JP2018161191A - Washing machine - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a washing machine capable of splashing circulation water sufficiently to laundry, irrespective of a condition in a tub.SOLUTION: A washing machine includes: a water tub; a rotary tub provided rotatably in the water tub; a plurality of circulation ducts provided on an inner peripheral surface of the rotary tub, and extending along an axial direction of the rotary tub; a pulsator provided rotatably at a bottom part of the rotary tub; a rear blade provided on a rear surface of the pulsator, and for raising water in the water tub through the circulation ducts according to the rotation of the pulsator; and discharge ports provided at the plurality of circulation ducts respectively, and for discharging the water rising in the circulation ducts by the rear blade to the inside of the rotary tub. Discharge quantity of water discharged from the discharge ports of the plurality of circulation ducts varies.SELECTED DRAWING: Figure 1

Description

  Embodiments described herein relate generally to a washing machine.

  For example, as disclosed in Patent Document 1, a washing machine that circulates water in a water tank through a circulation duct extending in the vertical direction on the inner peripheral surface of the rotating tank by rotating a pulsator having a back blade is conceivable. ing.

JP 2013-66592 A

  This type of washing machine is configured to circulate water by a pump function by rotating the back blade. Therefore, for example, if the rotational speed of the back blade, in other words, the pulsator is increased, the amount of circulating water can be increased. However, even if the amount of circulating water is increased, there may be a case where sufficient water cannot be applied to the laundry depending on the situation in the tank such as the water level in the water tank or the amount of laundry in the rotating tank.

  Then, the washing machine which can fully circulate water into the laundry irrespective of the condition in a tub is provided.

  The washing machine according to the present embodiment includes a water tank, a rotating tank, a circulation duct, a pulsator, a back blade, and a discharge port. The rotation tank is rotatably provided in the water tank. A plurality of circulation ducts are provided, are provided on the inner peripheral surface of the rotating tub, and extend along the axial direction of the rotating tub. The pulsator is rotatably provided at the bottom of the rotating tank. The back blade is provided on the back surface of the pulsator, and raises the water in the water tank through the circulation duct as the pulsator rotates. A discharge port is provided in each of the plurality of circulation ducts, and discharges the water rising in the circulation duct into the rotating tub by the back blades. And the discharge amount of the water discharged from the said discharge outlet of the said some circulation duct differs.

1 is a longitudinal side view schematically showing a configuration example of a washing machine according to a first embodiment. Bottom view schematically showing an example of pulsator configuration A perspective view schematically showing a configuration example of a pulsator Plan view schematically showing a configuration example of a pulsator Plan view of a rotating tank schematically showing the circulating water discharged from the circulation duct Block diagram schematically showing a configuration example of a control device Flow chart showing an example of the washing process The figure which shows an example of the control content by a control apparatus The figure (the 1) which shows roughly the example of composition of the plurality of circulation ducts concerning a modification The figure which shows schematically the structural example of the some circulation duct which concerns on a modification (the 2) Longitudinal side view schematically showing a configuration example of a washing machine according to a modification.

Hereinafter, a plurality of embodiments according to a washing machine will be described with reference to the drawings. In addition, in each embodiment, the substantially same element is attached | subjected with the same code | symbol and the description is abbreviate | omitted.
(First embodiment)
A washing machine 10 illustrated in FIG. 1 is a so-called vertical axis type washing machine in which a rotation center axis of a rotating tub extends in a vertical direction. The washing machine 10 includes a bottomed cylindrical water tank 12 having an open upper surface inside an outer box 11 constituting the outer shell. The water tank 12 is elastically supported by a known elastic suspension mechanism 13. A water supply mechanism (not shown) is provided inside the outer box 11. The water supplied from the water supply mechanism is stored inside the water tank 12. Inside the water tank 12, a bottomed cylindrical rotating tank 14 having an open upper surface is rotatably provided.

  The rotating tub 14 is a tub for storing laundry such as clothes. The rotating tub 14 is configured to rotate about a vertical axis, and serves as a washing tub for washing laundry, a washing tub for rinsing the laundry, and a dehydration tub for a dehydration stroke for dehydrating the laundry. It is also used. A pulsator 15 is provided at the bottom inside the rotary tank 14 so as to be rotatable around the vertical axis. A plurality of back blades 16 are provided on the back surface of the pulsator 15, that is, on the surface facing the bottom of the rotary tank 14.

  As illustrated in FIG. 2, on the back surface of the pulsator 15, the back blades 16 extend radially from the central part of the pulsator 15 toward the peripheral end. Further, the back blade 16 extends linearly from the central portion of the pulsator 15 toward the peripheral end portion. In addition, the back blade | wing 16 may be the shape bent in the parabola shape so that a curve may be borne from the center part of the pulsator 15 toward a peripheral end part.

  As illustrated in FIG. 1, a back blade space portion 17 is formed between the upper surface of the bottom portion of the rotating tub 14 and the back surface of the pulsator 15. The back blade 16 is accommodated in the back blade space 17. As will be described in detail later, the back blade 16 rotates in accordance with the rotation of the pulsator 15 in the back blade space portion 17, thereby realizing a pump function in which water in the back blade space portion 17 is pushed out. That is, the back blade space 17 functions as a so-called pump chamber.

  A driving mechanism 18 is provided at the center of the lower part of the water tank 12. The drive mechanism 18 includes a motor capable of variable speed drive, a clutch mechanism, a brake device, and the like. During the washing process or the rinsing process, the drive mechanism unit 18 transmits the rotational force of the motor to the pulsator 15 by the clutch mechanism. During the dehydration process, the drive mechanism unit 18 transmits the rotational force of the motor to the rotary tank 14 and the pulsator 15 at a high speed by the clutch mechanism.

  A plurality of, in this case, two circulation ducts 19 </ b> A and 19 </ b> B are provided on the inner peripheral surface of the rotating tub 14 extending in the axial direction of the rotating tub 14, that is, in the vertical direction. The lower ends of the circulation ducts 19 </ b> A and 19 </ b> B are communicated with the back blade space portion 17. When the pulsator 15 rotates, the back blade 16 rotates in the back blade space 17 together with the pulsator 15. Then, by the back blade 16 rotating in the back blade space portion 17, the water in the back blade space portion 17 is pushed out to the outer peripheral side of the back blade space portion 17, that is, the circulation ducts 19A and 19B. Thereby, the water in the back blade space part 17 comes to rise through the circulation ducts 19A and 19B. In other words, the washing machine 10 has a pump function that raises the water in the water tank 12 through the circulation ducts 19 </ b> A and 19 </ b> B by rotating the back blade 16 in the back blade space 17.

  The circulation duct 19A is provided with a plurality of, in this case, two discharge portions 19A1 and 19A2 extending in a slit shape along the horizontal direction. The water rising in the circulation duct 19A by the pump function by rotating the back blade 16 is discharged into the rotary tank 14 through the plurality of discharge portions 19A1, 19A2. That is, the washing machine 10 has a circulation function of raising the water in the water tub 12 through the circulation duct 19A and discharging the water from the plurality of discharge portions 19A1 and 19A2 into the rotary tub 14.

  In addition, the circulation duct 19B is provided with one discharge portion 19B1 extending in a slit shape along the horizontal direction. The water rising in the circulation duct 19B by the pump function by rotating the back blade 16 is discharged into the rotary tank 14 through one discharge part 19B1. That is, the washing machine 10 has a circulation function in which the water in the water tub 12 is raised through the circulation duct 19B and discharged from the one discharge portion 19B1 into the rotary tub 14.

  As illustrated in FIGS. 3 and 4, the pulsator 15 is entirely made of, for example, a synthetic resin, and has a base portion 21 having a circular shape when viewed from above, that is, from above, and the base portion 21. The surface, in this case, the central protrusion 22 protruding upward at the center of the upper surface, the mountain-shaped main front blade part 23 extending radially around the central protrusion 22 on the surface of the base 21, and the base 21 On the surface, a mountain-shaped auxiliary front blade portion 24 extending radially around the central protrusion 22 and the above-described back blade 16 are integrally provided. A boss portion 25 is provided at the center of the back side of the central protrusion 22. The boss portion 25 is fitted from above to a pulsator drive shaft 18a included in the drive mechanism portion 18. Further, the pulsator 15 has a flat annular surface portion whose horizontal end portion is horizontal at the inner bottom portion of the rotating tub 14, and a dent portion that smoothly dents downwardly on the inner side of the peripheral end portion. It has.

  The drive mechanism unit 18 is configured to be able to rotate the pulsator 15 in the normal rotation direction R1 and the reverse direction R2 illustrated in FIG. Here, the normal rotation direction R1 illustrated in FIG. 4 is a state in which the main front blade portion 23 entrains the laundry in the rotating tub 14 as the pulsator 15 rotates in the normal rotation direction R1. Is an example. In addition, the reversal direction R2 illustrated in FIG. 4 is an example of an “extrusion direction” in which the main front blade portion 23 pushes out the laundry in the rotating tub 14 as the pulsator 15 rotates in the reversal direction R2. It is.

  A plurality of main front blade portions 23 are provided, in this case, three. The main front blade portions 23 are arranged at equal intervals around the central protrusion 22. The main front blade portion 23 extends radially from the central protrusion 22 on the upper surface of the base portion 21, and has a shape in which a tip portion thereof is inclined to one side with respect to the radial direction of the base portion 21.

  And the side surface by the side where the front-end | tip part inclines among the both sides | surfaces of the main front blade | wing part 23 comprises the winding surface 23a in which the laundry in the rotating tub 14 is wound, when the pulsator 15 rotates to the normal rotation direction R1. ing. On the other hand, the side surface on the opposite side to the direction in which the tip portion is inclined among the both side surfaces of the main front blade portion 23 has an extrusion surface 23b for pushing out the laundry in the rotating tub 14 when the pulsator 15 rotates in the reverse direction R2. It is composed. The main front blade portion 23 has different shapes on the winding direction R1 side and the extrusion direction R2 side. Moreover, the front-end | tip part of the main front blade part 23 becomes a shape which winds in the winding direction R1 side. Further, the upper surface of the main front blade portion 23 has a shape that gradually inclines downward from the proximal end side, which is the central protrusion 22 side, toward the distal end portion side.

  Moreover, the auxiliary front blade part 24 is provided with two or more in this case. The auxiliary front blade portions 24 are arranged at equal intervals around the central protrusion 22. In addition, the auxiliary front blade portion 24 is provided at a central portion between the adjacent main front blade portions 23. On the upper surface of the pulsator 15, the main front blade portion 23 and the auxiliary front blade portion 24 are alternately arranged. Further, the height of the auxiliary front blade portion 24, that is, the amount of protrusion from the upper surface of the base portion 21 is lower than the height of the main front blade portion 23, that is, the amount of protrusion from the upper surface of the base portion 21. . That is, the pulsator 15 is configured such that an auxiliary front blade portion 24 that is lower than the main front blade portions 23 is auxiliary between the adjacent main front blade portions 23.

  The auxiliary front blade portion 24 extends radially from the central protrusion 22 on the upper surface of the base portion 21, and has a shape in which a tip portion thereof is inclined to one side with respect to the radial direction of the base portion 21. And the side surface by the side where the front-end | tip part inclines among the both sides | surfaces of the auxiliary front blade | wing part 24 is the winding surface 24a which winds up the laundry in the rotating tank 14 auxiliary | assistant when the pulsator 15 rotates to the normal rotation direction R1. Is configured. On the other hand, the side surface on the opposite side to the direction in which the tip end portion is inclined among both side surfaces of the auxiliary front blade portion 24 is extruded to assistly push out the laundry in the rotating tub 14 when the pulsator 15 rotates in the reverse direction R2. A surface 24b is formed. The auxiliary front blade portion 24 has different shapes on the winding direction R1 side and the extrusion direction R2 side. Moreover, the front-end | tip part of the auxiliary front blade part 24 becomes a shape which winds in the winding direction R1 side. Further, the upper surface of the auxiliary front blade portion 24 has a flat shape that is substantially horizontal.

  The pulsator 15 is provided with a plurality of through holes 51 that penetrate the front surface side and the back surface side of the pulsator 15. In this case, each of the plurality of through holes 51 is a hole that opens in a circular shape. In addition, the opening areas of the plurality of through holes 51 have a size that completely or substantially coincides with each other. In addition, the density of the plurality of through holes 51 in the pulsator 15 is denser as it approaches the central part, while it is sparser toward the peripheral end.

  As described above, when the pulsator 15 is rotated, the back blade 16 is rotated together with the pulsator 15 in the back blade space portion 17, whereby water in the back blade space portion 17 is moved to the outer peripheral side of the back blade space portion 17. Be pushed out. At this time, the water in the water tank 12 is sucked into the back blade space portion 17 from the through hole 51 of the pulsator 15 and the water sucked into the back blade space portion 17 with the pump action by the back blade 16. Is discharged from the outer peripheral end of the pulsator 15 and the through-hole 51 existing in the discharge part 42 of the pulsator 15.

  The washing machine 10 according to the present embodiment has a total discharge amount of circulating water discharged from the discharge ports 19A1 and 19A2 of the circulation duct 19A and a total discharge amount of circulating water discharged from the discharge port 19B1 of the circulation duct 19B. It has a different structure. That is, the washing machine 10 has a configuration in which the total amount of circulating water discharged from the circulation duct 19A is different from the total amount of circulating water discharged from the circulation duct 19B at a certain point in time.

  That is, as described above, the washing machine 10 has two discharge ports provided in the circulation duct 19A and one discharge port provided in the circulation duct 19B, that is, two circulation ducts 19A, The number of discharge ports provided in 19B is varied. As a result, as illustrated in FIG. 5, the discharge amount of the circulating water Wa from the circulation duct 19A with many discharge ports can be made larger than the discharge amount of the circulation water Wb from the circulation duct 19B with few discharge ports. That is, the discharge amounts of the circulating water Wa and Wb discharged from the discharge ports of the two circulation ducts 19A and 19B at a certain time can be made different from each other.

  Further, as illustrated in FIG. 5, the washing machine 10 makes the lateral width of the discharge ports 19A1 and 19A2 of the circulation duct 19A different from the lateral width of the discharge port 19B1 of the circulation duct 19B. ing. In this case, the washing machine 10 has the lateral width of the discharge ports 19A1 and 19A2 of the circulation duct 19A larger than the lateral width of the discharge port 19B1 of the circulation duct 19B. Thereby, the discharge width of the circulating water Wa discharged from the discharge ports 19A1 and 19A2 of the circulation duct 19A can be made wider than the discharge width of the circulating water Wb discharged from the discharge port 19B1 of the circulation duct 19B. The discharge width of the circulating water discharged from the discharge ports of the two circulation ducts 19A and 19B can be made different from each other.

  According to the washing machine 10 according to the present embodiment, in the configuration including the plurality of circulation ducts 19A and 19B, the number of discharge ports provided in the circulation duct 19A is different from the number of discharge ports provided in the circulation duct 19B. Thus, the discharge amount of water discharged from the discharge ports of the plurality of circulation ducts 19A and 19B is made different. According to this configuration, regardless of the water level in the water tank 12 or the amount of laundry in the rotating tank 14, the circulating water can be discharged from different directions over a wide range in the rotating tank 14 from different directions. The circulating water can be sufficiently applied to the laundry in the rotating tub 14.

  Moreover, according to the washing machine 10, not only the amount of circulating water discharged from the discharge ports of the plurality of circulation ducts 19A and 19B, but also the discharge width is varied. According to this configuration, the circulating water can be discharged with different amounts of water from different directions over a wider range in the rotating tub 14, and more effectively circulates in the laundry in the rotating tub 14 regardless of the situation in the tub. Can be watered.

(Second Embodiment)
In 1st Embodiment mentioned above, the structure which can fully circulate through a laundry regardless of the condition in the water tank 12 by giving an ingenuity to the structure of circulation duct 19A, 19B, especially the structure of a discharge outlet. An example was disclosed. On the other hand, in 2nd Embodiment, the form which can fully circulate water on a laundry irrespective of the condition in the water tank 12 is disclosed by giving an ingenuity to the control content in a washing process.

  That is, the control device 100 illustrated in FIG. 6 is configured mainly with a microcomputer, and controls the overall operation of the washing machine 10 by executing a control program. The control device 100 virtually realizes the washing process execution processing unit 101 and the weight detection processing unit 102 by software by executing a control program. The washing process execution processing unit 101 and the weight detection processing unit 102 may be realized by hardware, or may be realized by a combination of software and hardware.

  The washing process execution processing unit 101 is an example of a washing process execution unit. As illustrated in FIG. 7, in the washing process of washing the laundry in the rotary tub 14, first, the preliminary washing process (S 1) is performed, The main washing process (S2) is performed. In the preliminary washing process, the washing process execution processing unit 101 supplies water to the water level lower than the predetermined water level in the water tank 12 and rotates the pulsator 15. Thereby, the laundry in the rotating tub 14 is gently stirred, and the laundry is preliminarily washed.

  On the other hand, in the main washing process, the washing process execution processing unit 101 supplies water to the predetermined water level in the water tank 12 and rotates the pulsator 15. Thereby, the laundry in the rotating tub 14 is vigorously stirred, and the laundry is finally washed. Note that the predetermined water level here is, for example, a set water level that is automatically set based on the amount of laundry in the rotating tub 14 detected by a well-known weight sensing process, or an operation button (not shown) operated by the user. Set water level specified, etc.

  The washing process execution processing unit 101 is configured to be able to execute a normal water washing process and a strong water washing process. The normal water washing process is performed by rotating the pulsator 15 at a predetermined normal rotation speed in the main washing process, or rotating the on-time for rotating the pulsator 15 with the normal on-time. This is the process of washing the laundry by generating a normal water flow.

  On the other hand, the strong water washing process is performed by rotating the pulsator 15 at a high rotational speed that is higher than a predetermined normal rotational speed, or by making the on-time for rotating the pulsator 15 longer than the normal on-time. This is a process of washing the laundry by generating a strong water flow stronger than the normal water flow in the water in the water tank 12.

  The weight detection processing unit 102 is an example of a weight detection unit, and detects the weight of the laundry stored in the rotating tub 14 by a known weight sensing process. The weight sensing process uses the fact that the rotational load of the washing machine motor 21 changes according to the weight of the laundry in the rotating tub 14. For example, the washing machine motor is in a state before supplying water into the water tub 14. The rotation can be performed by rotating the motor 21 for a predetermined short time and detecting the change in the rotation speed of the washing machine motor 21 at that time. Further, the weight detection processing unit 102 may be configured to detect the amount of laundry by including a weight sensor (not shown) that detects the weight of the water tank 12.

  As illustrated in FIG. 8, the washing process execution processing unit 101 is configured to vary the rotational speed of the pulsator 15 and the on-time for rotating the pulsator 15 in the preliminary washing process and the main washing process. In addition, the washing process execution processing unit 101 determines the degree to which the rotational speed of the pulsator 15 is different between the preliminary washing process and the main washing process, and the degree to which the on-time of the pulsator 15 is different between the preliminary washing process and the main washing process. It is configured to be different from each other.

  That is, for example, when the amount of laundry is light, for example, 1 Kg, and the pulsator 15 is rotated in the normal rotation direction R1, the washing process execution processing unit 101 sets the pulsator 15 to 1.0 seconds in the preliminary washing process. The control to turn on and turn off for 1.0 second is repeated, and the rotation speed of the pulsator 15 is set to 100 rpm. The washing process execution processing unit 101 repeats the control to turn on the pulsator 15 for 0.8 seconds and turn it off for 1.0 seconds when performing the normal water washing process as the main washing process, and the rotation of the pulsator 15 The speed is 90 rpm. The washing process execution processing unit 101 repeats the control to turn on the pulsator 15 for 1.2 seconds and turn it off for 1.0 second when executing the strong water washing process as the main washing process, and the rotation of the pulsator 15 The speed is 110 rpm.

  Here, the degree to which the rotational speed of the pulsator 15 differs between the pre-washing process and the normal water-washing process is 100 rpm, whereas the rotational speed in the normal water-washing process is 90 rpm. From this, 90/100 = 0.9 is calculated. On the other hand, the degree of ON time of the pulsator 15 being different in the pre-washing process and the normal water washing process is 1.0 second in the pre-washing process, whereas the ON time in the normal water washing process is 0. .8 seconds, 0.8 / 1.0 = 0.8 is calculated. That is, the control device 100 sets the degree “0.9” for varying the rotational speed of the pulsator 15 to be greater than the degree “0.8” for varying the ON time of the pulsator 15.

  Further, the degree of rotation speed of the pulsator 15 in the pre-washing process and the strong water washing process is different from the rotational speed in the pre-washing process is 100 rpm, whereas the rotational speed in the strong water washing process is 110 rpm. 110/100 = 1.1. On the other hand, the degree of on-time of the pulsator 15 in the pre-washing process and the strong water washing process is different from the on-time in the pre-washing process of 1.0 second, while the on-time in the strong water washing process is 1 second. Since it is 2 seconds, 1.2 / 1.0 = 1.2 is calculated. That is, the control device 100 makes the degree “1.1” for varying the rotational speed of the pulsator 15 smaller than the degree “1.2” for varying the on-time of the pulsator 15.

  Further, the washing process execution processing unit 101 turns on the pulsator 15 for 1.2 seconds in the preliminary washing process, for example, when the amount of laundry is light, for example, 1 kg, and the pulsator 15 is rotated in the reverse direction R2. Then, the control to turn off for 1.0 second is repeated, and the rotation speed of the pulsator 15 is set to 120 rpm. The washing process execution processing unit 101 repeats the control to turn on the pulsator 15 for 1.0 second and turn it off for 1.0 second when the normal water washing process is executed as the main washing process. The speed is 90 rpm. The washing process execution processing unit 101 repeats the control to turn on the pulsator 15 for 1.4 seconds and turn it off for 1.0 seconds when the strong water washing process is executed as the main washing process, and the rotation of the pulsator 15 The speed is 130 rpm.

  Here, the degree to which the rotational speed of the pulsator 15 is different between the pre-washing process and the normal water-washing process is 120 rpm while the rotational speed in the normal water-washing process is 90 rpm. From this, 90/120 = 0.75 is calculated. On the other hand, the degree to which the pulsator 15 is turned on differently in the pre-washing process and the normal water-washing process is 1.2 seconds in the pre-washing process, whereas the on-time in the normal water-washing process is 1 Since 1.0 second, 1.0 / 1.2 = approximately 0.83 is calculated. That is, the control device 100 makes the degree “0.75” for varying the rotational speed of the pulsator 15 smaller than the degree “about 0.83” for varying the ON time of the pulsator 15.

  Further, the degree of rotation of the pulsator 15 in the pre-washing process and the strong water washing process is different from the rotational speed in the pre-washing process is 120 rpm, whereas the rotation speed in the strong water washing process is 130 rpm. , 130/120 = approximately 1.08. On the other hand, the degree to which the pulsator 15 is turned on differently in the pre-washing process and the strong water washing process is 1.2 seconds in the pre-washing process, whereas the on-time in the strong water washing process is 1 second. Since it is 4 seconds, 1.4 / 1.2 = 1.17 is calculated. That is, the control device 100 makes the degree “1.08” for varying the rotational speed of the pulsator 15 smaller than the degree “about 1.17” for varying the ON time of the pulsator 15.

  Further, the washing process execution processing unit 101, for example, when the amount of laundry is heavy, for example, when it is 6 kg, when rotating the pulsator 15 in the normal rotation direction R1, the pulsator 15 is operated for 1.2 seconds in the preliminary washing process. The control to turn on and turn off for 0.8 seconds is repeated, and the rotation speed of the pulsator 15 is set to 130 rpm. The washing process execution processing unit 101 repeats the control to turn on the pulsator 15 for 1.0 second and turn it off for 1.0 second when the normal water washing process is executed as the main washing process. The speed is 110 rpm. The washing process execution processing unit 101 repeats the control to turn on the pulsator 15 for 1.3 seconds and turn it off for 0.8 seconds when executing the strong water washing process as the main washing process, and the rotation of the pulsator 15 The speed is 140 rpm.

  Here, the degree to which the rotational speed of the pulsator 15 is different between the prewashing process and the normal water washing process is 130 rpm in the prewashing process, whereas the rotational speed in the normal water washing process is 110 rpm. Therefore, 110/130 = approximately 0.85 is calculated. On the other hand, the degree to which the pulsator 15 is turned on differently in the pre-washing process and the normal water-washing process is 1.2 seconds in the pre-washing process, whereas the on-time in the normal water-washing process is 1 Since 1.0 second, 1.0 / 1.2 = approximately 0.83 is calculated. In other words, the control device 100 makes the degree “about 0.85” for varying the rotation speed of the pulsator 15 larger than the degree “about 0.83” for varying the ON time of the pulsator 15.

  In addition, the degree of rotation of the pulsator 15 in the pre-washing process and the strong water washing process is different from the rotational speed in the pre-washing process is 130 rpm, whereas the rotational speed in the strong water washing process is 140 rpm. 140/130 = approximately 1.08. On the other hand, the degree to which the pulsator 15 is turned on differently in the pre-washing process and the strong water washing process is 1.2 seconds in the pre-washing process, whereas the on-time in the strong water washing process is 1 second. Since it is 3 seconds, 1.3 / 1.2 = approximately 1.08 is calculated. That is, the control device 100 determines that the degree of rotation of the pulsator 15 is “approximately 1.08” and the degree of variation of the pulsator 15 on time “approximately 1.08” are substantially the same or completely the same. It is said.

  Further, the washing process execution processing unit 101 turns on the pulsator 15 for 1.4 seconds in the preliminary washing process, for example, when the amount of laundry is heavy, for example, 6 kg, and the pulsator 15 is rotated in the reverse direction R2. Then, the control to turn off for 0.8 seconds is repeated, and the rotational speed of the pulsator 15 is set to 140 rpm. The washing process execution processing unit 101 repeats the control to turn on the pulsator 15 for 1.2 seconds and turn it off for 1.0 second when performing the normal water washing process as the main washing process, and the rotation of the pulsator 15 The speed is 130 rpm. The washing process execution processing unit 101 repeats the control to turn on the pulsator 15 for 1.8 seconds and turn it off for 0.8 seconds when executing the strong water washing process as the main washing process, and the rotation of the pulsator 15 The speed is 150 rpm.

  Here, the degree to which the rotation speed of the pulsator 15 is different between the pre-washing process and the normal water washing process is 140 rpm, whereas the rotation speed in the normal water washing process is 130 rpm. Therefore, 130/140 = approximately 0.93 is calculated. On the other hand, the degree to which the on time of the pulsator 15 is different between the pre-washing process and the normal water washing process is 1.4 seconds, whereas the on-time in the normal water washing process is 1 second. Since it is 2 seconds, it is calculated as 1.2 / 1.4 = about 0.86. In other words, the control device 100 makes the degree “about 0.93” for varying the rotational speed of the pulsator 15 larger than the degree “about 0.86” for varying the on-time of the pulsator 15.

  Further, the degree of rotation of the pulsator 15 in the preliminary washing process and the strong water washing process is different from the rotational speed in the preliminary washing process is 140 rpm, whereas the rotational speed in the strong water washing process is 150 rpm. 150/140 = approximately 1.07. On the other hand, the degree to which the pulsator 15 is turned on differently in the pre-washing process and the strong water washing process is 1.4 seconds, whereas the on-time in the strong water washing process is 1 second. Since it is 8 seconds, it is calculated that 1.8 / 1.4 = 1. That is, the control device 100 makes the degree “about 1.07” for varying the rotation speed of the pulsator 15 smaller than the degree “about 1.29” for varying the ON time of the pulsator 15.

  In addition, the washing process execution processing unit 101 sets the rotation speed of the pulsator 15 and the on-time for rotating the pulsator 15 depending on whether the weight of the laundry detected by the weight detection processing unit 102 is heavier or lighter than a predetermined amount. It is configured to be different. In addition, the predetermined amount used as the reference | standard which determines the lightness of the amount of laundry can be changed and set suitably. The washing process execution processing unit 101 turns on the pulsator 15 depending on the degree of rotation speed of the pulsator 15 depending on whether the laundry is heavy or light, and whether the laundry is heavy or light. It is configured to vary the degree of time difference.

  The washing process execution processing unit 101 is configured to vary the rotation speed of the pulsator 15 and the on-time for rotating the pulsator 15 in the normal water washing process and the strong water washing process. The washing process execution processing unit 101 is configured to vary the degree of varying the rotational speed of the pulsator 15 and the degree of varying the on-time of the pulsator 15 in the normal water washing process and the strong water washing process.

  That is, the washing process execution processing unit 101 executes the preliminary washing process when the amount of laundry is light, and the rotation speed in the forward rotation direction R1 is 100 rpm, the rotation speed in the reverse rotation direction R2 is 120 rpm, and the rotation speed in the normal rotation direction R1. The on time is 1.0 second, and the on time in the reverse direction R2 is 1.2 seconds. On the other hand, the washing process execution processing unit 101, when executing the preliminary washing process when the amount of laundry is heavy, sets the rotation speed in the normal rotation direction R1 to 130 rpm, the rotation speed in the reverse direction R2 to 140 rpm, and the normal rotation direction R1. The on time is 1.2 seconds, and the on time in the reverse direction R2 is 1.4 seconds. That is, the washing process execution processing unit 101 varies the rotational speed of the pulsator 15 and the on-time for rotating the pulsator 15 depending on whether the amount of laundry is heavy or light.

  In addition, the degree of rotation speed in the normal rotation direction R1 is different between the case where the amount of laundry is heavy and the case where the amount of laundry is light, whereas the rotation speed in the normal rotation direction R1 when the amount of laundry is light is 100 rpm. Since the rotational speed in the forward rotation direction R1 in the heavy case is 130 rpm, 100/130 = about 0.77 is calculated. On the other hand, when the amount of laundry is heavy and light, the degree of on-time in the forward direction R1 is different from the on-time in the forward direction R1 when the amount of laundry is light, whereas Since the ON time in the forward rotation direction R1 when the amount of laundry is heavy is 1.2 seconds, 1.0 / 1.2 = approximately 0.83 is calculated. That is, the control device 100 uses the degree “about 0.77” for varying the rotational speed of the pulsator 15 in the forward rotation direction R1 and the degree “about 0.83” for varying the ON time of the pulsator 15 in the forward rotation direction R1. Is also small.

  In addition, when the amount of laundry is heavy and light, the degree of rotation speed in the reverse direction R2 is different when the amount of laundry is heavy while the rotational speed in the reverse direction R2 is 120 rpm when the amount of laundry is light. Since the rotation speed in the reverse direction R2 is 140 rpm, it is calculated that 120/140 = about 0.86. On the other hand, the degree of on-time in the reversing direction R2 is different between the case where the amount of laundry is heavy and the case where the amount of laundry is light, whereas the on-time in the reversing direction R2 when the amount of laundry is light is 1.2 seconds. Since the ON time in the reversing direction R2 is 1.4 seconds when 1.2 is heavy, 1.2 / 1.4 = approximately 0.86 is calculated. That is, the control device 100 sets the degree of “about 0.86” for changing the rotation speed in the reverse direction R2 of the pulsator 15 and the degree “about 0.86” for changing the ON time of the reverse direction R2 of the pulsator 15 to each other. It is almost the same or completely the same.

  Further, when the normal washing process is performed when the amount of laundry is light, the washing process execution processing unit 101 sets the rotation speed in the normal rotation direction R1 to 90 rpm, the rotation speed in the reverse direction R2 to 90 rpm, and the normal rotation direction R1. Is set to 0.8 seconds, and the ON time in the reverse direction R2 is set to 1.0 seconds. On the other hand, when the washing process execution processing unit 101 executes the normal water washing process when the amount of laundry is heavy, the rotation speed in the normal rotation direction R1 is 110 rpm, the rotation speed in the reversal direction R2 is 130 rpm, and the normal rotation direction R1. Is set to 1.0 second, and the ON time in the reverse direction R2 is set to 1.2 seconds. That is, the washing process execution processing unit 101 varies the rotational speed of the pulsator 15 and the on-time for rotating the pulsator 15 depending on whether the amount of laundry is heavy or light.

  In addition, the degree of rotation speed in the normal rotation direction R1 is different between the case where the amount of laundry is heavy and the case where the amount of laundry is light, whereas the rotation speed in the normal rotation direction R1 when the amount of laundry is light is 90 rpm. Since the rotation speed in the forward rotation direction R1 in the heavy case is 110 rpm, 90/110 = approximately 0.82. On the other hand, when the amount of laundry is heavy and light, the degree of on-time in the forward rotation direction R1 is different from the on-time in the forward rotation direction R1 when the amount of laundry is light is 0.8 seconds. Since the ON time in the forward rotation direction R1 when the amount of laundry is heavy is 1.0 second, 0.8 / 1.0 = 0.8 is calculated. In other words, the control device 100 sets the degree of rotation of the pulsator 15 in the normal rotation direction R1 to “0.82” and the degree of change in the ON time of the pulsator 15 in the normal rotation direction R1 to “0.8”. It is getting bigger.

  In addition, when the amount of laundry is heavy and light, the degree of rotation speed in the reverse direction R2 is different when the amount of laundry is heavy while the rotational speed in the reverse direction R2 is 90 rpm when the amount of laundry is light. Since the rotation speed in the reverse direction R2 is 130 rpm, 90/130 = approximately 0.69 is calculated. On the other hand, when the amount of laundry is heavy and light, the degree of on-time in the reverse direction R2 is different from the amount of laundry while the on-time in the reverse direction R2 is 1.0 seconds when the amount of laundry is light. Since the ON time in the reversing direction R2 is 1.2 seconds when I is heavy, 1.0 / 1.2 = approximately 0.83 is calculated. In other words, the control device 100 reduces the degree “about 0.69” of changing the rotation speed of the pulsator 15 in the reverse direction R2 to be less than the degree “about 0.83” of changing the ON time of the pulsator 15 in the reverse direction R2. doing.

  In addition, when the washing process execution processing unit 101 executes the strong water washing process when the amount of laundry is light, the rotation speed in the forward rotation direction R1 is 110 rpm, the rotation speed in the reverse rotation direction R2 is 130 rpm, and the forward rotation direction R1. Is set to 1.2 seconds, and the ON time in the reverse direction R2 is set to 1.4 seconds. On the other hand, when the washing process execution processing unit 101 executes the strong water washing process when the amount of laundry is heavy, the rotational speed in the normal rotation direction R1 is 140 rpm, the rotational speed in the reverse direction R2 is 150 rpm, and the normal rotation direction R1. Is set to 1.3 seconds, and the ON time in the reverse direction R2 is set to 1.8 seconds. That is, the washing process execution processing unit 101 varies the rotational speed of the pulsator 15 and the on-time for rotating the pulsator 15 depending on whether the amount of laundry is heavy or light.

  In addition, the degree of rotation speed in the normal rotation direction R1 is different between the case where the amount of laundry is heavy and the case where the amount of laundry is light, whereas the rotation speed in the normal rotation direction R1 when the amount of laundry is light is 110 rpm. Since the rotation speed in the forward rotation direction R1 in the heavy case is 140 rpm, 110/140 = approximately 0.76 is calculated. On the other hand, when the amount of laundry is heavy and light, the degree of on-time in the forward direction R1 is different, whereas the on-time in the forward direction R1 when the amount of laundry is light is 1.2 seconds. Since the ON time in the forward rotation direction R1 when the amount of laundry is heavy is 1.3 seconds, 1.2 / 1.3 = 0.92 is calculated. That is, the control device 100 sets the degree of rotation of the pulsator 15 in the forward rotation direction R1 to be different from “about 0.76” and the degree of change in the ON time of the pulsator 15 in the forward rotation direction R1 from “0.92”. It is small.

  In addition, when the amount of laundry is heavy and light, the degree of rotation speed in the reverse direction R2 is different when the amount of laundry is heavy while the rotational speed in the reverse direction R2 when the amount of laundry is light is 130 rpm. Since the rotation speed in the reversing direction R2 is 150 rpm, 130/150 = approximately 0.87 is calculated. On the other hand, the degree of on-time in the reversing direction R2 is different between the case where the amount of laundry is heavy and the case where the amount of laundry is light, whereas the on-time in the reversing direction R2 when the amount of laundry is light is 1.4 seconds. Since the ON time in the reversing direction R2 is 1.8 seconds when the weight is heavy, 1.4 / 1.8 = approximately 0.78 is calculated. That is, the control device 100 increases the degree “about 0.87” of changing the rotation speed of the pulsator 15 in the reverse direction R2 to be larger than the degree “about 0.78” of changing the ON time of the pulsator 15 in the reverse direction R2. doing.

  Further, when the amount of laundry is light and the pulsator 15 is rotated in the forward rotation direction R1, the degree to which the rotational speed of the pulsator 15 is different between the normal water washing process and the strong water washing process is determined in the normal water washing process. Since the rotation speed in the normal rotation direction R1 is 90 rpm, whereas the rotation speed in the normal rotation direction R1 in the strong water washing process is 110 rpm, 110/90 = about 1.22. On the other hand, when the amount of laundry is light and the pulsator 15 is rotated in the forward rotation direction R1, the degree to which the ON time in the forward rotation direction R1 of the pulsator 15 is different between the normal water washing process and the strong water washing process is: The on-time in the forward direction R1 in the normal water washing process is 0.8 seconds, whereas the on-time in the forward direction R1 in the strong water washing process is 1.2 seconds. 8 = 1.5 is calculated. In other words, the control device 100 changes the degree of rotation of the pulsator 15 in the normal rotation direction R1 to “about 1.22” and the degree of change in the ON time of the pulsator 15 in the normal rotation direction R1 from “1.5”. It is small.

  Further, when the amount of laundry is light and the pulsator 15 is rotated in the reversing direction R2, the degree to which the rotation speed of the pulsator 15 is different between the normal water washing process and the strong water washing process is reversed in the normal water washing process. Since the rotation speed in the direction R2 is 90 rpm while the rotation speed in the reverse direction R2 in the strong water washing process is 130 rpm, 130/90 = 1.44 is calculated. On the other hand, when the amount of laundry is light and the pulsator 15 is rotated in the reversing direction R2, the degree to which the ON time in the reversing direction R2 of the pulsator 15 is different between the normal water washing process and the strong water washing process is the normal water flow. Since the ON time in the forward direction R1 in the washing process is 1.0 second, while the ON time in the reverse direction R2 in the strong water washing process is 1.4 seconds, 1.4 / 1.0 = 1. .4. In other words, the control device 100 increases the degree “about 1.44” of changing the rotation speed of the pulsator 15 in the reverse direction R2 to be larger than the degree “1.4” of changing the ON time of the pulsator 15 in the reverse direction R2. ing.

  Further, when the amount of laundry is heavy and the pulsator 15 is rotated in the forward rotation direction R1, the degree to which the rotational speed of the pulsator 15 is different between the normal water washing process and the strong water washing process is determined in the normal water washing process. Since the rotation speed in the forward rotation direction R1 is 110 rpm, whereas the rotation speed in the forward rotation direction R1 in the strong water washing process is 140 rpm, 140/110 = 1.27 is calculated. On the other hand, when the amount of laundry is heavy and the pulsator 15 is rotated in the forward rotation direction R1, the degree to which the on-time in the forward rotation direction R1 of the pulsator 15 is different between the normal water washing process and the strong water washing process is: The on-time in the forward direction R1 in the normal water washing process is 1.0 second, whereas the on-time in the forward direction R1 in the strong water washing process is 1.3 seconds. 0 = 1.3 is calculated. That is, the control device 100 sets the degree of rotation of the pulsator 15 in the normal rotation direction R1 to “about 1.27” and the degree of change in the ON time of the pulsator 15 in the normal rotation direction R1 to “1.3”. It is small.

  When the amount of laundry is heavy and the pulsator 15 is rotated in the reversing direction R2, the degree to which the rotational speed of the pulsator 15 is different between the normal water washing process and the strong water washing process is reversed in the normal water washing process. Since the rotational speed in the direction R2 is 130 rpm, whereas the rotational speed in the reverse direction R2 in the strong water washing process is 150 rpm, 150/130 = about 1.15 is calculated. On the other hand, when the amount of laundry is heavy and the pulsator 15 is rotated in the reversing direction R2, the degree of on-time in the reversing direction R2 of the pulsator 15 is different between the normal water washing process and the strong water washing process. Since the ON time in the forward direction R1 in the washing process is 1.2 seconds, while the ON time in the reverse direction R2 in the strong water washing process is 1.8 seconds, 1.8 / 1.2 = 1. .5. That is, the control device 100 makes the degree of “about 1.15” for changing the rotational speed in the reverse direction R2 of the pulsator 15 smaller than “1.5” for making the ON time of the reverse direction R2 of the pulsator 15 different. ing.

  The washing process execution processing unit 101 is a direction in which the resistance of water to the main front blade part 23 and the auxiliary front blade part 24 increases, in this case, excluding the case where the normal water washing process is performed when the amount of laundry is light. When the pulsator 15 rotates in the reverse direction R2 that is the direction, the rotational speed of the pulsator 15 is made higher than when the pulsator 15 rotates in the other direction, that is, the normal rotation direction R1 that is the winding direction. ing.

  In addition, the washing process execution processing unit 101 is configured so that when the pulsator 15 rotates in the direction in which the water resistance to the main front blade portion 23 and the auxiliary front blade portion 24 increases, in this case, the reverse direction R2 that is the pushing direction. The on-time for rotating the pulsator 15 is made longer than when the pulsator 15 rotates in one direction, that is, the normal rotation direction R1, which is the winding direction.

  According to the washing machine 10 according to the present embodiment, the control device 100 varies the rotational speed of the pulsator 15 and the ON time during which the pulsator 15 is rotated in the preliminary washing process and the main washing process, and the degree to which the rotational speed is different. And the degree of varying on-time is varied. According to this configuration, the discharge amount of the circulating water in the preliminary washing process and the discharge amount of the circulating water in the main washing process can be adjusted as appropriate, and the entire washing process including the preliminary washing process and the main washing process is performed. Regardless of the situation in the tub, the laundry can be fully circulated. In particular, by performing control so that the discharge amount of the circulating water is increased in the preliminary washing process in which the water level in the water tank 12 is low, the circulating water is effectively applied to the laundry from the preliminary washing process which is the initial stage of the washing process. be able to.

  Further, the control device 100 varies the rotational speed of the pulsator 15 and the on-time for rotating the pulsator 15 depending on whether the weight of the laundry is heavier or lighter than the predetermined amount, and the degree to which the rotational speed is varied and on. Different degrees of time. According to this configuration, the circulating water can be discharged with a discharge amount corresponding to the amount of laundry in the rotating tub 14, and the circulating water is effectively applied to the laundry regardless of the amount of laundry in the rotating tub 14. Can do.

  Further, the control device 100 varies the rotational speed of the pulsator 15 and the on-time for rotating the pulsator 15 in the normal water washing process and the strong water washing process, and the degree of varying the rotational speed and the degree of on-time. Make it different. According to this configuration, regardless of whether the water flow generated in the water tank 12 is a normal water flow or a strong water flow, the circulating water can be discharged with a discharge amount corresponding to the water flow. Regardless of its strength, it can effectively circulate water on the laundry.

  In addition, the control device 100 determines that when the pulsator 15 rotates in the direction in which the water resistance to the main front blade part 23 and the auxiliary front blade part 24 increases, the pulsator 15 rotates more than when the pulsator 15 rotates in the other direction. 15 is configured to increase the rotational speed. In addition, the control device 100 determines that when the pulsator 15 rotates in the direction in which the water resistance to the main front blade part 23 and the auxiliary front blade part 24 increases, the pulsator 15 rotates more than when the pulsator 15 rotates in the other direction. 15 is configured to increase the ON time. According to this configuration, a state in which the water in the water tank 12 is pushed out by the main front blade part 23 and the auxiliary front blade part 24, in other words, a state in which the water in the water tank 12 is easily pushed out to the circulation ducts 19A and 19B is ensured for a long time. It is possible to ensure a sufficient amount of circulating water discharged from the circulation ducts 19A and 19B.

(Other embodiments)
The present embodiment is not limited to the above-described embodiment, and may be expanded or changed as follows, for example.

  That is, as illustrated in FIG. 9, the washing machine 10 makes the size of the discharge ports 19A1 and 19A2 provided in the circulation duct 19A different from the size of the discharge port 19B1 provided in the circulation duct 19B, for example. The discharge amount of the circulating water discharged from the discharge ports of the plurality of circulation ducts 19A and 19B may be different.

  Moreover, as illustrated in FIG. 10, the washing machine 10 may have a configuration in which a rib 19r is provided inside the circulation duct 19A, for example. This rib 19r narrows the flow path area of the water channel in the circulation duct 19A, and can thereby strengthen the water flow of the circulating water discharged from the discharge ports 19A1 and 19B2 of the circulation duct 19A.

  Moreover, the height of the discharge port provided in circulation duct 19A, 19B can be adjusted suitably, and can be implemented. In the configuration example shown in FIG. 11, the water level L1 set when the amount of laundry in the rotating tub 14 is light is set to a lower water level than the discharge port 19A2 on the lower side of the circulation duct 19A, and the washing in the rotating tub 14 is performed. The water level L2 set when the quantity is large is higher than the discharge port 19A2 on the lower side of the circulation duct 19A and lower than the discharge port 19A1 on the upper side of the circulation duct 19A and the discharge port 19B1 of the circulation duct 19B. It is set. Further, the water level L3 that is set when the normal water washing process is selected is higher than the lower discharge port 19A2 of the circulation duct 19A, and is discharged from the upper discharge port 19A1 and the circulation duct 19B of the circulation duct 19A. The water level is lower than that of the outlet 19B1, and is further set lower than the above-described water level L2. Further, the water level L4 set when the strong water washing process is selected is lower than the upper discharge port 19A1 of the circulation duct 19A, and the discharge port 19A2 below the circulation duct 19A and the discharge of the circulation duct 19B. The water level is set higher than that of the outlet 19B1.

  In addition to the various water levels L1 to L4 illustrated in FIG. 11, at any one of the water levels, at least one discharge port may be configured to exist at a position higher than the water surface. In addition, in the state where water of the set water level is supplied in the water tank 12, even if there is a discharge port that is submerged, the water in the water tank 12 is agitated in the washing process, and the water level fluctuates, so that the water level fluctuates. Since a state where the discharge port appears on the water surface can also be formed, in such a state, the circulating water can be supplied to the laundry.

  Further, the number of main front blade portions 23 is not limited to three, and the number can be changed as appropriate. Further, the number of main front blade portions 23 may be an odd number or an even number. Further, the number of auxiliary front blade portions 24 is not limited to three, and the number can be changed as appropriate. Further, the number of auxiliary front blade portions 24 may be an odd number or an even number. Further, the number of main front blade portions 23 and the number of auxiliary front blade portions 24 may be the same or different. It is also permissible to provide a portion that does not have the auxiliary front blade portion 24 between the adjacent main front blade portions 23. In addition, a plurality of auxiliary front blade portions 24 may be provided between adjacent main front blade portions 23.

  Further, the number of circulation ducts provided in the rotating tub 14 is not limited to two, and may be three or more, for example. Further, the plurality of circulation ducts provided in the rotating tub 14 may face each other or may not face each other. Further, the plurality of circulation ducts provided in the rotating tank 14 may be provided at equal intervals along the circumferential direction of the rotating tank 14 or may be provided at unequal intervals.

  According to the washing machine which concerns on this embodiment, the discharge amount of the water discharged from the discharge port of a some circulation duct differs. According to this configuration, it is possible to sufficiently circulate water in the laundry regardless of the situation in the tub.

  This embodiment is presented as an example and is 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 drawing, 10 is a washing machine, 12 is a water tub, 14 is a rotating tub, 15 is a pulsator, 16 is a back blade, 19A and 19B are circulation ducts, 19A1, 19A2 and 19B1 are discharge ports, and 23 is a main front blade portion (front surface). The blades 24 and 24 are auxiliary front blades (front blades), 101 is a washing process execution processing unit (washing process execution means), and 102 is a weight detection processing unit (weight detection means).

Claims (8)

A tank,
A rotating tank provided rotatably in the water tank;
A plurality of circulation ducts provided on an inner peripheral surface of the rotating tub and extending along an axial direction of the rotating tub;
A pulsator provided rotatably at the bottom of the rotating tank;
A back blade that is provided on the back surface of the pulsator and raises the water in the water tank through the circulation duct as the pulsator rotates;
A discharge port that is provided in each of the plurality of circulation ducts, and discharges water that rises in the circulation duct by the back blades into the rotary tank;
With
A washing machine having different discharge amounts of water discharged from the discharge ports of the plurality of circulation ducts.   The washing machine according to claim 1, wherein the discharge amount of water discharged from the discharge ports of the plurality of circulation ducts is made different by changing the number of the discharge ports provided in the plurality of circulation ducts. .   The washing machine according to claim 1 or 2, wherein a discharge width of water discharged from the discharge ports of the plurality of circulation ducts is different. A washing step of performing a preliminary washing step of rotating the pulsator by supplying water to a level lower than a predetermined level in the water tank and a main washing step of supplying water to the predetermined level in the water tank and rotating the pulsator With execution means,
The washing step execution means makes the rotation speed of the pulsator and the on-time for rotating the pulsator different in the preliminary washing step and the main washing step, and makes the degree of the rotation speed different and the on-time different. The washing machine according to any one of claims 1 to 3, wherein the degrees are different. A washing process execution means for performing a washing process of supplying water into the water tank and rotating the pulsator;
Weight detection means for detecting the weight of the laundry contained in the rotating tub;
With
The washing process execution means varies the rotation speed of the pulsator and the on-time for rotating the pulsator depending on whether the weight of the laundry detected by the weight detection means is heavier than a predetermined amount or light. The washing machine according to any one of claims 1 to 3, wherein the degree of varying the speed and the degree of varying the on-time are varied. A normal water washing step of washing the laundry by generating a normal water flow in the water in the water tank, and a strong water washing step of washing the laundry by generating a strong water flow stronger than the normal water flow in the water in the water tank, A washing process execution means for executing
The washing step execution means varies the rotation speed of the pulsator and the on-time for rotating the pulsator in the normal water washing step and the strong water washing step, and the degree and the on-time for varying the rotation speed. The washing machine according to any one of claims 1 to 3, wherein the degree of difference is different. The pulsator has front blades on the surface, and is rotatable in a first direction and a second direction,
The front blades have different shapes on the first direction side and the second direction side,
When the pulsator rotates in the direction in which the resistance of water to the front blade increases in the first direction and the second direction, the washing process execution means is more than in the case where the pulsator rotates in the other direction. The washing machine according to any one of claims 4 to 6, wherein the rotational speed of the pulsator is increased. The pulsator has front blades on the surface, and is rotatable in a first direction and a second direction,
The front blades have different shapes on the first direction side and the second direction side,
When the pulsator rotates in the direction in which the resistance of water to the front blade increases in the first direction and the second direction, the washing process execution means is more than in the case where the pulsator rotates in the other direction. The washing machine according to any one of claims 4 to 6, wherein an on-time for rotating the pulsator is lengthened.

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