JP6411724B2 - Washing machine - Google Patents

Description

  Embodiments described herein relate generally to a washing machine.

  Conventionally, it has been considered to provide various functional films on a water tank of a washing machine. For example, Patent Document 1 discloses a technique in which a heat insulating paint film is provided on the inner surface of a water tank in order to reduce power consumption during drying. Further, in this Patent Document 1, by including hydrophilic hollow beads in the water-repellent heat-insulating coating film, the water film adhering to the surface of the film is spread and evaporated. It is disclosed to further reduce power consumption.

  By the way, in recent years, paints that exhibit antifouling functions due to hydrophilicity have been developed, and if such paints are applied to the inner surface of a water tank of a washing machine, the antifouling function keeps the inner surface of the water tank clean. Can do. However, the water stored in the water tank is contacted with the inner surface of the water tank during the washing operation or the rinsing operation, and the water splashed from the internal rotating tank is also in contact with the water during the dehydration operation. Therefore, the inner surface of the water tank can be kept relatively clean without applying such antifouling function paint, and therefore even if the antifouling function is held on the inner surface of the water tank, the function is effective. It cannot be used.

JP 2010-172436 A

  The present embodiment provides a washing machine in which an antifouling function due to hydrophilicity is applied to a part where the function can be most effectively utilized.

In the washing machine of the present embodiment, a hydrophilic coating is applied to the entire outer surface of a rotating tub provided rotatably in the water tub , and the hydrophilic coating is formed by a silica-based paint containing silicon oxide. is, have a siloxane skeleton, suppresses the growth of fungus to 99% or more even in the wet state of a relative humidity of 90% or more.

1 is a longitudinal sectional view schematically showing a configuration of a drum type washing machine according to a first embodiment. 1 is a longitudinal side view schematically showing the configuration of a vertical washing machine according to a first embodiment. The figure which shows the development view of the rotation tank typically Diagram showing the conditions and results of practical tests A diagram that visually shows the results of a practical test The figure which shows the test result of the simulation dirt washing test The figure which shows the test result of the simulation dirt washing test visually FIG. 3 equivalent diagram showing an example of a test target site in a mold adhesion and growth inhibition confirmation test The figure which shows the test result of mold adhesion and growth suppression confirmation test FIG. 1 equivalent view according to the second embodiment FIG. 2 equivalent diagram according to the second embodiment FIG. 1 equivalent view according to the third embodiment FIG. 2 equivalent diagram according to the third embodiment. FIG. 1 equivalent view (No. 1) according to a modified embodiment FIG. 1 equivalent view (No. 2) according to a modified embodiment FIG. 2 equivalent view according to a modified embodiment According to a modified embodiment, (a) is an enlarged view of the periphery of a hole showing an example of a configuration not having a hydrophilic performance portion on the end face of the hole, and (b) is an example of a configuration having a hydrophilic performance portion on the end face of the hole. Enlarged view around the hole showing

Hereinafter, a plurality of embodiments according to a washing machine will be described with reference to the drawings. In addition, the same code | symbol is attached | subjected to the substantially same element in each embodiment, and description is abbreviate | omitted.
(First embodiment)
A washing machine 100 shown in FIG. 1 is a so-called horizontal shaft type drum-type washing machine in which the rotation center axis of a rotating tub is horizontal or slightly inclined, and an outer box 101 constituting the outer shell is a base made of a synthetic resin. It is comprised from the base 102 and the box main body 103 couple | bonded with the base 102. FIG. In FIG. 1, a laundry doorway 104 is provided at a substantially central portion of the front portion of the box body 103 on the left side. A door 105 for opening and closing the laundry entrance 104 is provided on the front surface of the box body 103. An operation panel 106 is provided on the upper portion of the front surface of the box body 103. A control device 107 that controls the overall operation of the washing machine 100 is provided on the back side of the operation panel 106. Inside the outer box 101 is provided a bottomed cylindrical water tank 108 whose bottom side, which is the bottom, is closed. The water tank 108 is elastically supported by the suspension 109 so that its central axis is located on a slightly inclined axis that descends toward the rear in FIG.

  A motor 110 is provided outside the back of the water tank 108. The motor 110 is constituted by, for example, a DC brushless motor, is an outer rotor type, and includes a stator 111 and a rotor 112. The stator 111 is fixed to the outside of the back surface portion of the water tank 108. A rotation shaft 113 is provided at the center of the rotor 112. The rotating shaft 113 is supported by a bearing bracket 114 via a bearing 115 and is inserted into the water tank 108. Inside the water tank 108 is provided a bottomed cylindrical drum 116 whose bottom side, which is the bottom, is closed.

  The drum 116 is made of metal such as stainless steel. The drum 116 is fixed to the tip of the rotating shaft 113 of the motor 110 at the center of the back surface thereof, and is provided to be rotatable about the axis of the water tank 108, that is, the axis inclined downward toward the rear. In this case, the motor 110 functions as a drive device that rotates the drum 116. A reinforcing member 117 for reinforcing the back surface of the drum 116 is provided on the bottom of the drum 116, in other words, on the outer surface of the back surface. The reinforcing member 117 is made of metal such as aluminum die-casting. A large number of holes 118 are formed over the entire area of the peripheral wall portion constituting the drum portion of the drum 116. These holes 118 penetrate therethrough and allow water and air to pass therethrough. In addition, a plurality of synthetic resin baffles 119 for washing up laundry are provided on the inner periphery of the drum 116. The water tank 108 may be provided so that its central axis is positioned on a horizontal axis that does not incline. In this case, the drum 116 is provided so as to be rotatable about the horizontal axis.

  Each of the drum 116 and the water tank 108 is open on the front side, and has an opening 120 and an opening 121. Around the opening 120 of the drum 116, a synthetic resin balance ring 122 in which a liquid such as salt water is enclosed is provided. The balance ring 122 is fixed from the outer surface side of the drum 116 by a metal screw (not shown) made of, for example, stainless steel. The opening 121 of the water tub 108 is connected to the laundry entrance / exit 104 via an annular bellows 123 made of an elastic material such as rubber. Thereby, the laundry entrance / exit 104 is connected to the inside of the drum 116 via the bellows 123, the opening 121 of the water tank 108, and the opening 120 of the drum 116.

  A drain outlet 124 is provided at the bottom on the back side of the water tank 108. One end of an in-machine drain hose 125 is connected to the drain port 124. The other end of the in-machine drain hose 125 is connected to a filter case 126 provided at the front of the base 102 of the outer box 101. A cap 127 is detachably attached to the front end of the filter case 126. Inside the filter case 126, a lint filter (not shown) provided integrally with the cap 127 is accommodated. A drain valve 128 is connected to the lower part of the filter case 126. A drain pipe 129 is connected to the outlet of the drain valve 128. The distal end portion of the drain pipe 129 is led out of the machine from the base 102 of the outer box 101 and connected to a machine drain hose (not shown).

  An air trap 130 is provided above the filter case 126. The air trap 130 and the water level sensor 131 disposed in the upper part of the outer box 101 are connected by an air tube 132. The water level sensor 131 detects the water level in the water tank 108 via the in-machine drain hose 125, the filter case 126, the air trap 130, and the air tube 132, and outputs it to the control device 107.

  A water supply valve 133 and a water supply case 134 are provided in the upper part of the outer box 101. An external water supply hose extending from a faucet (not shown) is connected to the inlet of the water supply valve 133. One end of a connection pipe 135 is connected to the outlet of the water supply valve 133. The other end of the connection pipe 135 is connected to the water supply case 134. A detergent storage section (not shown) is provided inside the water supply case 134. One end of an in-machine water supply hose 136 is connected to the water supply case 134. The other end of the in-machine water supply hose 136 is connected to the upper part of the water tank 108. Water supplied from the water supply via the water supply valve 133 is supplied into the water tank 108 via the connection pipe 135, the water supply case 134 and the in-machine water supply hose 136.

  A washing machine 200 shown in FIG. 2 is a so-called vertical axis type washing machine in which a rotation center axis of a rotating tub extends in a vertical direction, and a bottomed cylinder whose upper surface is opened inside an outer box 201 constituting the outer shell. A water tank 202 is elastically supported by an elastic suspension mechanism 203. Inside the water tank 202, a bottomed cylindrical rotating tank 204 having an open upper surface is rotatably provided.

  The rotating tank 204 has a body portion made of a metal first member 204a made of, for example, stainless steel, and a bottom portion made of a synthetic resin second member 204b. A reinforcing member 204c for reinforcing the second member 204b, in other words, the bottom of the rotating tub 204, is provided outside the second member 204b constituting the bottom of the rotating tub 204. The reinforcing member 204c is made of metal such as a stainless plate. The rotating tub 204 is configured to rotate about a vertical axis, and is a washing tub for washing laundry, a washing tub for rinsing the laundry, and a dehydration tub for a dehydration step for dehydrating the laundry. Also used as. The rotary tank 204 has a large number of holes 205 in its peripheral wall. These holes 205 are penetrating and allowing water and air to pass therethrough. In the drawing, only a part of these holes 205 is shown. A balance ring 206 made of synthetic resin in which a liquid such as salt water is enclosed is attached to the upper part of the rotating tub 204. The balance ring 206 is fixed from the outer surface side of the rotating tub 204 by a metal screw 206a made of, for example, stainless steel. A synthetic resin stirring body 207 is rotatably provided at the bottom of the rotary tank 204.

  A drainage path 208 is provided below the water tank 202. The drainage path 208 is provided with a drainage valve 209. By opening the drainage valve 209, the water in the water tank 202 is discharged outside the apparatus. In addition, an air trap 210 for water level detection is provided at the bottom of the water tank 202. A water level sensor (not shown) is connected to the air trap 210 via an air tube 211. In this case, the water level sensor includes a pressure sensor, and detects the water level in the water tank 202 based on the pressure in the air trap 210.

  A drive mechanism 213 is provided at the center of the lower part of the water tank 202. The drive mechanism unit 213 includes a motor capable of variable speed drive, a clutch mechanism, a reduction gear, a brake device, and the like. During the washing process or the rinsing process, the drive mechanism 213 decelerates the rotational force of the motor by the speed reducer and transmits it to the agitator 207 by the clutch mechanism. During the dehydration process, the drive mechanism unit 213 transmits the rotational force of the motor to the rotating tub 204 and the stirring body 207 at a high speed by the clutch mechanism without being decelerated by the reduction device.

  A top cover 214 is provided on the outer box 201. The top cover 214 is provided with an openable / closable lid 215 that opens and closes the laundry doorway, for example. A tank cover (not shown) is attached to the upper part of the water tank 202 so as to be openable and closable. An operation panel 217 is provided on the front portion of the top cover 214. A control device (not shown) that controls the overall operation of the washing machine 200 is provided on the back side of the operation panel 217. A water supply mechanism (not shown) that supplies water from the water supply into the water tank 202 is provided at the rear portion of the top cover 214.

  As shown in FIG. 1, the above-described washing machine 100 includes a hydrophilic performance film 300 that is an example of a hydrophilic performance section on at least the outer surface of the side portion of the drum 116. In this case, the hydrophilic performance film 300 is formed on the entire outer surface of the side portion of the drum 116. As shown in FIG. 2, the above-described washing machine 200 includes a hydrophilic performance film 300 that is an example of a hydrophilic performance section on at least the outer surface of the first member 204 a that forms the side portion of the rotating tub 204. In this case, the hydrophilic performance film 300 is formed on the entire outer surface of the side of the rotating tub 204. Next, the hydrophilic performance membrane 300 will be described in more detail. The hydrophilic performance film 300 is formed by spraying a coating having a hydrophilic performance such as a silica-based inorganic coating (hereinafter referred to as “hydrophilic material”) on the outer surface of the drum 116 or the outer surface of the rotating tank 204. It is.

  In this case, since both the drum 116 and the rotating tub 204 are made of metal, coating can be performed by spraying a hydrophilic material onto the outer surface of the drum 116 or the outer surface of the rotating tub 204 and baking it. Can be. Note that the baking temperature of the hydrophilic material is preferably set at a temperature higher than 250 ° C., which is generally considered to be a temperature at which organic matter is decomposed, and may be set at a temperature of 300 ° C. or 500 ° C., for example. . By baking the hydrophilic material at such a high temperature, the organic matter contained in the hydrophilic material can be almost or completely decomposed, and the hydrophilic performance film 300 that is almost or completely mineralized can be formed. .

  Moreover, when coating this kind of material, it is common to perform the degreasing process which degreases the surface of the said base material before spraying a material on a base material. In this embodiment, since the drum 116 and the rotating tub 204, which are the base materials, are both made of stainless steel, degreasing is performed using a strong alkaline degreasing agent such as PH14 in the degreasing treatment performed before spraying the hydrophilic material. be able to. Therefore, the hydrophilic material can be sprayed after the oil and fat components are almost or surely removed from the surface of the drum 116 as a base material or the surface of the rotating tub 204, and the surface of the drum 116 or the surface of the rotating tub 204 can be sprayed. It becomes easy to get familiar with hydrophilic materials.

  Moreover, in this embodiment, the hydrophilic material which forms the hydrophilic performance film | membrane 300 which has the following performance at least is applied. That is, the hydrophilic performance film 300 of the present embodiment has a hydrophilic performance such that the contact angle of water is less than the lower limit value of the contact angle of water with respect to glass. Generally, the lower limit of the contact angle of water with respect to glass is considered to be 20 degrees. Therefore, in this embodiment, the hydrophilic material forming the hydrophilic performance film 300 in which the contact angle of water is less than 20 degrees, for example, 13 degrees is applied.

  In the present embodiment, a material containing silicon oxide is applied as the hydrophilic material forming the hydrophilic performance film 300, and the hydrophilic performance film 300 formed of this hydrophilic material has at least a pencil hardness of 5H or more. It has the following hardness characteristics. That is, the hydrophilic performance film 300 according to the present embodiment has a strong structure formed of a so-called siloxane skeleton and an alkali metal or alkaline earth metal. As a result, the hydrophilic performance film 300 has a pencil hardness of 5H or more. It has a strong structure.

  Moreover, the hydrophilic performance film | membrane 300 of this embodiment has a silanol group, The hydrophilic performance is a very high thing. Specifically, the hydrophilic performance film 300 has such a hydrophilic performance that a general oil-based ink attached to the hydrophilic performance film 300 can be removed only by contacting with water. Therefore, even when general oil-based pen ink is attached to the hydrophilic performance film 300, the ink is peeled off and removed so as to be lifted by water by bringing water into contact therewith.

  Moreover, the hydrophilic performance film | membrane 300 of this embodiment is 10 micrometers or less in thickness, and the film thickness is very thin. That is, in general, when it is desired to improve the hydrophilic performance, it is necessary to repeat the coating of the hydrophilic material. Therefore, the thickness of the obtained hydrophilic performance portion tends to increase. In the present embodiment, a hydrophilic material in which the hydrophilic performance film 300 having extremely high hydrophilic performance is formed by one-time coating and baking of the hydrophilic material is applied. Therefore, it is possible to form the hydrophilic performance film 300 having extremely high hydrophilic performance without repeating the coating of the hydrophilic material, and thereby the thickness of the hydrophilic performance film 300 can be suppressed to a thickness of 10 μm or less. . In the drawing, for the sake of convenience, the film thickness of the hydrophilic performance film 300 is shown to be larger than the actual film thickness.

  Further, the hydrophilic performance film 300 of the present embodiment has a so-called surface roughness of 2 μm or less. In the present embodiment, a hydrophilic material on which the hydrophilic performance film 300 having an extremely smooth surface is formed is applied. In addition, the hydrophilic material applied in the present embodiment is milky white before spraying, but becomes transparent so that milky white is hardly recognized after spraying, and becomes almost or completely transparent after baking.

  Next, the test result performed in order to evaluate the antifouling performance of the washing machine according to the present embodiment will be described. Here, for example, the following “practical test”, “simulated soil washing test”, and “mold adhesion and growth suppression confirmation test” were performed. In each test, for example, the test rotary tank T schematically shown in FIG. 3, that is, the hydrophilic performance film 300 is coated on the outer circumferential surface Ra of the side portion, and the remaining half circumferential portion Rb is hydrophilic. A test washing machine including a rotating tub T not coated with the performance film 300 was used. Hereinafter, the portion Ra coated with the hydrophilic performance film 300 is referred to as “coating portion Ra”, and the portion Rb not coated with the hydrophilic performance film 300 is referred to as “uncoated portion Rb”.

≪Practical test≫
In this “practical test”, a test washing machine was actually used in the A house and the B house under the following conditions. Then, after use, the surface of the coating portion Ra and the surface of the uncoated portion Rb of the rotating tub are wiped off with different cloths, and the increase in the weight of each cloth after wiping is respectively measured as the amount of dirt adhered to the coating portion Ra. This was observed as the amount of dirt adhered to the coating portion Rb. In addition, the unit of dirt adhesion amount is indicated by “mg / 25 cm ² ”, that is, the weight per 25 cm ² . Moreover, the stain | pollution | contamination adhering to a rotation tank after use may also contain the detergents used at the time of test driving | operation (the detergents which remain | survived slightly after completion | finish of driving | operation).

・ A house As shown in FIG. 4, for example, in the A house, a commercially available liquid detergent a and a softening finish a are used, and a general washing operation (a washing process, a rinsing process, a dehydrating process) Typical washing operation) and 75 cycles of normal drying operation. In House A, driving was performed using bath water.

In this case, the dirt adhesion amount of the coating portion Ra was not more than the detection limit value (0.01 mg / 25 cm ² ). On the other hand, the dirt adhesion amount of the uncoated portion Rb was 0.5 mg / 25 cm ² . That is, it was confirmed that the coating portion Ra exhibits a much higher antifouling performance than the uncoated portion Rb under the use conditions in the A house.

-B house For example, as shown in FIG. 4, in the B house, generally used powder detergent b, liquid detergent b, and softening agent b are used, and a normal washing operation (washing process, rinsing process, dehydration) is performed. A general washing operation consisting of a stroke) was performed for 76 cycles, and a normal drying operation was performed for several cycles. In House B, operation was performed using tap water.

In this case, the dirt adhesion amount of the coating portion Ra was not more than the detection limit value (0.01 mg / 25 cm ² ). On the other hand, the dirt adhesion amount of the uncoated portion Rb was 0.2 mg / 25 cm ² . In other words, it was confirmed that the coating portion Ra exhibited much higher antifouling performance than the uncoated portion Rb even under the usage conditions at house B. FIG. 5 visually shows the test result (dirt adhesion amount) obtained by the “practical test”.

≪Simulated dirt washing test≫
In this “simulated dirt washing test”, the clothes to which the pseudo dirt was attached were put into a rotating tub of a test washing machine, and a normal washing operation was performed a predetermined number of times. Then, after the washing operation was performed a predetermined number of times, a normal tank cleaning operation (an operation for storing water in the water tank and rotating the rotating tank in order to clean the water tank) was performed. In this case, a total of about 4.0 g of pseudo soil consisting of approximately 2.8 g of mud soil and approximately 1.2 g of lard was adhered to the clothing. In the washing process, a commercially available powder detergent was used, and water having a hardness of 50 ppm was used as water for washing or rinsing.

  FIG. 6 shows the amount of dirt attached to the coating portion Ra and the amount of dirt attached to the uncoated portion Rb observed before and after the tank cleaning operation in this “simulated stain washing test”. In this case as well, the dirt adhering to the rotating tank may include detergents used during the test operation (detergents slightly remaining after the operation is completed).

For example, when 30 cycles of a normal washing operation are performed, the amount of dirt adhered to the coating portion Ra is not more than the detection limit value (0.01 mg / 25 cm ² ) before the tank cleaning operation, and the detection limit value even after the tank cleaning. (0.01 mg / 25 cm ² ) or less. On the other hand, the amount of dirt adhering to the uncoated portion Rb was 0.3 mg / 25 cm ² before the tank cleaning operation and 0.1 mg / 25 cm ² even after the tank cleaning. That is, as much as 0.1 mg / 25 cm ^{2 of} dirt remains in the uncoated portion Rb even if the tank cleaning operation is performed, while in the coating portion Ra, the detection amount of the dirt is detected without performing the tank cleaning operation. It can be suppressed below the value. As described above, it was confirmed that the coated portion Ra exhibited a much higher antifouling performance than the uncoated portion Rb. FIG. 7A visually shows a test result (dirt adhesion amount) when 30 cycles of a normal washing operation are executed.

Further, for example, when 90 cycles of a normal washing operation are performed, the amount of dirt adhered to the coating portion Ra is equal to or less than a detection limit value (0.01 mg / 25 cm ² ) before the tank cleaning operation, and is detected even after the tank cleaning. It was below the limit value (0.01 mg / 25 cm ² ). On the other hand, the amount of dirt adhered to the uncoated portion Rb was 0.7 mg / 25 cm ² before the tank cleaning operation and 0.3 mg / 25 cm ² even after the tank cleaning. That is, as much as 0.3 mg / 25 cm ^{2 of} dirt remains in the uncoated portion Rb even if the tank cleaning operation is performed, while in the coating portion Ra, the detection amount of the dirt is detected without performing the tank cleaning operation. It can be suppressed below the value. As described above, it was confirmed that the coated portion Ra exhibited a much higher antifouling performance than the uncoated portion Rb. FIG. 7B visually shows a test result (dirt adhesion amount) when 90 cycles of a normal washing operation are executed.

≪Must adhesion and growth suppression confirmation test≫
This “mold adhesion and growth suppression confirmation test” has the following contents.
-Test object part As shown in FIG. 8, 12 places (3 rows x 4 rows) indicated by broken lines in the coated portion Ra, and 12 places (3 rows x vertical rows) indicated by broken lines in the uncoated portion Rb. (4th row) was set as a test object site. In addition, the size of each test target part has an area of 80 mm × 32 mm, that is, an area corresponding to 25 cm ² .

・ Operating conditions A washing operation consisting of the following steps was performed.
Washing operation: washing process → first intermediate dehydration process → first rinsing process → second intermediate dehydration process → second rinsing process → final dehydration process

• Mold used in the test The following mold was used in the test.
Exophiala dermatitidis NBRC 6421

・ Test method (outline)
Using the test washing machine described above, the mold spore liquid (liquid containing the mold spore described above) was applied to the coating portion Ra and the uncoated portion Rb of the rotating tub T. And after leaving for 24 hours, the part which apply | coated the mold spore liquid was wiped off. Thereafter, the above-described washing operation was performed, and after the washing operation was completed, the above-mentioned portion was wiped off in the same manner. Further, after being left for 3 days, the above-mentioned part was wiped off in the same manner. Further, after leaving for 7 days, the above-mentioned part was wiped off in the same manner. The mold wiped off at each timing described above was cultured and counted by a well-known culture method. And based on the count result, the mold removal effect and the growth inhibitory effect by the presence or absence of the hydrophilic coating were evaluated. Details of this test are shown below.

(1) Contamination adherence to the rotating tub The clothes on which the pseudo soil was adhered were put into the rotating tub, and the above washing operation was performed for 25 cycles. Thereby, dirt was made to adhere to a rotation tank.

(2) Application of fungal spore solution About 10 ⁷ CFU / ml (CFU: colony forming unit) of fungal spore solution is divided into 20 arbitrary places and dropped 10 μl at a time (10 μL × 20 places) and dried for about 3 hours. On the other hand, 20 μl of about 10 ⁸ CFU / ml of fungal spore solution was dropped onto the test target site of the uncoated portion Rb, and spread with a large stick.

  The coated portion Ra has a very high hydrophilic performance by coating, whereas the uncoated portion Rb does not have a hydrophilic performance. For this reason, the surface properties of the two are different, and it is difficult to apply the fungal spore solution to the two in the same manner. Therefore, in this test, the fungal spore solution was applied to the test target site of the coated portion Ra and the test target site of the uncoated portion Rb by different application methods. Although the application method is different, the amount of the fungal spore solution applied to both is the same.

(3) Test operation As described above, the fungal spore solution was applied to the test site and dried, and then the door of the washing machine was closed and left for 24 hours. During this standing period, the temperature inside the washing machine was about 21.5 to 25.8 ° C., and the relative humidity (RH: Relative Humidity) was about 65 to 87%. After leaving for 24 hours and before performing the above-described washing operation, arbitrary three locations (indicated by n1, n2, and n3 in FIG. 9) of the test target portions of the coated portion Ra and the test of the uncoated portion Rb Arbitrary three places (indicated by n1, n2 and n3 in FIG. 9) of the target part were wiped off with a sterilized pus (gauze for wiping off bacteria). Thereafter, the above-described washing operation was performed, and the cloth was wiped in the same manner, and the door was closed and left again. During this standing period, the temperature inside the washing machine was about 22.8 to 26.6 ° C., and the relative humidity (RH: Relative Humidity) was approximately 90% or more. Furthermore, it wiped off similarly 3 days after leaving to stand. Furthermore, it wiped off similarly 7 days later. The sterilized pouches wiped off at each timing described above were placed in a sterilization bag together with the medium. Then, mold was washed out by a well-known stomacher process (a process for extracting fungi after crushing and homogenizing the sample).

(4) Measurement of the number of molds The solution washed out from the sterilized pose was used as a sample solution, and the sample solution was adjusted to a 10-level concentration diluted solution with physiological saline. Then, 0.1 ml each of the sample solution and the diluted solution was applied to the PDA medium. Moreover, 1 ml of sample liquid was filtered with the membrane filter, and the surface blank filter was affixed on the surface of another PDA culture medium. These media were cultured at about 28 ° C. (28 ° C. ± 1 ° C.) for 7 days. Thereafter, the number of grown colonies was counted to determine the number of molds per 25 cm ² .

(5) Calculation of mold removal rate The mold removal rate (%) was calculated by the following formula.
Removal rate = (1− (B / A)) × 100
A: Number of molds before washing
B: Number of molds after washing operation

Test results The test results are shown in FIG. That is, the removal rate of the number of molds on the 0th day after the end of the washing operation is approximately 99.92% in the coated portion Ra, and is approximately 94.3% in the uncoated portion Rb. In addition, from the 3rd day to the 7th day after the end of the washing operation, the mold did not multiply in any of the coated portion Ra and the uncoated portion Rb. This is presumably because the nutrient applied with the mold was washed away by the washing operation.

  According to the above test results, it is observed that mold is removed at a very high probability (probability close to 100%) in the coated portion Ra. Therefore, the coated portion Ra has a much higher protection than the uncoated portion Rb. It was confirmed that the dirt performance was demonstrated.

  According to the washing machines 100 and 200 according to the present embodiment, the hydrophilic performance film 300 having extremely high hydrophilic performance is provided on the outer surface of the side of the rotating tubs 116 and 204 that are rotatably provided in the water tanks 108 and 202. ing. According to this configuration, the outer surfaces of the side portions of the rotating tanks 116 and 204 that cannot be easily reached and cannot be easily maintained such as cleaning can be kept clean by the antifouling function of the hydrophilic performance film 300, and the washing machine In 100 and 200, the antifouling function due to hydrophilicity can be most effectively utilized.

  Moreover, according to the washing machines 100 and 200, since the hydrophilic performance film 300 is provided on the outer surface of the rotating rotating tanks 116 and 204, the surface of the rotating tanks 116 and 204 is rotated when the rotating tanks 116 and 204 rotate. The dirt peeled off is easily removed by the action of the centrifugal force, and the surfaces of the rotating tanks 116 and 204 can be kept clean.

  Moreover, according to the washing machines 100 and 200, the hydrophilic performance film 300 is provided on the entire outer surface of the side portion of the rotating tubs 116 and 204. Therefore, the entire outer surfaces of the side portions of the rotary tanks 116 and 204 can be kept clean by the antifouling function of the hydrophilic performance film 300. Moreover, according to the washing machines 100 and 200, since the rotating tubs 116 and 204 are made of metal instead of synthetic resin, a hydrophilic material can be coated on the outer surface of the metal portion of the rotating tubs 116 and 204 by baking. . Thereby, it is possible to form a strong and durable hydrophilic performance film 300 that is highly mineralized.

  Moreover, according to the washing machines 100 and 200, the hydrophilic performance film 300 has a water contact angle less than the lower limit value of the water contact angle with respect to glass, and has a silanol group. Therefore, the hydrophilic performance film 300 exhibits extremely high hydrophilic performance. Accordingly, water easily enters between the surface of the hydrophilic performance film 300 and the dirt attached to the hydrophilic performance film 300, and the dirt attached to the hydrophilic performance film 300 can be removed so as to be lifted.

  Moreover, according to the washing machines 100 and 200, the hydrophilic performance film 300 has a silicon oxide and has a hardness characteristic such that the pencil hardness is 5H or more. Therefore, it is possible to prevent the hydrophilic performance film 300 from being damaged or the hydrophilic performance film 300 from being peeled off. Moreover, according to the washing machines 100 and 200, the hydrophilic performance film 300 has a thickness of 10 μm or less, and an extremely thin hydrophilic performance film 300 is realized. In addition, according to the washing machines 100 and 200, the hydrophilic performance film 300 has a surface roughness of 2 μm or less, and an extremely smooth hydrophilic performance film 300 is realized.

  The washing machine 100 may further include a metal screw attached to the drum 116 or a hydrophilic performance film 300 on the inner surface of the drum 116. The washing machine 200 may further include a hydrophilic screw 300a attached to the rotating tub 204 or a hydrophilic performance film 300 on the inner surface of the rotating tub 204. That is, in this embodiment, the portion where the hydrophilic performance film 300 is formed is not limited to the outer surface of the side portion of the drum 116 or the outer surface of the side portion of the rotating tub 204. In the case where the hydrophilic performance film 300 is formed on a metal screw, it is not necessary to form the hydrophilic performance film 300 on the entire screw, and it is sufficient to form the hydrophilic performance film 300 on the surface of the screw head that is the outer surface. It is. Further, when the hydrophilic performance film 300 is formed on the inner surface of the drum 116 or the rotating tub 204, the hydrophilic performance film 300 may be formed on the entire inner surface, or the hydrophilic performance portion 300 may be formed on a part of the inner surface. Also good.

  Further, the hydrophilic performance film 300 may be colored. That is, as the hydrophilic material for forming the hydrophilic performance film 300, a material that retains color after spraying onto the substrate and after baking may be applied. Thereby, it can be easily confirmed visually whether or not the formed hydrophilic performance film 300 is uneven. For example, a rotating tank in which the hydrophilic performance film 300 is not uniformly formed is regarded as a defective product. Can be identified.

Further, in the washing machines 100 and 200, after the washing course including the washing process, the rinsing process, the dehydration process, and the like is completed or during the execution of the washing course, the water is stored in the water tanks 108 and 202, and the drum 116 and the rotating tank 204 are stored. You may set so that the washing process which rotates may be performed. When the hydrophilic performance film 300 comes into contact with water in this cleaning process, dirt attached to the hydrophilic performance film 300 can be removed. In this washing process, the amount of water stored in the water tanks 108 and 202 is increased from the washing course, and the rotation speed of the drum 116 and the rotation tank 204 is set at a speed higher than the rotation speed in the washing process or the rinsing process. Good.
Moreover, according to the washing machines 100 and 200, the antirust effect by the hydrophilic performance film 300 can also be expected.

(Second Embodiment)
In the present embodiment, the hydrophilic performance film 300 is not provided on the entire outer surface of the side of the drum 116 or the entire outer surface of the side of the rotating tub 204, but a part of the outer surface of the side of the drum 116 or the side of the rotating tub 204. A hydrophilic performance film 300 is provided on a part of the outer surface.

  That is, as shown in FIG. 10 or FIG. 11, in the side portion of the drum 116 of the washing machine 100 or the side portion of the rotating tub 204 of the washing machine 200, the washing operation is performed at a portion lower than the set water level L indicated by the one-dot chain line. The water stored in the water tank 108 or the water tank 202 comes into contact with the water or during the rinsing operation. Therefore, a portion lower than the set water level L in the outer surface of the drum 116 side or the outer surface of the rotating tub 204 can be kept relatively clean without providing the hydrophilic performance film 300. However, the portion of the outer surface of the drum 116 side or the outer surface of the rotating tub 204 that is higher than the set water level L is in contact with the water stored in the water tank 108 or the water tank 202 during the washing operation or the rinsing operation. Therefore, dirt is likely to remain.

  Therefore, in this embodiment, as shown in FIG. 10 or FIG. 11, the hydrophilic performance film 300 is provided in a portion higher than the set water level L on the outer surface of the drum 116 side or the outer surface of the rotating tub 204 side. . Thus, hydrophilic performance can be imparted by concentrating on the portion of the outer surface of the drum 116 or the outer surface of the side of the rotating tub 204 where dirt is likely to remain, and the antifouling function based on the hydrophilic performance is effectively utilized. be able to. In addition, the amount of hydrophilic material used can be reduced. Since the set water level L can be changed, it is preferable to appropriately adjust the region in which the hydrophilic performance film 300 is formed according to the assumed water level. At this time, the region in which the hydrophilic performance film 300 is formed may be set wider, for example, including the lowest water level that can be set in the washing machines 100, 200, or to the extent that the water level may vary.

(Third embodiment)
Also in this embodiment, the hydrophilic performance film 300 is not provided on the entire outer surface of the side portion of the drum 116 or the entire outer surface of the side portion of the rotating tub 204, but a part of the outer surface of the side portion of the drum 116 or the side portion of the rotating tub 204. A hydrophilic performance film 300 is provided on a part of the outer surface.

  That is, as described above, the portion lower than the set water level L on the outer surface of the drum 116 side or the outer surface of the rotating tub 204 is a portion that is easily contacted with water and kept relatively clean, but is completely It does not mean that there is no stain on the surface. In particular, the portion of the outer surface of the drum 116 side or the outer surface of the rotating tub 204 that is lower than the set water level L is a portion that comes into contact with water during the washing operation or the rinsing operation. Therefore, if dirt remains in this portion, the dirt may be deteriorated due to a change with time or the like, and the deteriorated dirt may be transferred to the laundry during the washing operation or the rinsing operation.

  Therefore, in the present embodiment, as shown in FIG. 12 or FIG. 13, the hydrophilic performance film 300 is provided on a portion lower than the set water level L on the outer surface of the drum 116 side or the outer surface of the rotating tank 204 side. . Thus, hydrophilic performance can be imparted by concentrating on the outer surface of the drum 116 or the outer surface of the rotating tub 204, which can be kept relatively clean, but where dirt may remain. It is possible to prevent the deteriorated dirt from being transferred to the laundry during operation or rinsing operation. In addition, the amount of hydrophilic material used can be reduced. Since the set water level L can be changed, it is preferable to appropriately adjust the region in which the hydrophilic performance film 300 is formed according to the assumed water level. At this time, the region in which the hydrophilic performance film 300 is formed may be set wider, for example, including the lowest water level that can be set in the washing machines 100, 200, or to the extent that the water level may vary.

(Other embodiments)
The present embodiment can be expanded or modified as follows, for example.
For example, as shown in FIG. 14, the washing machine 100 may further include a hydrophilic performance film 300 on the outer surface of the bottom portion that constitutes the back surface portion of the drum 116. In this case, the hydrophilic performance film 300 may be provided on the entire outer surface of the back surface portion of the drum 116, or the hydrophilic performance film 300 may be provided on a part of the outer surface of the drum 116 back surface portion. Although not shown, when the second member 204b constituting the bottom portion is made of a metal made of, for example, stainless steel, the washing machine 200 is also formed on the outer surface of the bottom portion formed by the metal second member. It is good also as a structure provided with the hydrophilic performance film | membrane 300. FIG. In this case, the hydrophilic performance film 300 may be provided on the entire outer surface of the metal bottom, or the hydrophilic performance film 300 may be provided on a part of the outer surface of the metal bottom.

  Further, for example, as shown in FIG. 15, the washing machine 100 may further include a hydrophilic performance film 300 on the reinforcing member 117 that reinforces the bottom of the drum 116. In this case, the hydrophilic performance film 300 may be provided on the entire surface of the reinforcing member 117, or the hydrophilic performance film 300 may be provided on a part of the surface of the reinforcing member 117. For example, as shown in FIG. 16, the washing machine 200 may further include a hydrophilic performance film 300 on the reinforcing member 204 c that reinforces the bottom of the rotating tub 204. In this case, the hydrophilic performance film 300 may be provided on the entire surface of the reinforcing member 204c, or the hydrophilic performance film 300 may be provided on a part of the surface of the reinforcing member 204c. Further, the hydrophilic performance film 300 may be provided on both the upper surface and the lower surface of the reinforcing member 204c, or the hydrophilic performance film 300 may be provided on either the upper surface or the lower surface of the reinforcing member 204c.

  Further, for example, as shown in FIG. 17A, the washing machines 100 and 200 may have a configuration in which the hydrophilic performance film 300 is not provided on the end surfaces 118a and 205a constituting the inner peripheral surfaces of the holes 118 and 205. As shown in FIG. 17B, the washing machines 100 and 200 may be configured to include the hydrophilic performance film 300 on the end surfaces 118 a and 205 a of the holes 118 and 205.

The test results shown in the first embodiment are presumed to be obtained in the same manner when the same test is performed in the washing machine according to another embodiment.
Moreover, you may implement combining each above-mentioned embodiment and modified embodiment suitably.

  In the washing machine according to each embodiment described above, a hydrophilic coating is applied to a rotating tub provided rotatably in the water tub. According to this configuration, in the washing machine, it is possible to keep the rotating tub having a portion that is not reachable and cannot be easily maintained such as cleaning, and the hydrophilic antifouling function is most effectively utilized. be able to.

  Moreover, according to the washing machine which concerns on each embodiment, the effect which suppresses propagation of mold | fungi and adhesion of dirt by the hydrophilic coating being given to the rotating tub, as is clear from each test result described above. Excellent effects such as the effect of suppressing the adhesion and the effect of suppressing the adhesion of detergents can be obtained.

  In addition, in a normal stainless steel rotating tank that is not coated with a hydrophilic material, even if the tank cleaning operation is performed about once a month by using, for example, a chlorine-based tank cleaning agent, dirt gradually accumulates. End up. According to the washing machine which concerns on this embodiment, it was confirmed by the above-mentioned test result that even if a washing operation is repeated, dirt hardly accumulates because the hydrophilic material is coated on the rotating tub. Therefore, the frequency of tank cleaning operations can be reduced, or the tank cleaning operation can be made unnecessary, and the operating costs associated with the tank cleaning operation (amount of tank cleaning agent, water, electricity, etc., charges, etc.) Can be reduced.

  The above-described embodiments are presented as examples, and are not intended to limit the scope of the invention. These novel embodiments can be implemented in various other forms, and various omissions, replacements, and changes can be made without departing from the scope of the invention. This embodiment and its modifications are included in the scope and gist of the invention, and are included in the invention described in the claims and the equivalents thereof.

  In the drawings, 100 and 200 are washing machines, 108 and 202 are water tanks, 116 are drums (rotating tanks), 117 and 204c are reinforcing members, 204 are rotating tanks, 118 and 205 are holes, 206a are screws, and 300 is hydrophilic performance. The membrane (hydrophilic performance part) is shown.

Claims (5)

A hydrophilic coating is applied to the entire outer surface of the rotating tank provided rotatably in the water tank,
The hydrophilic coating is
Formed of silica-based paint containing silicon oxide,
Have a siloxane skeleton,
A washing machine that suppresses the growth of mold by 99% or more even in a damp state with a relative humidity of 90% or more .   The washing machine according to claim 1, wherein the hydrophilic coating has a performance such that a contact angle of water is less than a lower limit value of a contact angle of water with respect to glass. The rotating tank is made of metal,
The washing machine according to claim 1 or 2, wherein the hydrophilic coating is applied by baking an inorganic material on the rotating tub. The washing machine according to any one of claims 1 to 3 , wherein the rotating tub is provided with a hydrophilic coating that suppresses adhesion of dirt. The washing machine according to any one of claims 1 to 4 , wherein the rotating tub is provided with a hydrophilic coating that suppresses adhesion of detergent.

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