KR20220159030A - washing machine and control method thereof - Google Patents

Abstract

A washing machine of the present disclosure includes an image acquisition module which acquires a first image of laundry inside a washing tub. The image acquisition module includes a light source for radiating light into the washing tub and a camera for receiving reflected light of the light. A processor detects the contamination amount of the laundry from the first image before washing, and sets washing conditions according to the detection result. Accordingly, the washing machine can perform efficient washing according to the contamination amount of laundry.

Description

Washing machine and control method thereof {washing machine and control method thereof}

Embodiments of the present disclosure relate to a washing machine capable of effectively removing contaminants and a control method thereof.

A washing machine is a device that loads laundry, water, and detergent into a washing tub, rotates the washing tub to remove contaminants from the laundry, rinses, and spins the laundry to wash the laundry. The washing machine may provide a plurality of selectable washing courses according to the amount of laundry and the type of laundry. For example, a plurality of washing courses may be displayed through a manipulation panel, and a user may select a desired washing course through an input means such as a button or a jog dial provided on the manipulation panel.

A washing machine capable of efficiently washing laundry according to the amount of contamination of laundry and a control method thereof are provided.

A washing machine capable of sanitary washing and a control method thereof are provided.

A washing machine according to an embodiment of the present disclosure includes a washing tub; an image acquisition module including a light source for radiating light into the washing tub and a camera for receiving reflected light of the light to acquire a first image of laundry inside the washing tub; and a processor that detects the amount of contamination of the laundry from the first image before washing, and sets washing conditions according to the detection result.

As an embodiment, the processor may detect the amount of laundry from the first image, and the detection result may include the amount of contamination and the amount of laundry.

As an embodiment, the processor may set the washing condition by adjusting the preset washing condition according to the detection result.

As an embodiment, after performing laundry, the processor obtains a second image of the laundry using the image acquisition module, re-detects the amount of contamination from the second image, and performs additional washing according to the re-detection result. can decide whether to perform

As an example, the light source may include a first light source for image detection and a second light source for sterilization. The processor may control the second light source to sterilize the washing tub and the laundry after washing is performed. As an example, the first light source may include a plurality of first light sources disposed on a circular arc centered on an optical axis of the camera. As an example, an optical axis of the first light source and an optical axis of the camera may be parallel.

As an example, the image acquisition module may include a plurality of color filters sequentially positioned in an optical path of the camera.

A method for controlling a washing machine according to an embodiment of the present disclosure includes radiating light from a first light source to laundry inside a washing tub, and acquiring a first image of the laundry using a camera; detecting the amount of contamination of the laundry from the first image; and setting washing conditions according to the detection result.

As an embodiment, the method may further include detecting the amount of laundry from the first image, and the detection result may include the amount of contamination and the amount of laundry.

As an embodiment, in the setting of the washing conditions, the washing conditions may be set by adjusting the preset washing conditions according to the detection result.

As an example, the method may include irradiating light for sterilization into the washing tub from a second light source after performing washing according to the washing conditions.

As an embodiment, the method may include irradiating light from a first light source to laundry inside the washing tub after washing, and obtaining a second image of the laundry using the camera; The method may include re-detecting the amount of contamination of the laundry from the second image and determining whether to perform additional washing according to the re-detection result. As an example, the method may include irradiating light for sterilization into the washing tub from a second light source after performing the additional washing.

As an embodiment, the acquiring of the first image may include sequentially locating a plurality of color filters on an optical path of the camera and acquiring a plurality of first images sequentially passing through the plurality of color filters. step; may be included.

According to the washing machine and its control method according to the present disclosure, it is possible to set suitable washing conditions according to the amount of contamination or the amount of contamination and the amount of laundry, so that efficient washing is possible and damage to the laundry can be reduced. The light source and camera are modularized together, which can simplify the adjustment process during manufacturing. Hygienic washing is possible by adopting a light source for contamination detection and a light source for sterilization.

1 is a perspective view of a washing machine according to an embodiment of the present disclosure.
2 is a schematic perspective view of one embodiment of an image acquisition module.
3 is a view showing an example of an arrangement form of a first light source and a second light source.
4 is a view showing an example of an arrangement form of a first light source and a second light source.
5 is a diagram illustrating an example of a process of detecting the amount of laundry from an acquired image.
6 is a perspective view of one embodiment of an image acquisition module.
7 is a flowchart of a method of controlling a washing machine according to an embodiment.
8 is a flowchart of a method of controlling a washing machine according to an embodiment.
9 is a flowchart of a method of controlling a washing machine according to an embodiment.
10 is a schematic perspective view of a washing machine according to an embodiment of the present disclosure.

The terms used in this specification have been selected from general terms that are currently widely used as much as possible while considering the functions in the present invention, but these may vary depending on the intention of a person skilled in the art, precedent, or the emergence of new technologies. In addition, in a specific case, there is also a term arbitrarily selected by the applicant, and in this case, the meaning will be described in detail in the description of the invention. Therefore, the term used in the present invention should be defined based on the meaning of the term and the overall content of the present invention, not simply the name of the term. When it is said that a certain part "includes" a certain component throughout the specification, it means that it may further include other components without excluding other components unless otherwise stated.

Hereinafter, with reference to the accompanying drawings, embodiments will be described in detail so that those skilled in the art can easily carry out the present invention. However, the present invention may be embodied in many different forms and is not limited to the embodiments described herein. And in order to clearly explain the present invention in the drawings, parts irrelevant to the description are omitted, and similar reference numerals are attached to similar parts throughout the specification. Hereinafter, embodiments of the present disclosure will be described with reference to the accompanying drawings.

1 is a perspective view of a washing machine according to an embodiment of the present disclosure. 2 is a schematic perspective view of an embodiment of the image acquisition module 5 . The washing machine of this embodiment is a top-loading washing machine. 1 and 2, an embodiment of a washing machine includes a washing tub 2, a light source 52 for irradiating light into the washing tub 2, and a camera 51 for receiving reflected light of the light. (2) an image acquisition module 5 that acquires a first image of laundry inside, and a processor 61 that detects the amount of contamination of laundry from the first image before washing and sets washing conditions according to the detection result. can include

The washing machine may include a housing 1 accommodating the washing tub 2 and a door 3 opening and closing an opening provided at an upper portion of the housing 1 . The door 3 can be opened and laundry can be put into the washing tub 2 through the opening. Although not shown in the drawing, the housing 1 is a water supply/drainage structure for supplying water to the washing tub 2 and discharging water from the washing tub 2, and a washing tub 2 or water and laundry inside the washing tub 2. It may include a driving structure that rotates, and the like.

The washing machine may include a control unit 6. The controller 6 controls the washing process. For example, the controller 6 may include a processor 61 . The processor 61 may include, for example, a central processing unit (CPU). The processor 61 may be connected to the control panel 4 and driving elements of the washing machine, for example, a motor (not shown) that rotates the washing tub 2 and a water supply/drainage structure. The processor 61 may control the image acquisition module 5 to detect the amount of contamination and the amount of laundry, and may perform image processing on the obtained image. The processor 61 may set washing conditions or adjust preset washing conditions according to the detection result. The processor 61 may control driving elements of the washing machine to control a washing process according to washing conditions. The controller 6 may include a memory 62 that stores information about washing courses, such as washing time, rinsing time, and the number of times of rinsing. A control program executable by the processor 61 may be stored in the memory 62 . The memory 62 may store reference contrast information and various lookup tables to be described later. The control unit 6 may include an image processing unit that processes an image acquired by the camera 51 . The image processing unit may be implemented in the form of a control program. The image processing unit may be implemented in the form of hardware including the processor 61 .

A plurality of washing courses selectable by the user according to the amount and type of laundry may be provided to the user through the control panel 4 . A plurality of washing courses may be implemented by various combinations of washing conditions, eg, washing time and rinsing time. A user may select a desired washing course through a control unit such as a button provided on the control panel 4 . The controller 6 may control the washing process according to the selected washing course. For example, the controller 6 may control a motor (not shown) that rotates the washing tub 2 and a water supply/drain structure according to the selected washing course.

Washing conditions may affect washing performance, that is, stain removal performance and the degree of damage to laundry. Washing conditions need to be set to sufficiently remove contamination and at the same time to minimize damage to laundry. Considering this point, the washing machine of the present embodiment has a structure capable of detecting the contamination amount of laundry and setting washing conditions according to the detected contamination amount. To this end, the washing machine of this embodiment is equipped with an image acquisition module 5. The image acquisition module 5 acquires an image of laundry in the washing tub 2 .

Referring to FIGS. 1 and 2 , the image acquisition module 5 may include a light source 52 for irradiating light into the washing tub 2 and a camera 51 for receiving reflected light of the light. The camera 51 may include an image sensor that receives reflected light and converts an optical signal into an electrical signal by photoelectric conversion. As the image sensor, for example, a charge coupled device (CCD) image sensor, a complementary metal-oxide semiconductor (COMS) image sensor, or the like may be employed. The camera 51 may further include an imaging optical system for forming an image of reflected light on an image sensor. The imaging optical system may be a reduction imaging optical system that reduces reflected light and forms an image on the image sensor. The imaging optical system may include one or more lenses.

The light source 52 may be a point light source. The light source 52 may include a first light source 52a for image acquisition. The first light source 52a may emit, for example, ultraviolet light. The first light source 52a may emit long-wavelength (UV-A) ultraviolet light having a wavelength of 315 to 400 nm, for example. In this embodiment, the first light source 52a emits long-wavelength ultraviolet light having a wavelength of 360 to 380 nm. The light source 52 may further include a second light source 52b for sterilization. The second light source 52b may emit short-wavelength (UV-C) ultraviolet light having a wavelength of 100 to 280 nm, for example. In this embodiment, the second light source 52b emits short-wavelength ultraviolet light having a wavelength of 265 nm. Since short-wavelength ultraviolet light with a wavelength of 265 nm has a strong sensitivity to DNA, irradiation with short-wavelength ultraviolet light with a wavelength of 265 nm changes the structure of DNA and/or RNA in the cell nucleus of bacteria, bacteria, viruses, etc., and stops cell division function. let it As a result, the proliferation of germs, bacteria, viruses, etc. is prevented, and sterilization is possible.

Although two first light sources 52a are disposed in FIG. 2 , the scope of the invention is not limited thereby. The first light source 52a may be one or two or more. As an example, the plurality of first light sources 52a may be arranged on a circular arc or circle centered on the optical axis 51a of the camera 51 . Each interval between the plurality of first light sources 52a may be the same or may be different from each other. Optical axes of the plurality of first light sources 52a may be parallel to the optical axis 51a of the camera 51 . By arranging the plurality of first light sources 52a with the camera 51 as the center, it is possible to improve the accuracy of contaminant detection by minimizing a shaded area within an irradiation angle range of the first light source 52a. In addition, the angle of view of the camera 51 and the angle of irradiation of the first light source 52a may be simultaneously adjusted in the position adjustment process after the image acquisition module 5 is installed, thereby simplifying the adjustment process. Although two second light sources 52b are disposed in FIG. 2 , the scope of the invention is not limited thereby. The number of second light sources 52b may be one or two or more. As an example, the plurality of second light sources 52b may be arranged on a circular arc or circle centered on the optical axis 51a of the camera 51 . Each interval between the plurality of second light sources 52b may be the same or may be different from each other. Optical axes of the plurality of second light sources 52b may be parallel to the optical axis 51a of the camera 51 . By arranging the plurality of second light sources 52b with the camera 51 as the center, the sterilization effect can be improved by minimizing the shaded area within the irradiation angle range of the second light source 52b. In addition, the angle of view of the camera 51 and the angle of irradiation of the second light source 52b may be simultaneously adjusted in the position adjustment process after the image acquisition module 5 is installed, thereby simplifying the adjustment process.

3 and 4 show examples of the arrangement of the first light source 52a and the second light source 52b. As shown in FIG. 3 , four first light sources 52a and four second light sources 52b may be arranged on a circle 50a centered on the optical axis 51a of the camera 51 . The first light source 52a and the second light source 52b may be alternately arranged. As shown in FIG. 4, the four first light sources 52a are arranged on a circle 50b centered on the optical axis 51a of the camera 51, and the four second light sources 52b are arranged on the camera ( 51) may be arranged on a circle 50c centered on the optical axis 51a. The number and arrangement of the first light sources 52a and the second light sources 52b are not limited to those shown in FIGS. 3 and 4 .

The image acquisition module 5 is disposed to sufficiently illuminate the laundry inside the washing tub 2 . For example, as shown in FIG. 1 , the image acquisition module 5 may be located at the edge of the opening of the housing 1 . Of course, the image acquisition module 5 may also be installed on the door 3. The image acquisition module 5 of this embodiment is in the form of an assembly in which a light source 52 and a camera 51 are integrated. Optical axes of the camera 51 and the light source 52 may be parallel to each other. By adjusting the position of the image acquisition module 5, the shooting range of the camera 51 and the irradiation range of the light source 52 can be adjusted in one adjustment process. Accordingly, the adjustment process in the manufacturing process of the washing machine can be simplified.

The control unit 6, for example, the processor 61, before performing washing, detects the amount of contamination of the laundry from the image (first image) acquired by the image acquisition module 5, and the washing conditions according to the detection result. can be set. An image obtained by the camera 51 has a distribution of brightness and darkness according to the location and degree of contaminants. For example, contaminants may have relatively high or low brightness compared to laundry. The memory 62 may store an intensity distribution (reference intensity distribution) of the reference image. The control unit 6 may calculate a contrast distribution from the obtained image, compare the calculated contrast distribution with a reference contrast distribution, and detect a contamination amount according to the comparison result. For example, the controller 6 may obtain a difference (contrast difference) between the detected contrast distribution and the reference contrast distribution, and determine a contamination amount corresponding to the contrast difference from a lookup table stored in the memory 62 . As an example, the controller 6 may distinguish between laundry and contaminants based on the brightness distribution of the obtained image, and detect the area and brightness of the contaminants. The control unit 6 may determine the amount of contamination corresponding to the area and lightness of the contaminant from a lookup table stored in the memory 62 . The control unit 6 may set washing conditions according to the detected amount of contamination. The washing conditions may include, for example, washing time, rinsing time, and the number of rinsing. According to this configuration, it is possible to set optimal washing conditions capable of removing contaminants, so that damage to laundry due to excessive washing and rinsing can be prevented. In addition, by optimizing the washing time, rinsing time, and rinsing frequency according to the amount of contamination of the laundry, consumption of water, detergent, and energy due to excessive washing and rinsing can be prevented. In addition, since invisible contamination can be detected and removed by using ultraviolet rays as illumination light, efficient and sanitary washing is possible.

When washing conditions are preset by the user selecting a wash course through the manipulation panel 4, the controller 6, for example, the processor 61 may adjust the preset wash conditions according to the detection result. For example, based on the detection result, a washing time, a rinsing time, a rinsing number, and the like may be increased or decreased in preset washing conditions. The user may select a washing course according to the degree of contamination visually confirmed and the amount of laundry. The contamination amount based on the user's arbitrary judgment may not be accurate. In addition, there may be contamination that is not visible to the naked eye. According to the washing machine of this embodiment, efficient washing is possible by detecting the amount of contamination of the laundry using an optical means and adjusting the washing conditions set by the user according to the amount of contamination of the laundry. In addition, efficient and sanitary washing is possible by detecting invisible contamination by using ultraviolet rays as illumination light and adjusting washing conditions according to the detection result.

The detection result may include the amount of contamination and the amount of laundry. The controller 6, for example, the processor 61 may detect the amount of laundry from the acquired image. Since the angle of view (shooting range) of the camera is constant, the amount of laundry may be detected from an area occupied by laundry in an acquired image as an example. 5 is a diagram illustrating an example of a process of detecting the amount of laundry from an acquired image. Referring to FIG. 5 , the background BG represents the inner wall of the washing tub 2 and has a large difference in contrast from that of the laundry CB. An outline of the laundry CB may be determined by detecting a boundary representing a sharp contrast between light and dark. If the amount of laundry CB in the washing tub 2 is small, the water level of the laundry CB is low, so the area occupied by the laundry CB in the acquired image becomes smaller and the area occupied by the background BG increases. Accordingly, the outline can be detected as indicated by reference numeral BL1. By calculating the inner area of the outline BL1, the area occupied by the laundry CB can be calculated. Conversely, if the amount of laundry CB inside the washing tub 2 is large, the water level of the laundry CB is high, so the area occupied by the laundry CB in the acquired image increases and the area occupied by the background BG decreases. Accordingly, the outline can be detected as indicated by reference numeral BL2. The area occupied by the laundry CB can be calculated by calculating the inner area of the outline BL2. The relationship between the area of the laundry CB and the amount of laundry CB may be previously stored in the memory 62 in the form of a look-up table. The controller 6, for example, the processor 61 may determine the amount of laundry CB by referring to the look-up table from the calculated area of the laundry CB. The controller 6, for example, the processor 61 may set a washing condition based on the detected amount of contamination and the amount of laundry CB. Of course, the controller 6, for example, the processor 61 may adjust preset washing conditions by the user.

After washing, the controller 6, for example, the processor 61, acquires an image (second image) of the laundry using the image acquisition module 5 and re-detects the amount of contamination of the laundry from the acquired image. can A process of acquiring the second image and re-detecting the amount of contamination from the second image may be the same as the above-described process of acquiring the first image and detecting the amount of contamination from the first image. The controller 6, for example, the processor 61 may determine whether to perform additional washing according to the re-detected amount of contamination. For example, the controller 6 may perform additional washing when the re-detected contamination amount is greater than the reference contamination amount stored in the memory 62, for example. Additional washing may include, for example, rinsing. The controller 6 may set at least one of a rinsing time and a rinsing number according to the re-detected amount of contamination and control the washing machine to perform additional washing. With this configuration, contaminants and detergents remaining after washing can be removed, and a high washing effect can be obtained, and sanitary washing can be performed.

6 is a perspective view of one embodiment of the image acquisition module 5 . Referring to FIG. 6 , the image acquisition module 5 may include a plurality of color filters 54R, 54Y, and 54G. The plurality of color filters 54R, 54Y, and 54G may be red, yellow, and green filters, respectively. A plurality of color filters 54R, 54Y, and 54G are sequentially placed on the optical path of the camera 51. As an example, the plurality of color filters 54R, 54Y, and 54G may be rotated by the driving motor 53 and sequentially positioned on the optical path of the camera 51. A plurality of color filters 54R, 54Y, and 54G are sequentially positioned on an optical path of the camera 51, and light passing through each of the plurality of color filters 54R, 54Y, and 54G is transmitted to the camera 51. ) to obtain a plurality of images. According to this configuration, it is possible to easily identify various types of contaminants, for example, oily contaminants, water-based contaminants, fluorescent substances, and the like, by reducing background reflected light.

Images obtained by applying the color filters 54R, 54Y, and 54G may have different contrast distributions. Images obtained by applying the color filters 54R, 54Y, and 54G may have a different intensity distribution from images obtained without applying the color filters 54R, 54Y, and 54G. This is because light reflectivity is different depending on the type of contaminant. Therefore, by applying the color filters 54R, 54Y, and 54G, the reflected light of the part that becomes the background of the contaminant is removed, so that the contaminant can be better detected, and various types of contaminants having different reflection characteristics can be detected. can As an example, the controller 6 may synthesize a plurality of images acquired by applying the color filters 54R, 54Y, and 54G, and calculate a contrast distribution from the synthesized images. The control unit 6 may compare the calculated intensity distribution with a reference intensity distribution, and detect the contamination amount according to the comparison result. As an example, the controller 6 may calculate the intensity distribution of a plurality of images, and calculate the final intensity distribution by summing the calculated intensity distributions. Then, the control unit 6 may compare the final intensity distribution with the reference intensity distribution and detect the contamination amount according to the comparison result. As an example, the controller 6 may distinguish between laundry and contaminants based on the brightness distribution of the plurality of images, and detect the area and brightness of the contaminants. The control unit 6 may determine the amount of contamination corresponding to the area and lightness of the contaminant from a lookup table stored in the memory 62 . In addition, the amount of contamination may be detected from a plurality of images obtained by receiving light passing through the color filters 54R, 54Y, and 54G by various other methods. The user can check the contamination of the laundry with his eyes and set washing conditions. When a color filter is applied, it is possible to detect contaminants that are invisible to the naked eye, so that more appropriate washing conditions can be set to remove the contaminants. Therefore, effective and sanitary washing is possible.

Hereinafter, embodiments of a control method for a washing machine will be described. 7 is a flowchart of an example of a method for controlling a washing machine. 1 to 6 , in an embodiment of a method of controlling a washing machine, a first light source 52a irradiates laundry inside the washing tub 2 with light, and a camera 51 is used to generate a first image of the laundry. It may include obtaining (S110), detecting the amount of contamination of the laundry from the first image (S120), and setting washing conditions according to the detection result (S130).

A user may open the door 3 and put laundry into the washing tub 2 . When a wash start command is input through the manipulation panel 4, the control unit 6 acquires an image (first image) of the laundry using the image acquisition module 5. For example, the controller 6 controls the first light source 52a to radiate light into the washing tub 2 . The light may be, for example, long-wavelength ultraviolet light having a wavelength of 360 to 380 nm. The camera 51 receives the light reflected from the laundry and converts the optical signal into an electrical signal through a photoelectric conversion process. The electrical signal is converted into a digital signal via an amplifier or an analog-to-digital converter, for example. The controller 6 can obtain data of the first image from the digital signal.

When the image acquisition module 5 having the color filters 54R, 54Y, and 54G shown in FIG. 6 is employed, the controller 6 sequentially applies the color filters 54R, 54Y, and 54G to the camera. 51, and the first images to which the color filters 54R, 54Y, and 54G are applied, respectively, can be obtained. For example, the control unit 6 first places, for example, a color filter 54R in an optical path of the camera 51, receives the light reflected from the laundry using the camera 51, and photoelectric conversion-amplification-AD Through the conversion process, a digital signal of the first image to which the color filter 54R is applied is obtained. Next, the controller 6 places the color filter 54Y on the optical path of the camera 51 and obtains a digital signal of the first image to which the color filter 54Y is applied. Next, the controller 6 places the color filter 54G on the optical path of the camera 51 and obtains a digital signal of the first image to which the color filter 54G is applied. The controller 6 may obtain data of the first image from digital signals of the first images to which the color filters 54R, 54Y, and 54G are applied.

Next, the controller 6 detects the amount of contamination using the data of the first image. As an example, the control unit 6 may detect the intensity distribution according to the location and degree of contaminants from the first image data, compare them with the reference intensity distribution stored in the memory 62, and detect the amount of contamination according to the comparison result. . For example, the controller 6 may obtain a difference (contrast difference) between the detected contrast distribution and the reference contrast distribution, and determine a contamination amount corresponding to the contrast difference from a lookup table stored in the memory 62 . As an example, the controller 6 classifies laundry and contaminants from the brightness distribution of the acquired image, detects the area and lightness of the contaminants, and then determines the amount of contamination corresponding to the area and brightness of the contaminants from a look-up table stored in the memory 62. can decide

According to an embodiment of the method for controlling the washing machine, the step of detecting the amount of laundry from the first image (S150) may be further included. For example, as shown in FIG. 5 , the controller 6 determines the outline BL1 or BL2 of the laundry CB by using a contrast difference between the background BG and the laundry CB from the first image, and , the area within the outline BL1 or BL2 can be calculated. The controller 6 may determine the amount of laundry CB by referring to the look-up table of the memory 62 based on the calculated area.

Next, the controller 6 may set washing conditions according to the detection result, that is, the amount of contamination or the amount of contamination and the amount of laundry (S130). The washing conditions may include, for example, washing time, rinsing time, and the number of rinsing. The controller 6 controls the washing machine to perform washing according to set washing conditions (S140). The washing process may include, for example, washing, rinsing, and spin-drying. When washing is completed, the control unit 6 may generate a visual and audible signal indicating completion of washing through the manipulation panel 4 . Since the amount of contamination of the laundry or the amount of contamination and the amount of laundry may be detected, an optimal washing condition capable of removing the contamination may be set, and thus damage to the laundry due to excessive washing time may be prevented. In addition, by optimizing the washing time according to the amount of contamination of the laundry, an increase in energy consumption due to excessive washing time may be prevented.

One embodiment of the control method of the washing machine may further include a step of sterilizing the inside of the washing tub 2 by irradiating light for sterilization from the second light source 52b to sterilize after washing (S160). The second light source 52b may emit short-wavelength ultraviolet light having a wavelength of 265 nm, for example. Since short-wavelength ultraviolet light with a wavelength of 265 nm has a strong sensitivity to DNA, irradiation with short-wavelength ultraviolet light with a wavelength of 265 nm changes the structure of DNA and/or RNA in the cell nucleus of bacteria, bacteria, viruses, etc., and stops cell division function. let it This prevents the growth of germs, bacteria, viruses and the like. Therefore, it is possible to sterilize the inside of the washing tub 2 and the laundry.

8 is a flowchart of a method of controlling a washing machine according to an embodiment. Referring to FIG. 8 , steps S110, S120, S130, S140, S150, and S160 are the same as those described in FIG. 7 . The washing machine control method according to the present embodiment includes the steps of radiating light from a first light source 52a to laundry inside the washing tub 2 after washing, and obtaining a second image of the laundry using a camera 51 ( S210), and a step of re-detecting the amount of contamination of the laundry from the second image and determining whether to perform additional washing (S230) according to the re-detection result (S220).

The controller 6 may detect whether contaminants are well removed after washing and whether detergent remains in the laundry. The controller 6 acquires a second image of the laundry using the camera 51 and re-detects the amount of contamination of the laundry from the second image. Contamination can refer to contamination and residual detergents that have not been removed. The process of acquiring the second image is the same as the process of obtaining the first image described above. The process of re-detecting the amount of contamination is the same as the process of detecting the amount of contamination from the first image. The controller 6 may determine whether to perform additional washing according to the re-detected contamination amount. The controller 6 may perform additional washing when the re-detected contamination amount is greater than the reference contamination amount stored in the memory 62, for example. Additional washing may include, for example, rinsing. The controller 6 may set at least one of a rinsing time and a rinsing number according to the re-detected amount of contamination and control the washing machine to perform additional washing. A sterilization step ( S160 ) may be performed after additional washing is completed. With this configuration, contaminants and detergent remaining after washing are removed, so that sanitary washing is possible. When the re-detected contamination amount is smaller than the reference contamination amount, the controller 6 may control the washing machine to perform the sterilization step (S160) without performing additional washing.

9 is a flowchart of a method of controlling a washing machine according to an embodiment. Referring to FIG. 9 , steps S110, S120, S130, S140, S150, S160, S210, S220, and S230 are the same as those described in FIGS. 7 and 8 . The washing machine control method according to this embodiment differs in a process of setting washing conditions after detecting the amount of contamination from the first image. A user may select one of a plurality of washing courses provided through the operation panel 4 after putting laundry into the washing tub. The controller 6 detects the amount of contamination or the amount of contamination and the amount of laundry from the first image of the laundry, and then determines whether a preset washing condition exists (S310). When there is no preset washing condition, the controller 6 sets washing conditions according to the detected amount of contamination or the amount of contamination and the amount of laundry (S130) and controls the washing machine to perform washing (S140). When there are preset washing conditions, the controller 6 determines whether the preset washing conditions are appropriate according to the detected amount of contamination or the amount of contamination and the amount of laundry (S320). When the preset washing conditions are appropriate, the controller 6 controls the washing machine to perform washing according to the preset washing conditions. If the preset washing conditions are inappropriate, the controller 6 adjusts the washing conditions according to the detected amount of contamination or the amount of contamination and the amount of laundry (S330). Adjustment of washing conditions may include, for example, increasing or decreasing washing time, rinsing time, or rinsing number. The controller 6 controls the washing machine to perform washing according to the adjusted washing conditions. According to this configuration, when the user selects the wrong washing course, the washing conditions can be adjusted according to the amount of contamination or the amount of contamination and the amount of laundry. Therefore, it is possible to perform effective washing with well-removed stains, prevent damage to laundry due to excessive washing, and reduce energy waste.

When washing is completed, the controller 6 may acquire a second image of the laundry according to steps S210, S220, and S230, re-detect the amount of contamination from the second image, and determine whether to perform additional washing according to the re-detection result. . The controller 6 may control the washing machine to perform the sterilization step (S160) after performing additional washing.

10 is a schematic perspective view of a washing machine according to an embodiment of the present disclosure. The washing machine of this embodiment is a drum type washing machine. Referring to FIG. 10 , an embodiment of a washing machine includes a washing tub 2 and an image acquisition module 5 for acquiring an image of laundry inside the washing tub 2 by irradiating light into the washing tub 2 and receiving reflected light. and a control unit 6 that detects the amount of contamination of the laundry from the image before washing and sets washing conditions according to the detection result. The image acquisition module 5 is the same as described in FIGS. 1, 2, and 6 .

The washing machine may include a housing 1 accommodating the washing tub 2 and a door 3 opening and closing an opening provided on a side of the housing 1 . The door 3 can be opened and laundry can be put into the washing tub 2. Although not shown in the drawing, the housing 1 is a water supply/drainage structure for supplying water to the washing tub 2 and discharging water from the washing tub 2, and a washing tub 2 or water and laundry inside the washing tub 2. It may include a driving structure that rotates, and the like. The image acquisition module 5 may be positioned at an appropriate location capable of illuminating the inside of the washing tub 2 and acquiring an image. For example, the image acquisition module 5 may be located at the edge of an opening of the housing 21 opened and closed by the door 3 . Of course, the image acquisition module 5 may also be located on the door 3 .

The washing machine may include a control unit 6. The controller 6 controls the washing process. For example, the controller 6 may include a processor 61 . The processor 61 may be connected to the control panel 4 and driving elements of the washing machine, for example, a motor (not shown) rotating the washing tub 2 and a water supply/drainage structure. The controller 6 may include a memory 62 that stores information about washing courses, such as washing time, rinsing time, and the number of times of rinsing. A control program executable by the processor 61 may be stored in the memory 62 . The controller 6 may control the washing process according to the washing conditions of the washing course selected by the user or the washing conditions set or adjusted according to the amount of contamination. For example, the controller 6 may control a motor (not shown) that rotates the washing tub 2 and a water supply/drain structure according to the selected washing course. The control unit 6 may include an image processing unit that processes an image acquired by the camera 51 . The image processing unit may be implemented in the form of a control program. The image processing unit may be implemented in the form of hardware.

The technical idea including the image acquisition module 5 and the control unit 6 that detects the amount of contamination from the acquired image and controls the washing machine according to the detection result can also be applied to a clothes handler that removes contamination from clothes using air and vibration. can In this case, the housing 1 may include an accommodating portion accommodating clothes, a vibration generator vibrating the clothes, and a hot air supplier supplying hot air into the accommodating portion. The image acquisition module 5 radiates light to the clothing in the accommodating unit and obtains an image of the clothing from the reflected light. The control unit 6 may detect the amount of contamination of the clothes from the acquired image, and may set treatment conditions for the clothes, such as vibration intensity, hot air temperature, hot air supply time, etc., according to the detection result. When there are preset processing conditions, the controller 6 can adjust the processing conditions according to the detection result. The image acquisition module 5 may sterilize the clothes by irradiating the clothes with short-wavelength ultraviolet light using the second light source 52b while the clothes are being treated.

Although the embodiments have been described in detail above, the scope of the present invention is not limited thereto, and various modifications and improvements of those skilled in the art using the basic concept of the present invention defined in the following claims are also within the scope of the present invention. belongs to

Claims (15)

washing tub;
an image acquisition module including a light source for radiating light into the washing tub and a camera for receiving reflected light of the light to acquire a first image of laundry inside the washing tub;
A washing machine comprising: a processor which detects the amount of contamination of the laundry from the first image before washing, and sets washing conditions according to the detection result. According to claim 1,
The processor detects the amount of laundry from the first image;
The detection result includes the amount of contamination and the amount of laundry. According to claim 1,
The washing machine is a washing condition in which the processor sets the washing condition by adjusting a predetermined washing condition according to the detection result. According to claim 1,
After performing washing, the processor obtains a second image of the laundry using the image acquisition module, re-detects the amount of contamination from the second image, and determines whether to perform additional washing according to the re-detection result. washing machine to do. According to claim 1,
The light source includes a first light source for image detection and a second light source for sterilization,
The washing machine according to claim 1 , wherein the processor controls the second light source to sterilize the washing tub and the laundry after washing is performed. According to claim 5,
The first light source includes a plurality of first light sources disposed on a circular arc centered on an optical axis of the camera. According to claim 5,
An optical axis of the first light source and an optical axis of the camera are parallel to each other. According to claim 1,
The image acquisition module includes a plurality of color filters sequentially positioned in an optical path of the camera. irradiating light from a first light source to the laundry inside the washing tub and acquiring a first image of the laundry using a camera;
detecting the amount of contamination of the laundry from the first image;
A control method for a washing machine comprising: setting washing conditions according to the detection result. According to claim 9,
Further comprising: detecting the amount of laundry from the first image;
The detection result includes the amount of contamination and the amount of laundry. According to claim 9,
The setting of the washing conditions may include setting the washing conditions by adjusting preset washing conditions according to the detection result. According to claim 9,
and irradiating light for sterilization from a second light source into the washing tub after performing washing according to the washing conditions. According to claim 9,
after washing, irradiating light from a first light source to the laundry inside the washing tub and acquiring a second image of the laundry using the camera;
A control method for a washing machine, comprising: re-detecting the amount of contamination of the laundry from the second image, and determining whether to perform additional washing according to the re-detection result. According to claim 13,
and irradiating light for sterilization into the washing tub from a second light source after performing the additional washing. According to claim 9,
The step of obtaining the first image,
and sequentially positioning a plurality of color filters on an optical path of the camera and acquiring a plurality of first images sequentially passing through the plurality of color filters.

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