the water through holes 82 are in a funnel structure with a size shrinking from up to down. Foreign bodies such as coins and buttons can pass through the structure, thereby reducing the possibility of blockage while preventing the cleaning pellets from entering the inner drum therefrom.
The stop cover includes a donut-like annular cover body defining a hollow region therein. The main body of the flange plate correspondingly blocks the hollow region of the stop cover, the diameter of the main body of the flange plate being d, the diameter of the hollow area of the bottom part of the inner drum being D, the inner diameter of the stop cover being d1, and the outer diameter of the stop cover being d2.
According to this embodiment, the stop cover 80 has an independent structure, clamped or adhered between the bottom 21 of the inner drum and the flange plate 81, or the stop cover 80 and the bottom of the inner drum are integrated, or the stop cover 80 and the flange plate 81 are integrated, or the stop cover 80, the bottom of the inner drum, and the flange plate are integrated. The stop cover can prevent the cleaning pellets between the inner and outer drums from entering the inner drum, which can prevent quantity reduction of the cleaning pellets between the inner and outer drums to affect the drum wall cleaning
When the stop cover 80 and the bottom part 21 of the inner drum are integrated by injection molding, d1≦d<D=d2 is satisfied, that is, the water through holes 82 are arranged in an area of the stop cover 80 that is beyond the central area of diameter d and corresponding to an area between two adjacent fixing feet 85 of the flange plate 81.
When the stop cover 80 has an independent cover body structure, the outer diameter d2 of the stop cover is the same as the diameter D of the hollow area of the bottom part of the inner drum, and the stop cover 80 is embedded and adhered in the hollow area 20 of the bottom part of the inner drum. In this case, d1<d, that is, the stop cover 80 has a partial annular cover body overlapping the main body 84 of the flange plate, and the water through holes 82 are distributed in an external area of an annular cover body that does not overlap the main body 84 of the flange plate, corresponding to an area between adjacent fixing feet 85 of the flange plate 81. In certain embodiments, a snap-fit structure is arranged at an outer side of the stop cover and embedded on a corresponding snap-on structure at an outer side of the hollow area of the bottom part of the inner drum, for example, a slot is arranged on the edge of the stop cover, and a jaw matching the slot is correspondingly arranged at a lateral side of the hollow area of the bottom part of the inner drum.
When the stop cover 80 has an independent cover body structure, the outer diameter d2 of the stop cover is greater than the diameter D of the hollow area 20 of the bottom part of the inner drum, the stop cover is clamped between the flange plate 81 and the bottom part 21 of the inner drum by using a fixing foot 85 of the flange plate, and d1≦d<D<d2 is satisfied. The inner diameter d1 of the stop cover 80 may be equal to the diameter d of the main body 84 of the flange plate, the water through holes 82 are arranged in an area, of the stop cover 80, corresponding to the area between two adjacent fixing feet 85 of the flange plate 81. In certain embodiments, the stop cover is mounted on the bottom of the inner drum and then is clamped between the flange plate and the bottom of the inner drum by using the flange plate.
When the outer diameter d2 of the stop cover 80 is less than the inner diameter D of the hollow area 20 of the bottom part of the inner drum, d1≦d<d2<D is satisfied, and the difference between the inner diameter D of the hollow area 20 of the bottom part of the inner drum and the outer diameter d2 of the stop cover 80 satisfies that the cleaning pellets are incapable of passing through a gap between the edge of the hollow area of the bottom part of the inner drum and the periphery of the stop cover. The stop cover is arranged in the hollow area 20 of the bottom of the inner drum, and may be connected with the bottom part of the inner drum by using a plurality of connection ribs distributed on the edge, or be integrated with the bottom part of the inner drum by injection molding using the connection ribs (not shown in the figure), or be connected with the bottom part of the inner drum by using a snap-fit structure extending at the edge of the stop cover, or the stop cover is mounted on the flange plate, the stop cover corresponding to a position of the hollow area, and the flange plate fixed with the bottom part of the inner drum.
As shown in
The grooves 23 include large grooves 231 formed by reinforcing ribs 221 outside the drum bottom in a surrounding manner and small grooves 232 formed by division of reinforcing ribs 222 inside the drum bottom (referring to
As shown in
In this embodiment according to the present invention, the cleaning pellets can float in the water, flowing between the inner and outer drums of the washing machine with water flow to impact the walls of the inner and outer drums. During the washing process, water flow drives the cleaning pellets to collide with and rub the walls of the inner and outer drums to clean the drum walls between the inner and outer drums of the washing machine, and after washing, water is drained from the water drainage apparatus, and the cleaning pellets flow to the pellet receiving chamber with the drained water and are collected in the pellet receiving chamber. When water is fed for rinsing or washing in the next time with the rise of the water level of the fed water, the cleaning pellets flow out of the pellet receiving chamber from the water drainage port and flow into the outer drum.
Putting cleaning pellets between inner and outer drums to clean walls of the inner and outer drums is learned from the fact that washed objects in the inner drum rub the inner drum so that the inner drum has no dirt adhered thereon and no bacteria breed thereon. The cleaning pellets may be sponge typed objects, and may also be rubber or plastic foamed objects, such as foamed rubber, foamed plastic, and foamed composite polyurethane. In certain embodiments, an absorptive material is used so that better drum wall cleaning effect is achieved. The cleaning pellets should have certain elasticity, a smaller density than that of water when dry, soakage in water and cheap. After multiple uses, cleaning pellets can be taken out by opening a sealing cover of an opening of a storage chamber and recycled, and then new cleaning pellets are used.
The cleaning pellets are ball-shaped, block-shaped, ellipsoid-shaped, cylinder-shaped, or regular tetrahedron-shaped, or are other irregular mass-like pellets, with a quantity of about 3 to about 50. These pellets have a density smaller than that of water, and have certain elasticity and abrasive resistance.
As shown in
As shown in
The difference between this embodiment and Embodiment 8 is that: the inner drum is controlled to repeat actions for about 2 to about 8 times with a rule of rotating at a medium speed for about 2 to about 5 seconds and stopping for about 5 to about 15 seconds, preferably about 4 to about 6 times, to replace the action of continuously spinning the laundry at a medium speed for about 10 to about 60 seconds by the inner drum in step (a) of Embodiment 8.
The difference between this embodiment and Embodiment 8 or Embodiment 9 is that:
between step (a) and step (b), a step of feeding water for flushing is added. Specifically, as shown in
In this embodiment, the following step is added based on Embodiment 8 or Embodiment 9: if the amount of washed laundry is lower than a set value, step (c) is replaced by feeding water for about 5 to about 15 seconds, repeat step (a), and then repeat step (b).
As shown in
In the foregoing Embodiments 8-12, during the spin-dry stage, the medium rotational speed is in a range of about 200 to about 500 rpm, the high speed is in a range of about 500 to about 700 rpm, and the highest rotational speed is in a range of about 700 to about 1600 rpm; and time allocation for each action during the stage is determined according to total time of the spin-dry procedure.
Many modifications and variations are possible in light of the above teaching. Although not explicitly described in the present invention, other embodiments within the scope of the invention and defined by the claims may be obtained by combining, modifying or changing the exemplary embodiments as described in the present invention. The foregoing description of the exemplary embodiments of the invention has been presented only for the purposes of illustration and description and is not intended to be exhaustive or to limit the invention to the precise forms disclosed. Alternative embodiments will become apparent to those skilled in the art to which the invention pertains without departing from its spirit and scope.
| Number | Date | Country | Kind |
|---|---|---|---|
| 201210188593.X | Jun 2012 | CN | national |
| 201210188601.0 | Jun 2012 | CN | national |
| 201210188605.9 | Jun 2012 | CN | national |
| 201210188729.7 | Jun 2012 | CN | national |
| Number | Date | Country | |
|---|---|---|---|
| Parent | PCT/CN2012/084714 | Nov 2012 | US |
| Child | 14559679 | US |
