JP5508758B2 - Washing machine - Google Patents

Description

  The present invention relates to a washing machine provided with means for detecting the weight of laundry put into a rotating tub.

  In a washing machine, the laundry put in a rotating tub such as a drum before starting the washing operation in order to determine the amount of detergent required and the amount of water to be supplied in the washing operation and the rinsing operation. A process for detecting the weight of the (a weight sensing process) is performed. For example, in Patent Document 1, after eliminating the imbalance of the laundry in the drum, the q-axis current (torque current) obtained by the vector control calculation is sampled in a period in which the rotation speed is increased to 200 rpm, and the sampling value is calculated. A configuration is disclosed that integrates by accumulation and detects the weight of the laundry according to the result. Recently, however, the capacity of washing machines has been increasing, and there are products in which the maximum weight of laundry reaches nearly 10 kg. For this reason, in the case where laundry of various fabrics is mixed, it is assumed that the weight detected in the dry cloth state is different from the actual weight.

  Further, the applicant arranges a permanent magnet having a coercive force at a level at which the magnetizing amount can be easily changed in a part of the rotor magnet as disclosed in Patent Document 2, and the magnetizing amount of the magnet We are considering applying a motor whose characteristics can be changed dynamically to a washing machine. By adopting such a configuration, it is possible to change the torque characteristics of the motor when the required output characteristics change greatly, such as in the washing operation or the dehydration operation, or according to the weight of the laundry.

JP 2004-113286 A JP 2006-28095 A

However, if the actual weight of the laundry is different from the sensed result, the motor torque becomes insufficient for heavy loads and the stirring operation becomes insufficient, or conversely, the motor torque becomes excessive for light loads. It is assumed that the driving efficiency decreases, for example, it is turned too much.
The present invention has been made in view of the above circumstances, and an object of the present invention is to provide a washing machine that can more reliably detect the weight of the laundry and adapt the characteristics of the motor to the actual load.

In order to achieve the above object, the washing machine according to claim 1 or 2 is provided with a permanent magnet having a coercive force at a level at which the amount of magnetization can be easily changed on the rotor side, for performing a washing operation. A permanent magnet motor that generates rotational driving force;
A magnetization amount control means for generating an exciting current so as to change the magnetization amount of the permanent magnet;
A weight detection means for detecting the weight of the laundry put in the rotating tub,
The magnetization amount control means includes:
The amount of magnetization of the permanent magnet is set according to the dry cloth weight detected before the first water supply is performed in the rotary tub by the weight detection means,
If it is determined that the weight of the laundry estimated from the cloth weight in the water absorption state (water absorption cloth weight) detected after the first water supply is performed is heavier than the dry cloth weight, the amount of magnetization of the permanent magnet is increased. (Claim 1), when it is determined that the weight is smaller than the weight of the dry cloth, the amount of magnetization of the permanent magnet is reduced (Claim 2) .
If comprised in this way, since the magnetization amount of a permanent magnet will respond | correspond by the actual weight of the laundry, the characteristic of a motor can be optimized according to a load amount.

According to the washing machine of the first or second aspect , since the motor characteristics can be optimized according to the load amount, the driving efficiency can be improved and the power consumption can be reduced.

The flowchart which is a 1st Example and shows the process part which performs a weight detection during a washing operation. (A) is a magnetizing process of an alnico magnet, (b) is a flowchart showing the demagnetizing process. The figure which shows the relationship between the stop position of a rotor, and each signal output level of a rotation position sensor The figure which shows the process when a general washing machine performs fully automatic operation, and the change of motor rotation speed FIG. 1A is a plan view schematically showing an overall configuration of a drum motor, and FIG. 2B is an enlarged perspective view showing a part of a rotor. Longitudinal side view showing the configuration of the washer / dryer Diagram showing drum motor drive system The figure which shows the functional block of the sensorless vector control performed about a drum motor FIG. 1 equivalent view showing the second embodiment Flow chart showing cloth quality determination processing The flowchart which is a 3rd Example and shows the process part which performs a weight detection during washing | cleaning driving | operation. The flowchart which is a 4th Example and shows the process part which performs a weight detection during drying operation. Time chart showing an example of the progress of drying operation

(First embodiment)
Hereinafter, a first embodiment applied to a heat pump type washing / drying machine (laundry machine) will be described with reference to FIGS. In FIG. 6 which shows the longitudinal side surface of the washing / drying machine, a water tank 2 is elastically supported by a plurality of support devices 3 in a horizontal state inside the outer box 1. A rotating drum (hereinafter simply referred to as a drum) 4 is rotatably disposed in the water tank 2 in a coaxial state with the water tank 2. The drum 4 has a large number of dewatering holes 4a (only part of which are shown) serving as ventilation holes on the peripheral side wall and the rear wall, and also functions as a washing tub, a dewatering tub, and a drying chamber. A plurality of baffles 4 b (only one is shown) are provided on the inner peripheral surface of the drum 4.

  The outer box 1, the water tank 2 and the drum 4 all have openings 5, 6 and 7 for putting in and out the laundry on the front surface (right side in the figure), respectively. The portion 6 is connected in watertight communication with a bellows 8 that is elastically deformable. The opening 5 of the outer box 1 is provided with a door 9 for opening and closing the opening. The drum 4 has a rotating shaft 10 on the back surface. The rotating shaft 10 is supported by a bearing (not shown) and attached to the outer side of the back surface of the water tank 2. A drum motor (washing / dehydrating motor, permanent magnet motor) 11 composed of a phase brushless DC motor is driven to rotate. The rotating shaft 10 is integral with a rotating shaft of a drum motor (hereinafter simply referred to as a motor) 11, and the drum 4 is driven by a direct drive system.

  A casing 13 is supported on the bottom plate 1a of the outer box 1 via a plurality of support members 12, and a discharge port 13a and a suction port 13b are formed at the upper right end portion and the upper left end portion of the casing 13, respectively. ing. Moreover, the compressor 15 of the heat pump (refrigeration cycle) 14 is installed in the bottom plate 1a. Further, in the casing 13, a condenser 16 and an evaporator 17 of the heat pump 14 are installed in order from the right side to the left side, and a blower fan 18 is disposed at the right end portion. A dish-shaped water receiving portion 13 c is formed at a portion of the casing 13 located below the evaporator 17.

  In the water tank 2, an intake port 19 is formed in the upper part of the front surface part, and an exhaust port 20 is formed in the lower part of the back surface part. The intake port 19 is connected to the discharge port 13 a of the casing 13 through a linear duct 21 and an extendable connecting duct 22. Further, the exhaust port 20 is connected to the suction port 13 b of the casing 13 via an annular duct 23 and an extendable connecting duct 24. The annular duct 23 is attached to the outside of the back surface portion of the water tank 2 and is formed so as to be concentric with the motor 11. That is, the inlet side of the annular duct 23 is connected to the exhaust port 20, and the outlet side is connected to the suction port 13 b via the connecting duct 24. The casing 13, the connecting duct 22, the linear duct 21, the intake port 19, the exhaust port 20, the annular duct 23, and the connecting duct 14 constitute an air circulation path 25.

In the outer box 1, a water supply valve 26 composed of a three-way valve is disposed at the upper rear portion thereof, and a detergent feeder 26a is disposed at the upper upper portion thereof. The water supply valve 26 has a water inlet connected to a water faucet via a water supply hose, a first water outlet connected to an upper water inlet of the detergent feeder 26a via a water supply hose 26b for washing, The water outlet is connected to the lower water inlet of the detergent dispenser 26a through the rinsing water supply hose 26c. And the water outlet of the detergent feeder 26a is connected to the water inlet 2a formed in the upper part of the water tank 2 via the water supply hose 26d.
A drain port 2b is formed at a rear portion of the bottom of the water tank 2, and the drain port 2b is connected to the drain hose 27 via a drain valve 27a. A part of the drain hose 27 is telescopic. And the water receiving part 13c of the casing 13 is connected to the middle part of the drainage hose 27 via the drainage hose 28 and the check valve 28a.

  An operation panel unit 29 is provided on the front upper portion of the outer box 1, and the operation panel unit 29 is provided with a display and various operation switches (not shown). Further, a display / operation board 84 is provided on the back surface of the operation panel unit 29, and communicates with a control circuit (magnetization amount control means, weight detection means) 30 built in the board case 110. The operation panel unit 29 is controlled. The control circuit 30 is constituted by a microcomputer, and controls the water supply valve 26, the motor 11 and the drain valve 27a in accordance with the operation of the operation switch of the operation panel unit 29, and performs washing, rinsing and dewatering washing operations, 11 and a compressor motor (compressor motor, not shown) composed of a three-phase brushless DC motor for driving the compressor 15 is controlled to execute a drying operation.

FIG. 7 schematically shows the drive system of the motor 11. The inverter circuit (PWM control type inverter, magnetization amount control means) 32 is configured by connecting six IGBTs (semiconductor switching elements) 33a to 33f in a three-phase bridge, and between the collector and emitter of each IGBT 33a to 33f. Are connected to flywheel diodes 34a to 34f.
The emitters of the IGBTs 33d, 33e, 33f on the lower arm side are connected to the ground through shunt resistors (current detection means) 35u, 35v, 35w. The common connection point between the emitters of the IGBTs 33d, 33e, and 33f and the shunt resistors 35u, 35v, and 35w is connected to the control circuit 30 via the level shift circuit 36, respectively. Incidentally, since a maximum of about 15 A flows through the windings 11u to 11w of the motor 11, the resistance values of the shunt resistors 35u to 35w are set to 0.1Ω, for example.

The level shift circuit 36 includes an operational amplifier and the like, amplifies the terminal voltage of the shunt resistors 35u to 35w, and gives a bias so that the output range of the amplified signal is within the positive side (for example, 0 to + 3.3V). . Further, when the upper and lower arms of the inverter circuit 32 are short-circuited, the overcurrent comparison circuit 38 performs overcurrent detection in order to prevent circuit destruction.
A driving power supply circuit 39 is connected to the input side of the inverter circuit 32. The drive power supply circuit 39 rectifies a 100V AC power supply 40 by a full-wave rectification circuit 41 composed of a diode bridge and a double voltage full-wave rectification by two capacitors 42a and 42b connected in series, and a DC voltage of about 280V. Is supplied to the inverter circuit 32. Each phase output terminal of the inverter circuit 32 is connected to each phase winding 11 u, 11 v, 11 w of the motor 11.

The control circuit 30 detects currents Iau to Iaw flowing through the windings 11u to 11w of the motor 11 obtained via the level shift circuit 36, and based on the current value, the phase θ and the rotational angular velocity of the secondary rotating magnetic field. In addition to estimating ω, the three-phase current is subjected to orthogonal coordinate transformation and dq (direct-quadrature) coordinate transformation to obtain an excitation current component Id and a torque current component Iq.
When a speed command is given from the outside, the control circuit 30 generates current commands Idref and Iqref based on the estimated phase θ, rotational angular velocity ω, and current components Id and Iq, and converts them into voltage commands Vd and Vq. Then, rectangular coordinate transformation and three-phase coordinate transformation are performed. Finally, a drive signal is generated as a PWM signal and output to the windings 11 u to 11 w of the motor 11 via the inverter circuit 32.

  The first power supply circuit 43 steps down the drive power supply of about 280V supplied to the inverter circuit 32 to generate a control power supply of 15V and supplies it to the control circuit 30 and the drive circuit 44. The second power supply circuit 45 is a three-terminal regulator that generates 3.3V power from the 15V power generated by the first power circuit 43 and supplies the 3.3V power to the control circuit 30. The high voltage driver circuit 46 is arranged to drive the IGBTs 33 a to 33 c on the upper arm side in the inverter circuit 32.

  Further, the rotor of the motor 11 is provided with a rotational position sensor 78 (u, v, w) constituted by, for example, a Hall IC for use at startup, and the rotational position sensor 78 (position detecting means) outputs The rotor position signal is supplied to the control circuit 30. That is, when the motor 11 is started, vector control is performed using the rotational position sensor 78 until the rotational speed at which the rotor position can be estimated (for example, about 30 rpm), and after reaching the rotational speed, Switch to sensorless vector control without using the rotational position sensor 78.

The compressor motor has a configuration that is substantially symmetric to the drive system of the motor 11, although not specifically illustrated.
A series circuit of resistance elements 79 a and 79 b is connected between the output terminal of the power supply circuit 39 and the ground, and the common connection point is connected to the input terminal of the control circuit 30. The control circuit 30 reads the input voltage of the inverter circuit 32 divided by the resistance elements 79a and 79b and uses it as a reference for determining the PWM signal duty.

In addition, a series circuit of a diode 80 and resistance elements 81a and 81b (induced voltage detection means) is connected between the W-phase output terminal of the inverter circuit 32 and the ground, and a capacitor (inductive voltage) is connected to the resistance element 81b. (Voltage detection means) 82 is connected in parallel. The common connection point of the resistance elements 81a and 81b is connected to the input terminal of the control circuit 30, and the control circuit 30 detects the induced voltage generated in the winding 11W when the motor 11 is idling. .
In addition, the control circuit 30 controls various electrical components 83 such as a door lock control circuit and a drying fan motor, and inputs / outputs operation signals and control signals to / from the display / operation board 84 described above. To do.

  FIG. 8 is a functional block diagram of sensorless vector control performed by the control circuit 30 for the motor 11 (and the compressor motor). This configuration is the same as that disclosed in, for example, Japanese Patent Application Laid-Open No. 2003-181187, and will be schematically described here. In FIG. 8, (α, β) represents an orthogonal coordinate system obtained by orthogonal transformation of a three-phase (UVW) coordinate system with an electrical angle interval of 120 degrees corresponding to each phase of the motor 11, and (d, q) is The coordinate system of the secondary magnetic flux which is rotating with rotation of the rotor of the motor 11 is shown.

  The subtracter 62 is supplied with the target speed command ωref from the speed command output unit 60 as a subtracted value and the detected speed ω of the motor 11 detected by the estimator 63 as a subtracted value. The result is given to a speed PI (Proportional-Integral) control unit 65. The speed PI control unit 65 performs PI (proportional integration) control based on the difference between the target speed command ωref and the detected speed ω, and generates and subtracts the q-axis current command value Iqref and the d-axis current command value Idref. Are output as subtracted values to the devices 66q and 66d, respectively. The subtractors 66q and 66d are respectively provided with the q-axis current value Iq and the d-axis current value Id output from the αβ / dq conversion unit 67 as subtraction values, and the subtraction results are respectively supplied to the current PI control units 68q and 68d. Given. The control period in the speed PI control unit 65 is set to 1 msec.

  The current PI controllers 68q and 68d perform PI control based on the difference amount between the q-axis current command value Iqref and the d-axis current command value Idref, and generate the q-axis voltage command value Vq and the d-axis voltage command value Vd. And output to the dq / αβ conversion unit 69. The dq / αβ conversion unit 69 is given a rotational phase angle (rotor position angle) θ of the secondary magnetic flux detected by the estimator 63, and voltage command values Vd and Vq are converted into voltage commands based on the rotational phase angle θ. Convert to values Vα and Vβ.

  The voltage command values Vα and Vβ output from the dq / αβ conversion unit 69 are converted into three-phase voltage command values Vu, Vv and Vw by the αβ / UVW conversion unit 70 and output. The voltage command values Vu, Vv, Vw are given to one fixed contact 71ua, 71va, 71wa of the changeover switches 71u, 71v, 71w, and are output from the initial pattern output unit 76 to the other fixed contact 71ub, 71vb, 71wb. Voltage command values Vus, Vvs, and Vws are given. The movable contacts 71uc, 71vc, 71wc of the changeover switches 71u, 71v, 71w are connected to the input terminal of the PWM forming unit 73.

The PWM forming unit 73 modulates a 15.6 kHz carrier (triangular wave) based on the voltage command values Vus, Vvs, Vws or Vu, Vv, Vw, and outputs PWM signals Vup (+,-), Vvp (+, -), Vwp (+,-) is output to the inverter circuit 32. The PWM signals Vup to Vwp are output as signals having a pulse width corresponding to the voltage amplitude based on the sine wave so that, for example, a sine wave current is passed through the phase windings 11u, 11v, and 11w of the motor 11.
The A / D converter 74 outputs current data Iau, Iav, and Iaw obtained by A / D converting voltage signals appearing at the emitters of the IGBTs 33 d to 33 f to the UVW / αβ converter 75. The UVW / αβ conversion unit 75 converts the three-phase current data Iau, Iav, Iaw into two-axis current data Iα, Iβ in an orthogonal coordinate system according to a predetermined arithmetic expression. Then, the biaxial current data Iα and Iβ are output to the αβ / dq converter 67.

  The αβ / dq conversion unit 67 obtains the rotor position angle θ of the motor 11 from the estimator 63 at the time of vector control, thereby obtaining the biaxial current data Iα, Iβ on the rotational coordinate system (d, q) according to a predetermined arithmetic expression. When converted into the d-axis current value Id and the q-axis current value Iq, they are output to the estimator 63 and the subtractors 66d and 66q as described above.

  The estimator 63 estimates the rotor position angle θ and the rotational speed ω based on the q-axis voltage command value Vq, the d-axis voltage command value Vd, the q-axis current value Iq, and the d-axis current value Id, and outputs them to each unit. . Here, when the motor 11 is started, a startup pattern is applied by the initial pattern output unit 76 and forced commutation is performed. Thereafter, when the rotational position sensor 78 performs vector control based on the sensor signal, the estimator 63 is activated, and the process proceeds to sensorless vector control in which the rotor position angle θ and the rotational speed ω of the motor 11 are estimated. In the case of a compressor motor, the process shifts from forced commutation to sensorless vector control.

  The switching control unit 77 controls switching of the selector switch 71 based on the duty information of the PMW signal given from the PWM forming unit 73. In the above configuration, the configuration excluding the inverter circuit 32 is a block of functions realized by the software of the control circuit 30. The current control period in the vector control is set to 128 μsec, for example. However, the PWM carrier wave period is 64 μsec on the motor 11 side and 128 μsec on the compressor motor side. The control circuit 30 and the inverter circuit 32 constitute an inverter device 99.

5A is a plan view schematically showing the entire configuration of the motor 11, and FIG. 5B is a perspective view showing a part thereof enlarged. The motor 11 includes a stator 91 and a rotor 92 provided on the outer periphery of the stator 91. The stator 91 includes a stator core 93 and stator windings 11u, 11v, and 11. The stator core 93 has an annular yoke portion 93a and a large number of teeth portions 93b protruding radially from the outer peripheral portion of the yoke portion 93a. The stator windings 11u, 11v, and 11w are connected to the teeth portions 93b. It is wound.
The rotor 92 has a structure in which a frame 94, a rotor core 95, and a plurality of permanent magnets 96, 97 are integrated with a mold resin (not shown). The frame 94 is formed into a flat bottomed cylindrical shape by pressing, for example, an iron plate that is a magnetic material. The permanent magnets 96 and 97 constitute a rotor magnet 98.

  The rotor core 95 is disposed on the inner peripheral portion of the peripheral side wall of the frame 94, and the inner peripheral surface thereof is formed in a concavo-convex shape having a plurality of convex portions 95a that protrude in an arc shape toward the inside. . Inside these convex portions 95a, there are formed rectangular insertion holes 95b and 95c penetrating in the axial direction and having different short sides, and these are alternately arranged in an annular shape one by one. Yes. Neodymium magnets 96 (first permanent magnets) and alnico magnets 97 (second permanent magnets) are inserted into the respective insertion holes 95b and 95c. In this case, the coercive force of the neodymium magnet 96 is about 900 kA / m, the coercive force of the alnico magnet 97 is about 100 kA / m, and the coercive force differs by about 9 times.

  Further, each of these two types of permanent magnets 96 and 97 forms one magnetic pole, and for example, a total of 48 pieces are arranged in each of 24 pieces so that the magnetization direction is along the radial direction of the motor 11. Has been. In this way, by arranging the two types of permanent magnets 96 and 97 alternately so that their magnetization directions are along the radial direction, the adjacent permanent magnets 96 and 97 have magnetic poles in opposite directions. (A state in which one N pole is inside and the other N pole is outside), and a magnetic path (magnetic flux) is generated between the neodymium magnet 96 and the Alnico magnet 97 in the direction indicated by the arrow B, for example. That is, a magnetic path passing through both the neodymium magnet 96 having a large coercive force and the alnico magnet 97 having a small coercive force is formed.

  Next, the operation of this embodiment will be described with reference to FIGS. FIG. 4 shows a process when a general washing machine performs a fully automatic operation, in which the horizontal axis represents elapsed time (minutes) and the vertical axis represents the rotation speed (rpm) of the motor 11. In addition, although the structure demonstrated above is a washing dryer, it is abbreviate | omitting about the drying operation on account of description.

Among these, the main processes in which the change in the number of revolutions of the motor 11 is remarkable are (B) washing process, (E) rinsing dehydration (1) process, (G) rinsing stirring (1) process, (J) rinsing dehydration. (2) Step, (L) Rinsing and stirring (2) Step, (O) Final dehydration step. The maximum rotation speed of the motor 11 in the steps (B), (G), and (L) is about 50 rpm, the maximum rotation speed in the steps (E) and (J) is about 1300 rpm, and the maximum rotation speed in the step (O) is It is about 800 rpm. Further, the output torque of the motor 11 in the steps (B), (G), and (L) is about 280 kgf · cm, and the output torque in the steps (E) and (J) is about 20 to 30 kgf · cm. That is, the steps (B), (G), and (L) are operated with low speed rotation and high output torque, and the steps (E) and (J) are operated with high speed rotation and low output torque.
In the case of the “preheat dehydration” operation in which the washing and drying machine performs dehydration while applying heat to the laundry in the drum 4, the pattern is the same as the rinse dehydration process of (E) and (J).

  In the conventional washing machine, as described above, in the high speed rotation / low output torque operation, the field speed control is performed to increase the number of rotations. However, in this embodiment, the rotor 92 of the motor 11 is changed. By changing the amount of magnetization of the constituting Alnico magnet 97, the magnetic flux of the rotor magnet 98 is dynamically changed so that the motor 11 conforms to the characteristics required for each operation of the washing machine. That is, when low-speed rotation and high output torque are required, such as washing and rinsing operations, the magnetic flux of the entire rotor magnet 98 is increased by increasing (magnetizing) the magnetization amount of the alnico magnet 97, and dehydration. When high speed rotation and low output torque are required as in operation, the magnetic flux of the entire rotor magnet 98 is controlled by decreasing (demagnetizing) the amount of magnetization of the alnico magnet 97.

  Hereinafter, processing for changing the magnetization amount of the alnico magnet 97 will be described. FIG. 2A is a flowchart showing processing when the Alnico magnet 97 is demagnetized from the dehydrating operation to the washing / rinsing operation. In order to stop the rotation of the drum 4-motor 11 in the dehydration operation, a brake operation is started (step S1). When the rotation stops (step S2: YES), a d-axis current is output so as to magnetize the alnico magnet 97. (Step S3). In this case, the rotational position of the rotor 92 is fixed by applying a d-axis current. Next, the energized phase is changed so that the rotor 92 is moved by one electrical angle (1/24 mechanical angle) from that state (step S4), and the d-axis current is output again (step S5). To do.

  Here, as shown in FIG. 5A, the Alnico magnets 97 are arranged in the order of U, V, W,... In the clockwise direction. For example, when the rotor 92 is positioned with reference to the uppermost U phase, the stator 91 Alnico magnets 97 to which the teeth 93b face are arranged in the order of U, W, V, U, W, V,. Accordingly, in step S3, every other alnico magnet 97 is magnetized as described above, and the alnico magnet 97 positioned between them is in an incompletely magnetized state. Therefore, when the rotor 92 is moved by one electrical angle in step S4, the remaining alnico magnet 97 can be favorably magnetized.

In addition, in the case where the d-axis current is generated in step S3 and the first magnetizing is performed, the position of the rotor 92 in the stopped state is ascertained by the rotational position sensor 78 before that, and according to the stop position. Determine the energized phase. That is, as shown in FIG. 3, the output levels of the signals A, B, and C of the rotational position sensors (Hall sensors) 78u, 78v, and 78w differ depending on the electrical angle of 60 degrees according to the stop position of the rotor 92. There are six states. Therefore, if a d-axis current is applied in an energized phase corresponding to the output level of the sensor signals A, B, C, and the rotor 92 is fixed at each of 30 degrees, 90 degrees, 150 degrees,. Since the rotational movement amount of 92 is reduced, noise can be suppressed. Since washing machines are often installed indoors, it is extremely important to reduce noise.
FIG. 2B is a flowchart showing a process for demagnetizing the alnico magnet 97 from the magnetized state when shifting from the washing / rinsing operation to the dehydrating operation. The basic procedure is the same as in the case of FIG. 2A, and only steps S8 and S10 corresponding to steps S3 and S5 are “demagnetizing current output”.

By the way, in general, in a washing machine, when the user puts laundry into the drum 4 and performs an input operation instructing the start of operation (before the start of the step (A) in FIG. 4), the amount of detergent necessary for the laundry operation is set. A laundry weight detection process (weight sensing) is performed for the purpose of displaying or determining the amount of water supply. Although there are various methods, for example, the method disclosed in Japanese Patent Application Laid-Open No. 2004-113286 is used here.
That is, the motor 11 is forcibly commutated by a starting voltage command output from the initial pattern output unit 73 that positions the rotor 92 by direct current excitation. The forced commutation operation is continued in step S3 until the rotation speed of the motor 11 reaches 30 rpm. When the rotation speed reaches 30 rpm, switching to the vector control side is performed, and acceleration is performed by speed PI control so that the rotation speed of the motor 11 reaches a target rotation speed (for example, 270 rpm) in about 3 seconds.

  Then, the q-axis current value Iq is sampled at regular intervals and integrated (integrated) during the acceleration period of about 3 seconds, and the dry cloth weight of the laundry to be loaded is estimated from the integration result. At this time, as in Japanese Patent Application Laid-Open No. 2004-113286 or Japanese Patent Application Laid-Open No. 2004-49431, the q-axis current value Iq is continuously integrated, and at the same time, the fluctuation of the q-axis current is also integrated, The estimation result of the amount of laundry may be corrected according to the degree of unevenness of the laundry distribution and the unbalanced state. Alternatively, unbalance detection may be performed before the integration of the q-axis current value Iq is started, and the integration of the q-axis current value Iq may be started when it is determined that the degree of unbalance is equal to or less than a threshold value.

  Further, in the present embodiment, after the above weight sensing is performed, water supply is started and the laundry weight detection process is performed even during the washing operation (see the upward arrow in FIG. 4). Hereinafter, this process will be described with reference to FIG. FIG. 1 is a flowchart showing a processing portion that performs weight detection during a washing operation. After the washing operation is started, it is determined whether or not 5 minutes have passed (steps S11 and S12). When 5 minutes have passed (YES), the drum 4 is rotated at 50 rpm in a steady manner (step S13). Then, when the motor 11 is idled, the control circuit 30 samples the induced voltage for 3 seconds from that point in time and takes the average of the data to estimate the weight of the laundry that has been absorbed (water absorption cloth weight) ( Step S14). Further, the dry cloth weight is estimated based on the water absorbent cloth weight (step S15).

  Next, the result of weight sensing performed at the start of operation (dry cloth weight) is compared with the weight estimated in step S15 (steps S16 and S18), and if it is determined that the latter weight is heavy (step S16: YES) ) The rotor magnet 98 of the motor 11 is magnetized (step S17). On the other hand, when it is determined that the former is heavy (step S18: YES), the rotor magnet 98 of the motor 11 is demagnetized (step S19). If “NO” is determined in the step S18, the weights of the both are almost the same, so the processing is ended as it is.

That is, depending on the type of laundry put into the drum 4, for example, the cloth quality, the weight detection in the dry cloth state is not performed accurately, the drum 4 is supplied with water, and the laundry is detected in a state of absorbing water. The weight estimated based on the weight may be different. Since the weight detected in the water absorption state may be a more accurate value, if the result estimated from the water absorption cloth weight is different from the dry cloth weight, the magnetization of the rotor magnet 98 according to the difference between the two. The state is changed so that the motor 11 can output torque according to the load.
The reason why the same detection method as that for detecting the dry cloth weight is not employed is that the method for detecting the induced voltage is easy to execute even during the washing operation.

  As described above, according to the present embodiment, when the motor 11 is configured to include the Alnico magnet 97 having a coercive force at a level at which the amount of magnetization can be easily changed, the rotor 92 is inserted into the drum 4. For the laundry, the amount of magnetization of the Alnico magnet 97 is set according to the dry cloth weight detected before the first water supply, and is estimated from the water absorbent cloth weight detected after the first water supply. When there is a difference between the laundry weight and the dry cloth weight, the magnetization amount of the alnico magnet 97 is changed according to the difference. Accordingly, the magnetized amounts of the alnico magnet 97 and the rotor magnet 98 correspond to the actual weight of the laundry, and the characteristics of the motor 11 can be optimized according to the load amount, so that the driving efficiency is improved and the power consumption is improved. Can be reduced.

  When the weight of the water absorbent cloth is detected, the magnitude of the induced voltage (sampling data) generated in the winding 11w of the motor 11 when the motor 11 is rotated at a constant rotation speed (50 rpm) and then idled. Therefore, the weight of the absorbent cloth can be easily detected even during the washing operation. In the washing operation, the weight of the water absorbent cloth is detected when a predetermined time (5 minutes) has elapsed after the start of the washing operation, so that the water absorption is performed when almost the entire laundry has absorbed water. The cloth weight can be detected more accurately.

(Second embodiment)
9 and 10 show the second embodiment. The same parts as those in the first embodiment are denoted by the same reference numerals and the description thereof is omitted. Hereinafter, different parts will be described. In the second embodiment, when washing operation is performed, a process for determining the quality of the laundry is performed, and the amount of magnetization of the alnico magnet 97 and the rotor magnet 98 is changed according to the determination result. Here, “cloth quality determination” means that the overall fabric quality of the laundry put in the drum 4 is mostly pure cotton (cotton-based), or a mixture of cotton and synthetic fiber. It is a rough judgment as to whether there are many or other.

  FIG. 9 is a flowchart showing a process during the washing operation. First, a cloth quality determination process is performed (step S21), which will be described with reference to FIG. When the drum 4 is rotated by driving the motor 11 and the laundry is stirred (step S31), the motor 11 is rotated in the idling state 10 seconds after reaching the steady rotation speed (for example, 50 rpm). When the q-axis current Iq is sampled for a predetermined number of units before the stop, the average value thereof is taken (step S32). The process of taking the average value for the sampling data for the predetermined number of units is repeated 10 times (step S33).

  When 10 measurements are completed (step S33: YES), an average value is further calculated for the 10 measurement results (step S34), and the calculated average value (measured value) is compared with the first threshold value (step S34). Step S35). If (measured value> first threshold value) (YES), the fabric is determined to be “cotton” (step S36). If (measured value ≦ first threshold value), (NO) the measured value is set to the first threshold value. It is compared with the second threshold value set to a lower value (step S37). If (measured value> second threshold value) (YES), the fabric is determined to be “synthetic fiber blend” (step S38). If (measured value ≦ second threshold value), (NO) fabric quality is other than the above. "Other (for example, synthetic fiber)" is determined (step S39).

  Refer to FIG. 9 again. As described above, if the result of the cloth quality determination in step S21 is “cotton” (step S22: YES), it is estimated that the rate of water absorption by the laundry is high, and the load on the motor 11 is heavier. Therefore, the rotor magnet 98 is magnetized (step S23). On the other hand, if the result of the cloth quality determination is “synthetic fiber blend” (step S24: YES), it is estimated that the cloth is an average laundry quality, so that the amount of magnetization of the rotor magnet 98 remains unchanged. And

If the result of the fabric quality determination is neither “cotton” nor “synthetic fiber blend” (step S24: NO), the water absorption rate of the laundry is low and the motor is low, as in the case where almost the whole is synthetic fiber, for example. 11 is estimated to be lighter. Therefore, the rotor magnet 98 is demagnetized (step S25).
As described above, according to the second embodiment, the cloth quality of the laundry is determined during the washing operation, and the amount of magnetization of the rotor magnet 98 is changed according to the determination result. It is possible to cope with different loads depending on the fabric quality (water absorption rate).

(Third embodiment)
FIG. 11 is a third embodiment, and shows the contents of processing performed during the rinsing operation. When the rinsing operation is performed for the set time (steps S41, S42: YES), the same processing as that of steps S13 to S15 of the first embodiment is performed after draining and before intermediate dehydration (steps S43, S42). S44). The “induced voltage measurement” in step S43 corresponds to steps S13 and S14.

  Then, it is determined whether or not the washing operation is performed before starting the rinsing operation (step S45). If the washing operation is performed (YES), the weight estimated in step S15 and the estimation in step S44 are performed. The weight is compared (step S46). If the latter weight is larger (YES), the rotor magnet 98 is magnetized (step S47) and the operation is continued. If the latter weight is less than the former weight (NO), the latter weight is increased. It is determined whether or not is smaller (step S48). If the latter weight is smaller (YES), the rotor magnet 98 is demagnetized (step S49), and if not smaller (NO), both the weights are equal, so the operation is continued.

On the other hand, in step S45, when only the rinsing operation is performed without performing the washing operation in advance (NO), the weight of the laundry is automatically set to a fixed value before the rinsing operation is started. Therefore, the automatically set weight is compared with the weight estimated in step S44 (step S50). If the latter weight is larger (YES), the rotor magnet 98 is magnetized (step S51) and the operation is continued. If the latter weight is less than the former weight (NO), the latter weight is increased. It is determined whether or not is smaller (step S52). If the latter weight is smaller (YES), the rotor magnet 98 is demagnetized (step S53). If not smaller (NO), the weights of both are equal, so the operation is continued.
In addition, the comparison object in step S46, S48, S50, S52 may not be the estimated dry cloth weight, and may compare the water absorbent cloth weight before estimation. However, in this case, for steps S50 and S52, the automatically set laundry weight needs to correspond to the absorbent cloth weight.

  As described above, according to the third embodiment, the weight of the water absorbent cloth is detected before intermediate dehydration is performed in the rinsing operation, and the weight of the laundry estimated from the weight of the water absorbent cloth and the weight of the water absorbent cloth detected in the washing operation are as follows. When there is a difference in the estimated laundry weight, the amount of magnetization of the rotor magnet 98 is changed according to the difference. Therefore, when the estimation results are different between the time of washing and the time of rinsing, the output torque of the motor 11 immediately after the start of the intermediate dehydration is appropriately obtained by changing the characteristics of the motor 11 according to the difference between the two. .

(Fourth embodiment)
12 and 13 show a fourth embodiment. The fourth embodiment shows processing performed for the drying operation, FIG. 12 is a flowchart, and FIG. 13 is a time chart showing an example of the progress of the drying operation. In FIG. 12, when a room temperature is first detected by a temperature sensor (not shown) for detecting the room temperature (step S61), weight sensing is performed in the same manner as when detecting the dry cloth weight (step S62). In this case, the weight of the water absorbent cloth is detected.

  Then, the warm air is circulated by the heat pump 14 and the blower fan 18 to blow the air into the drum 4, and the drum 11 is rotated to start the first stage of the drying operation (step S63). As shown in FIGS. 13C and 13D, in the driving specification A of the motor 11 in the first stage, the rotation speed is 55 rpm, the normal inversion time is 29 seconds, and the rotation pause time is 3 seconds. During the execution of the first stage, the inlet temperature Ti and the outlet temperature To are measured by temperature sensors (not shown) respectively arranged at the hot air inlet and outlet of the drum 4 (step S64). The first stage (NO) is continued until the temperature difference ΔT (= Ti−To) between the two reaches the maximum value ΔTm, and strictly speaking, when the maximum value ΔTm is reached, the temperature difference ΔT changes from increasing to decreasing. (YES) The first stage is terminated (step S65), and the process proceeds to the second stage (step S66).

  FIG. 13 (a) shows changes in the inlet temperature Ti and the outlet temperature To as the drying operation proceeds, and FIG. 13 (b) shows changes in the temperature difference ΔT. In the state before starting the drying operation, the inlet temperature Ti and the outlet temperature To coincide with each other, and the temperature difference ΔT is “0”. When the drying operation is started from this state, the inlet temperature Ti rapidly increases, but the outlet temperature To gradually increases because the warm air takes in moisture contained in the laundry. As a result, the timing at which the temperature difference ΔT between the two reaches the maximum comes later. The dryness of the laundry at this point is estimated to be about 85%, assuming that the moisture content before starting the drying operation is 100%.

  In the drive specification B of the motor 11 in the second stage, the rotation speed is 60 rpm, the normal inversion time is 29 seconds, and the rotation pause time is 0.2 seconds. During the execution of the second stage, the inlet temperature Ti and the outlet temperature To are measured (step S67), and the second stage is continued until the temperature difference ΔT between the two drops below the maximum value ΔTm by the predetermined temperature T1 (NO). To do. When the temperature difference: ΔT <(ΔTm−T1) is satisfied (YES), the second stage is terminated (step S68), and the process proceeds to the third stage (step S69). The dryness at this point is estimated to be about 90%.

  The drive specification C of the motor 11 in the third stage has a rotation speed of 100 rpm, a normal inversion time of 14 seconds, and a rotation pause time of 0.2 seconds. Even during the execution of the third stage, the inlet temperature Ti and the outlet temperature To are measured to determine the temperature difference ΔT between them (step S70), and the temperature difference ΔT decreases by a predetermined temperature T2 (> T1) from the maximum value ΔTm. (NO) Continue the third stage. When the temperature difference: ΔT <(ΔTm−T2) is satisfied (YES), the third stage is ended (step S71), and the process proceeds to the finishing process (step S72). The dryness at this point is estimated to be about 95-97%.

  The drive specification D of the motor 11 in the finishing stroke has a rotation speed of 125 rpm, a normal inversion time of 14 seconds, and a rotation pause time of 0.2 seconds. When the finishing process is performed for a preset time, the cooling process is finally performed (step S73). At this time, cool air is blown to the drum 4 by the heat pump 14 and the blower fan 18. In the driving specification E of the motor 11 in the cooling stroke, the rotation speed is 80 rpm, the normal inversion time is 29 seconds, and the rotation pause time is 0.2 seconds. When the cooling process is performed for a preset time, the drying operation is terminated.

In the above-described drying operation, as shown in FIG. 13C, when shifting to each stage of the first → second → third → finishing → air blowing, induction is performed as in steps S13 and S14 of the first embodiment. Based on the voltage sampling result, the weight of the absorbent cloth during the drying operation is obtained. If the weights detected before starting each stage (stroke) are weights (A) to (E), the weight (A), the weight (B), and the weight (B ) And weight (C), weight (C) and weight (D), weight (D) and weight (E), respectively. In the drying operation, the weight of the laundry gradually decreases as the drying proceeds. Therefore, the amount of magnetization of the rotor magnet 98 is changed according to the difference in weight detected at the time of transition to each stage and the steady rotational speed of the drive specification of the motor 11.
During the period of transition to the specifications A to D, the steady rotational speed is set to increase sequentially, so the rotor magnet 98 is demagnetized accordingly. When shifting from the last specification D to E, the steady rotational speed is set to be low, and accordingly, the rotor magnet 98 is magnetized.

  As described above, according to the fourth embodiment, when the washing machine has a function of performing the drying operation, the weight of the absorbent cloth is intermittently detected several times during the drying operation, and the latest absorbent cloth weight and the previous time are detected. If there is a difference in the weight of the water absorbent cloth detected, the amount of magnetization of the rotor magnet 98 is changed according to the difference. Therefore, the characteristics of the motor 11 can be changed according to the state of the load that changes as the drying progresses, and the driving specifications of the motor 11 set for each stage of the drying operation. Efficiency can be improved.

The present invention is not limited to the embodiments described above or shown in the drawings, and the following modifications or expansions are possible.
Settings such as the motor rotation speed and sampling period when detecting the induced voltage may be changed as appropriate.
As the induced voltage, a voltage obtained by calculation based on the voltage / current equation of the motor inside the estimator 63 may be used.
The weight detection method is not limited to that shown in the embodiment, and any method may be used. For example, the detection of the dry cloth weight and the detection of the water absorbent cloth weight may be performed by the same method.
In the first embodiment, the timing for estimating the load amount during the washing operation is not limited to 5 minutes after the start of operation, and may be changed as appropriate.
A different method may be adopted for the cloth quality determination process in the second embodiment.

The first and second permanent magnets are not limited to neodymium magnets and alnico magnets, respectively, and may be appropriately changed as long as they are magnetic materials that satisfy the holding force conditions.
In the case where it is possible to cope with all the operating characteristics only by the amount of change in magnetization of the second permanent magnet, the first permanent magnet is unnecessary.
The rotation axis of the drum 4 may have an inclination of about 10 to 15 degrees in the elevation direction with respect to the horizontal.
You may apply to the washing machine which does not have a drying function. Moreover, you may apply to the vertical washing machine which stirs a water flow using a pulsator.

  In the drawings, 4 is a rotating drum (rotating tank), 11 is a drum motor (permanent magnet motor), 30 is a control circuit (magnetization amount control means, weight detection means), 32 is an inverter circuit (magnetization amount control means), Reference numeral 92 denotes a rotor, and 97 denotes an alnico magnet (permanent magnet).

Claims (7)

A permanent magnet motor configured to include a permanent magnet having a coercive force at a level at which the amount of magnetization can be easily changed on the rotor side, and generating a rotational driving force for performing a washing operation;
A magnetization amount control means for generating an exciting current so as to change the magnetization amount of the permanent magnet;
A weight detection means for detecting the weight of the laundry put in the rotating tub,
The magnetization amount control means includes:
The amount of magnetization of the permanent magnet is set according to the dry cloth weight detected before the first water supply is performed in the rotary tub by the weight detection means,
When the laundry weight the first water supply is estimated from the fabric weight of the sensed water condition (water absorption fabric weight) after performed it is determined to heavier than the dry cloth weight, increasing the magnetizing amount of the permanent magnet A washing machine characterized by letting A permanent magnet motor configured to include a permanent magnet having a coercive force at a level at which the amount of magnetization can be easily changed on the rotor side, and generating a rotational driving force for performing a washing operation;
A magnetization amount control means for generating an exciting current so as to change the magnetization amount of the permanent magnet;
A weight detection means for detecting the weight of the laundry put in the rotating tub,
The magnetization amount control means includes:
The amount of magnetization of the permanent magnet is set according to the dry cloth weight detected before the first water supply is performed in the rotary tub by the weight detection means,
If it is determined that the weight of the laundry estimated from the weight of the water-absorbing cloth (water-absorbing cloth weight) detected after the first water supply is performed is smaller than the weight of the dry cloth, the amount of magnetization of the permanent magnet is reduced. A washing machine characterized by letting When the weight detection means detects at least the weight of the absorbent cloth, when the motor is rotated at a constant rotation speed and then is idled , the weight detection means has a magnitude of an induced voltage generated in the winding of the motor. 3. The washing machine according to claim 1, wherein detection is performed based on the washing machine. The washing according to any one of claims 1 to 3, wherein the weight detection means detects the weight of the water absorbent cloth at a time when a predetermined time has elapsed after the start of the washing operation in the washing operation. Machine. The magnetizing amount control means changes the magnetizing amount of the permanent magnet according to the determined cloth quality when the cloth quality of the laundry is determined during the washing operation. The washing machine according to any one of 1 to 4 . Before Symbol weight detection means detects the water absorption fabric weight before the interim dehydrating is conducted in the rinse operation,
The magnetizing amount control means increases the magnetizing amount of the permanent magnet when the water absorbing cloth weight is determined to be heavier than the water absorbing cloth weight detected in the washing operation, and the water absorbing cloth weight is detected in the washing operation. 5. The washing machine according to claim 4, wherein when it is determined that the weight is lighter than the weight of the water absorbent cloth, the amount of magnetization of the permanent magnet is reduced . It has a function to perform drying operation,
The weight detection means intermittently detects the water absorbent cloth weight a plurality of times during the drying operation,
The magnetizing amount control means reduces the magnetizing amount of the permanent magnet when determining that the latest absorbent cloth weight is lighter than the previously detected absorbent cloth weight. A washing machine according to claim 1.

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