CN112538717A - Dehydration control method utilizing novel swinging motion - Google Patents

Abstract

The invention discloses a dehydration control method by utilizing a novel swinging motion, and relates to the technical field of laundry dehydration control. The method comprises the steps of firstly carrying out pre-dehydration, wherein a dehydration cylinder sequentially runs at t1 at the rotating speed of X1, runs at t2 at X2 and runs at t3 at X3; then the speed is reduced to X for eccentric weighing detection; judging IB less than or equal to A after pre-dehydration; if yes, the control of different rotating speeds is performed in different intervals by judging UB. The invention enhances the dehydration performance of the machine by improving the deviation rectifying action before dehydration; analyzing according to the dewatering deviation rectifying action before the machine, detecting the large eccentricity again before dewatering, and determining whether to continue to dewater downwards or not by judging the shaking dispersion through the action; so as to improve the dehydration performance.

Description

Dehydration control method utilizing novel swinging motion

Technical Field

The invention belongs to the technical field of laundry dehydration control, and particularly relates to a dehydration control method by utilizing a novel swinging motion.

Background

In the current market, the deviation rectifying and swinging actions of most drum washing machines before dehydration are too single, so that the drum washing machines are difficult to dehydrate when washing some real loads, the deviation rectifying time is too long even if dehydration is realized, the dehydration rotating speed is too low, and even the phenomenon that individual loads impact a box body and the like is not considerable when dehydration is carried out.

The phenomenon possibly caused by deviation correction before dehydration can directly influence the product quality and bring bad experience to users. The demands of people on product quality in all aspects are continuously improved in the face of the modern technological development and the improvement of life quality. For the important quality standard of the drum washing machine in dewatering, we need to reduce the phenomenon as much as possible. The basic factor for eliminating the phenomenon is that the eccentricity and the weighing value generated by the load of the objects in the barrel are reduced as much as possible, and most of the load can easily meet the dehydration requirement and reach the required standard. However, some individual loads can cause difficulty in dewatering due to water absorption or excessive bucket volume, and the ordinary deviation rectification can shake off the loads to meet the dewatering requirement. Improvements in the corrective action are needed.

To solve the above problems, the present invention provides a dehydration control method using a novel swing motion.

Disclosure of Invention

The invention aims to provide a dehydration control method utilizing a novel swing motion, which is used for solving the technical problems in the background technology.

In order to solve the technical problems, the invention is realized by the following technical scheme:

the invention relates to a dehydration control method by utilizing novel swing motion, which comprises the following processes:

a00: executing a dehydration program to adjust clothes;

a01: carrying out eccentric weighing detection under the condition that the rotating speed of the dewatering cylinder is N;

a02: judging whether UB is less than or equal to K; if yes, A03 is executed; if not, executing A05;

UB is an eccentric weighing value, and K is a preset maximum weighing threshold value;

a03: executing m +1 and judging that m is less than or equal to m 0; if yes, the rotating speed of the dewatering drum is reduced to N0 and is kept for T0 seconds; if not, executing A04;

wherein m is the deceleration number and the initial value of m is 0, and m0 is a preset deceleration threshold;

a04: n is n +1 and n is judged to be less than or equal to n 0; if yes, execute A00; if not, the clothes are shaken out, and the dehydration is finished; wherein n0 is a first threshold value of the adjustment times and an initial value of n is 0;

a05: judging that IB is less than or equal to A; if yes, A06 is executed; if not, the clothes are shaken out, and the dehydration is finished;

wherein IB is a weighing value, and A is a first weighing threshold value;

a06: judging that B is more than IB and less than or equal to A; if yes, A07 is executed; if not, executing the processes from A06 to A09 according to the interval of IB;

wherein B is a second weighing threshold;

a07: judging whether UB is less than or equal to a 1; if yes, execute A09; if not, executing A08;

wherein a1 is the eccentricity threshold a1 corresponding to the current interval;

a08: n1 is n1+1, and n1 is not more than n 2; if yes, the clothes are adjusted, and A07 is executed; if not, the clothes are shaken out, and the dehydration is finished; wherein n2 is the second threshold of the adjustment times and the initial value of n1 is 0;

a09: performing pre-dehydration, and sequentially operating the dehydration cylinder at a rotating speed of X1 for t1, at X2 for t2 and at X3 for t 3; then the speed is reduced to X for eccentric weighing detection;

a10: judging IB less than or equal to A after pre-dehydration; if yes, execute A11; if not, the clothes are shaken out, and the dehydration is finished;

a11: judging that B is more than IB and less than or equal to A; if yes, A12 is executed; if not, executing the processes from A12 to A17 according to the interval of IB;

a12: judging whether UB is less than or equal to a 2; if yes, the dewatering drum operates T1 under the rotating speed N1, operates T2 under N2, operates T3 under N3, operates T4 under N4, operates T5 under N5, then the clothes are shaken and dispersed, and dewatering is finished; if not, executing A13; wherein a2 is a second eccentricity threshold;

a13: judging whether UB is less than or equal to a 3; if yes, the dewatering drum sequentially runs T1 at the rotating speed N1, T2 at the rotating speed N2, T3 at the rotating speed N3 and T4 at the rotating speed N4, then the clothes are shaken up, and dewatering is finished; if not, executing A14; wherein a3 is a third eccentricity threshold;

a14: judging whether UB is less than or equal to a 4; if yes, the dewatering drum sequentially runs T1 at the rotating speed N1, T2 at the rotating speed N2 and T3 at the rotating speed N3, then the clothes are shaken up, and dewatering is finished; if not, executing A15; wherein a4 is a fourth eccentricity threshold;

a15: judging whether UB is less than or equal to a 5; if yes, the dewatering drum sequentially operates T1 at the rotating speed N1 and operates T2 at the rotating speed N2, then clothes are shaken up, and dewatering is finished; if not, executing A16; wherein a5 is a fifth eccentricity threshold;

a16: judging whether UB is less than or equal to a 6; if yes, the dewatering drum sequentially operates at a rotating speed N1 for T1, then the clothes are shaken up, and dewatering is finished; if not, executing A17; wherein, a6 is the sixth eccentricity threshold

A17: executing n 3-n 3+1 and judging n3 ≦ n 4; if yes, performing A12 after clothes adjustment; if not, the clothes are shaken out, and the dehydration is finished; wherein n4 is the second threshold of the adjustment times and the initial value of n3 is 0.

As a preferred technical solution, the process from a06 to a09 performed according to the interval where IB is located in a06 is specifically as follows:

when C < IB ≦ B, replacing a1 with B1 performs A06 through A09;

when D < IB ≦ C, replacing a1 with C1 performs A06 through A09;

when E < IB ≦ D, replacing a1 with D1 performs A06 through A09;

when F < IB ≦ E, A06 through A09 are performed with a substitution of a1 with E1.

As a preferred technical solution, the process of performing a12 to a17 according to the interval where IB is located in a11 specifically includes the following steps:

when C is less than IB and less than or equal to B, a2, A3, a4, a5 and A6 are respectively replaced by B2, B3, B4, B5 and B6 to carry out A12 to A17;

when D < IB ≦ C, correspondingly replacing a2, A3, a4, a5 and A6 with C2, C3, C4, C5 and C6 to carry out A12 to A17;

when E is less than IB and less than or equal to D, correspondingly replacing a2, A3, a4, a5 and A6 with D2, D3, D4, D5 and D6 to execute A12 to A17;

when F < IB ≦ E, A12 to A17 are executed by replacing a2, A3, a4, a5 and A6 with E2, E3, E4, E5 and E6 respectively.

The invention has the following beneficial effects:

the invention enhances the dehydration performance of the machine by improving the deviation rectifying action before dehydration; analyzing according to the dewatering deviation rectifying action before the machine, detecting the large eccentricity again before dewatering, and determining whether to continue to dewater downwards or not by judging the shaking dispersion through the action; so as to improve the dehydration performance.

Of course, it is not necessary for any product in which the invention is practiced to achieve all of the above-described advantages at the same time.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings used in the description of the embodiments will be briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art that other drawings can be obtained according to the drawings without creative efforts.

FIG. 1 is a flow chart of a dewatering control method using a novel swing motion of the present invention.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1, the present invention is a dewatering control method using a novel swing motion, including the following steps:

a00: executing a dehydration program to adjust clothes;

a01: carrying out eccentric weighing detection under the condition that the rotating speed of the dewatering cylinder is N;

a02: judging whether UB is less than or equal to K; if yes, A03 is executed; if not, executing A05;

UB is an eccentric weighing value, and K is a preset maximum weighing threshold value;

a03: m is m +1, and m is judged to be less than or equal to m 0; if yes, the rotating speed of the dewatering drum is reduced to N0 and is kept for T0 seconds; if not, executing A04;

wherein m is the deceleration number and the initial value of m is 0, and m0 is a preset deceleration threshold;

a04: n is n +1 and n is judged to be less than or equal to n 0; if yes, execute A00; if not, the clothes are shaken out, and the dehydration is finished; wherein n0 is a first threshold value of the adjustment times and an initial value of n is 0;

a05: judging that IB is less than or equal to A; if yes, A06 is executed; if not, the clothes are shaken out, and the dehydration is finished;

wherein IB is a weighing value, and A is a first weighing threshold value;

a06: judging that B is more than IB and less than or equal to A; if yes, A07 is executed; if not, executing the processes from A06 to A09 according to the interval of IB;

wherein B is a second weighing threshold;

a07: judging whether UB is less than or equal to a 1; if yes, execute A09; if not, executing A08;

wherein a1 is the eccentricity threshold a1 corresponding to the current interval;

a08: n1 is n1+1, and n1 is not more than n 2; if yes, the clothes are adjusted, and A07 is executed; if not, the clothes are shaken out, and the dehydration is finished; wherein n2 is the second threshold of the adjustment times and the initial value of n1 is 0;

a09: performing pre-dehydration, and sequentially operating the dehydration cylinder at a rotating speed of X1 for t1, at X2 for t2 and at X3 for t 3; then the speed is reduced to X for eccentric weighing detection;

a10: judging IB less than or equal to A after pre-dehydration; if yes, execute A11; if not, the clothes are shaken out, and the dehydration is finished;

a11: judging that B is more than IB and less than or equal to A; if yes, A12 is executed; if not, executing the processes from A12 to A17 according to the interval of IB;

a12: judging whether UB is less than or equal to a 2; if yes, the dewatering drum operates T1 under the rotating speed N1, operates T2 under N2, operates T3 under N3, operates T4 under N4, operates T5 under N5, then the clothes are shaken and dispersed, and dewatering is finished; if not, executing A13; wherein a2 is a second eccentricity threshold;

a13: judging whether UB is less than or equal to a 3; if yes, the dewatering drum sequentially runs T1 at the rotating speed N1, T2 at the rotating speed N2, T3 at the rotating speed N3 and T4 at the rotating speed N4, then the clothes are shaken up, and dewatering is finished; if not, executing A14; wherein a3 is a third eccentricity threshold;

a14: judging whether UB is less than or equal to a 4; if yes, the dewatering drum sequentially runs T1 at the rotating speed N1, T2 at the rotating speed N2 and T3 at the rotating speed N3, then the clothes are shaken up, and dewatering is finished; if not, executing A15; wherein a4 is a fourth eccentricity threshold;

a15: judging whether UB is less than or equal to a 5; if yes, the dewatering drum sequentially operates T1 at the rotating speed N1 and operates T2 at the rotating speed N2, then clothes are shaken up, and dewatering is finished; if not, executing A16; wherein a5 is a fifth eccentricity threshold;

a16: judging whether UB is less than or equal to a 6; if yes, the dewatering drum sequentially operates at a rotating speed N1 for T1, then the clothes are shaken up, and dewatering is finished; if not, executing A17; wherein, a6 is the sixth eccentricity threshold

A17: executing n 3-n 3+1 and judging n3 ≦ n 4; if yes, performing A12 after clothes adjustment; if not, the clothes are shaken out, and the dehydration is finished; wherein n4 is the second threshold of the adjustment times and the initial value of n3 is 0.

The process from A06 to A09 executed in A06 according to the interval of IB is specifically as follows:

when C < IB ≦ B, replacing a1 with B1 performs A06 through A09;

when D < IB ≦ C, replacing a1 with C1 performs A06 through A09;

when E < IB ≦ D, replacing a1 with D1 performs A06 through A09;

when F < IB ≦ E, A06 through A09 are performed with a substitution of a1 with E1.

The process of performing the interval from A12 to A17 according to IB in A11 specifically includes the following steps:

when C is less than IB and less than or equal to B, a2, A3, a4, a5 and A6 are respectively replaced by B2, B3, B4, B5 and B6 to carry out A12 to A17;

when D < IB ≦ C, correspondingly replacing a2, A3, a4, a5 and A6 with C2, C3, C4, C5 and C6 to carry out A12 to A17;

when E is less than IB and less than or equal to D, correspondingly replacing a2, A3, a4, a5 and A6 with D2, D3, D4, D5 and D6 to execute A12 to A17;

when F < IB ≦ E, A12 to A17 are executed by replacing a2, A3, a4, a5 and A6 with E2, E3, E4, E5 and E6 respectively.

When the invention is actually used, the dehydration control method is provided, so that negative effects of dehydration failure, over-low rotating speed, over-high water content, even box body collision and the like caused by over-eccentricity of some loads in the normal drum washing machine during dehydration are reduced; therefore, the requirement of a user on dehydration is met, the treatment of the dehydration process is optimized, and the advantages of the product are enhanced; in addition, the dewatering performance of the machine is enhanced by improving the deviation rectifying action before dewatering; analyzing according to the dewatering deviation rectifying action before the machine, detecting the large eccentricity again before dewatering, and determining whether to continue to dewater downwards or not by judging the shaking dispersion through the action; so as to improve the dehydration performance.

It should be noted that, in the above system embodiment, each included unit is only divided according to functional logic, but is not limited to the above division as long as the corresponding function can be implemented; in addition, specific names of the functional units are only for convenience of distinguishing from each other, and are not used for limiting the protection scope of the present invention.

In addition, it is understood by those skilled in the art that all or part of the steps in the method for implementing the embodiments described above may be implemented by a program instructing associated hardware, and the corresponding program may be stored in a computer-readable storage medium.

The preferred embodiments of the invention disclosed above are intended to be illustrative only. The preferred embodiments are not intended to be exhaustive or to limit the invention to the precise embodiments disclosed. Obviously, many modifications and variations are possible in light of the above teaching. The embodiments were chosen and described in order to best explain the principles of the invention and the practical application, to thereby enable others skilled in the art to best utilize the invention. The invention is limited only by the claims and their full scope and equivalents.

Claims (3)

1. A dehydration control method using a novel swing motion is characterized by comprising the following processes:

a00: executing a dehydration program to adjust clothes;

a01: carrying out eccentric weighing detection under the condition that the rotating speed of the dewatering cylinder is N;

a02: judging whether UB is less than or equal to K; if yes, A03 is executed; if not, executing A05;

UB is an eccentric weighing value, and K is a preset maximum weighing threshold value;

a03: executing m +1 and judging that m is less than or equal to m 0; if yes, the rotating speed of the dewatering drum is reduced to N0 and is kept for T0 seconds; if not, executing A04;

wherein m is the deceleration number and the initial value of m is 0, and m0 is a preset deceleration threshold;

a04: n is n +1 and n is judged to be less than or equal to n 0; if yes, execute A00; if not, the clothes are shaken out, and the dehydration is finished; wherein n0 is a first threshold value of the adjustment times and an initial value of n is 0;

a05: judging that IB is less than or equal to A; if yes, A06 is executed; if not, the clothes are shaken out, and the dehydration is finished;

wherein IB is a weighing value, and A is a first weighing threshold value;

a06: judging that B is more than IB and less than or equal to A; if yes, A07 is executed; if not, executing the processes from A06 to A09 according to the interval of IB;

wherein B is a second weighing threshold;

a07: judging whether UB is less than or equal to a 1; if yes, execute A09; if not, executing A08;

wherein a1 is the eccentricity threshold a1 corresponding to the current interval;

a08: n1 is n1+1, and n1 is not more than n 2; if yes, the clothes are adjusted, and A07 is executed; if not, the clothes are shaken out, and the dehydration is finished; wherein n2 is the second threshold of the adjustment times and the initial value of n1 is 0;

a09: performing pre-dehydration, and sequentially operating the dehydration cylinder at a rotating speed of X1 for t1, at X2 for t2 and at X3 for t 3; then the speed is reduced to X for eccentric weighing detection;

a10: judging IB less than or equal to A after pre-dehydration; if yes, execute A11; if not, the clothes are shaken out, and the dehydration is finished;

a11: judging that B is more than IB and less than or equal to A; if yes, A12 is executed; if not, executing the processes from A12 to A17 according to the interval of IB;

a12: judging whether UB is less than or equal to a 2; if yes, the dewatering drum operates T1 under the rotating speed N1, operates T2 under N2, operates T3 under N3, operates T4 under N4, operates T5 under N5, then the clothes are shaken and dispersed, and dewatering is finished; if not, executing A13; wherein a2 is a second eccentricity threshold;

a13: judging whether UB is less than or equal to a 3; if yes, the dewatering drum sequentially runs T1 at the rotating speed N1, T2 at the rotating speed N2, T3 at the rotating speed N3 and T4 at the rotating speed N4, then the clothes are shaken up, and dewatering is finished; if not, executing A14; wherein a3 is a third eccentricity threshold;

a14: judging whether UB is less than or equal to a 4; if yes, the dewatering drum sequentially runs T1 at the rotating speed N1, T2 at the rotating speed N2 and T3 at the rotating speed N3, then the clothes are shaken up, and dewatering is finished; if not, executing A15; wherein a4 is a fourth eccentricity threshold;

a15: judging whether UB is less than or equal to a 5; if yes, the dewatering drum sequentially operates T1 at the rotating speed N1 and operates T2 at the rotating speed N2, then clothes are shaken up, and dewatering is finished; if not, executing A16; wherein a5 is a fifth eccentricity threshold;

a16: judging whether UB is less than or equal to a 6; if yes, the dewatering drum sequentially operates at a rotating speed N1 for T1, then the clothes are shaken up, and dewatering is finished; if not, executing A17; wherein, a6 is the sixth eccentricity threshold

A17: executing n 3-n 3+1 and judging n3 ≦ n 4; if yes, performing A12 after clothes adjustment; if not, the clothes are shaken out, and the dehydration is finished; wherein n4 is the second threshold of the adjustment times and the initial value of n3 is 0.

2. The method as claimed in claim 1, wherein the steps from A06 to A09 performed according to the interval of IB in A06 are as follows:

when C < IB ≦ B, replacing a1 with B1 performs A06 through A09;

when D < IB ≦ C, replacing a1 with C1 performs A06 through A09;

when E < IB ≦ D, replacing a1 with D1 performs A06 through A09;

when F < IB ≦ E, A06 through A09 are performed with a substitution of a1 with E1.

3. The method as claimed in claim 2, wherein the steps from A12 to A17 performed according to the interval of IB in A11 specifically include the following steps:

when C is less than IB and less than or equal to B, a2, A3, a4, a5 and A6 are respectively replaced by B2, B3, B4, B5 and B6 to carry out A12 to A17;

when D < IB ≦ C, correspondingly replacing a2, A3, a4, a5 and A6 with C2, C3, C4, C5 and C6 to carry out A12 to A17;

when E is less than IB and less than or equal to D, correspondingly replacing a2, A3, a4, a5 and A6 with D2, D3, D4, D5 and D6 to execute A12 to A17;

when F < IB ≦ E, A12 to A17 are executed by replacing a2, A3, a4, a5 and A6 with E2, E3, E4, E5 and E6 respectively.

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