JP6071479B2 - Washing and drying machine - Google Patents

Description

  Embodiments described herein relate generally to a washing dryer.

  Conventional washing / drying machines that perform washing, rinsing, dehydration, and drying processes do not use an electric heater as a drying means, and use a heat pump that saves wrinkles and shrinkage of clothes, saves energy, and shortens drying time. There is a machine. In this type of washing machine, when the washing operation is started, the weight of the clothes (dry cloth weight) is detected before the washing process, and the end time of the washing / drying operation is predicted and displayed. In this case, the predicted end time of the washing / drying machine is estimated as the total time of the time required for the washing process, the time required for the rinsing process, the time required for the dehydration process, and the time required for the drying process. The estimated time required for the drying process is a reference time required for the dryness of the clothes to reach a predetermined target dryness set in advance according to the weight of the clothes as a dry load.

  In this case, the weight of clothing used for predicting the time required for the drying process is the weight of the clothes in the dry cloth state. However, when the washing process is performed from the washing process to the dehydration process, the dehydration rate in the dehydration process is known. Since the amount of moisture corresponding to the clothing weight (the amount of moisture corresponding to the weight of the dry clothing) is known in advance, the time required for the drying process can be predicted from the clothing weight in the dry clothing state.

  By the way, the clothes to be washed and dried are usually clothes in a dry cloth state at the start, but in some cases, washing and drying may be started from wet clothes. In the case of this wet clothing, the moisture weight is excessively heavy, so the estimated time required for the drying process (and thus the estimated end time of the washing and drying operation) is predicted to be longer than the appropriate time, and the drying process is initially performed. If it is executed with the estimated required time, the actual washing / drying end time and the predicted end time are shifted. Such a problem also occurs when clothes are added or removed after the weight of the clothes (dry cloth weight) is detected.

Japanese Patent Laid-Open No. 11-146999

  In view of the above, a laundry dryer capable of controlling the time required for the drying process according to the weight of clothes as a drying load and adjusting the time required for the entire washing and drying operation is provided.

The washing / drying machine according to the embodiment is a washing / drying machine that performs each process of washing, rinsing, dehydration, and drying, a water tub having an exhaust port and an air supply port, and a clothes rotatively provided in the water tub to wash and rinse clothes and a rotatable tub for accommodating therein for drying, and air circulation passage is provided outside the tub connecting said exhaust port and the air inlet, the air in the air circulation path is provided in the air circulation duct A heat pump unit having an evaporator for dehumidification, a condenser provided on the downstream side of the evaporator in the circulation air passage, for heating air in the circulation air passage, and a compressor for supplying refrigerant to the condenser; provided in the air circulation duct, a blower constituting the drying means in the dehumidification and the heated air by being supplied the heat pump unit is supplied to the water tank from the air inlet the pump unit from the exhaust port Drying clothes weight detecting means for detecting the weight of the clothes at the end of the dehydration process, and drying capacity setting capable of setting the drying capacity of the drying means according to the clothes weight detected by the drying clothes weight detecting means Means.

Schematic longitudinal side view of the washing and drying machine according to the first embodiment Schematic longitudinal rear view of the washer / dryer Schematic configuration diagram of drying equipment Functional configuration block diagram Illustration for explaining the stored contents Flow chart showing control contents of control device Flow chart showing control contents of compressor rotation speed setting FIG. 7 equivalent diagram according to the second embodiment Illustration for explaining the stored contents FIG. 7 equivalent diagram according to the third embodiment Illustration for explaining the stored contents Functional configuration block diagram according to the fourth embodiment Flow chart showing control contents of compressor rotation speed setting Illustration for explaining the stored contents Functional configuration block diagram according to the fifth embodiment Flow chart showing control contents of control device Flow chart showing control contents of compressor rotation speed setting Illustration for explaining the stored contents The flowchart which shows the control content of the control apparatus by 6th Embodiment. Flow chart showing contents of compressor start timing setting Illustration for explaining the stored contents Block diagram of functional configuration according to seventh embodiment Flow chart showing control contents of control device Flow chart showing control contents of control temperature setting Illustration for explaining the stored contents Functional configuration block diagram according to the eighth embodiment Flow chart showing control contents of control device Flow chart showing control contents of control temperature setting Illustration for explaining the stored contents The block diagram of the functional structure by 9th Embodiment Flow chart showing control contents of control device Flow chart showing control contents of control temperature setting Illustration for explaining the stored contents (A) is a figure for demonstrating the memory content by 10th Embodiment, (b) is a figure for demonstrating the memory content by 11th Embodiment, (c) demonstrates the memory content by 12th Embodiment. Illustration for (A) is a figure for demonstrating the memory content by 13th Embodiment, (b) is a figure for demonstrating the memory content by 14th Embodiment, (c) demonstrates the memory content by 15th Embodiment. Illustration for (A) is a figure for demonstrating the memory content by 16th Embodiment, (b) is a figure for demonstrating the memory content by 17th Embodiment, (c) demonstrates the memory content by 18th Embodiment. Illustration for The flowchart which shows the control content of the control apparatus by 19th Embodiment. Illustration for explaining the stored contents Functional configuration block diagram according to the twentieth embodiment Flow chart showing control contents of control device Figure for explaining the stored contents (Part 1) Figure for explaining the stored contents (Part 2) Figure for explaining the contents of memory (Part 3) Functional configuration block diagram according to the twenty-first embodiment Illustration for explaining the stored contents Functional configuration block diagram according to the twenty-second embodiment Illustration for explaining the stored contents Functional configuration block diagram according to the twenty-third embodiment. Flow chart showing control contents of control device Figure for explaining the stored contents (Part 1) Figure for explaining the stored contents (Part 2) Figure for explaining the contents of memory (Part 3) Functional configuration block diagram according to the twenty-fourth embodiment Flow chart showing control contents of control device Figure for explaining the stored contents (Part 1) Figure for explaining the stored contents (Part 2) Figure for explaining the contents of memory (Part 3) Functional configuration block diagram according to the twenty-fifth embodiment Flow chart showing control contents of control device Figure for explaining the stored contents (Part 1) Figure for explaining the stored contents (Part 2) Figure for explaining the contents of memory (Part 3) (A) is a figure for demonstrating the memory content by 26th Embodiment, (b) is a figure for demonstrating the memory content by 27th Embodiment. (A) is a figure for demonstrating the memory content by 28th Embodiment, (b) is a figure for demonstrating the memory content by 29th Embodiment. (A) is a figure for demonstrating the memory content by 30th Embodiment, (b) is a figure for demonstrating the memory content by 31st Embodiment. The figure for demonstrating the memory content by 32nd Embodiment Flow chart showing control contents of control device Flow chart showing control content of blower rotation speed setting The flowchart which shows the control content of the fan rotation speed setting by 33rd Embodiment. Illustration for explaining the stored contents

Hereinafter, a washing and drying machine according to a plurality of embodiments will be described with reference to the drawings. In addition, in each embodiment, the same code | symbol is attached | subjected to the substantially same component, and description is abbreviate | omitted.
(First embodiment)
First, a first embodiment will be described with reference to FIGS.
As shown in FIG. 1, the washing / drying machine 10 includes an outer box 11, a water tank 12, a rotating tank 13, a motor 14, and a door 15. In the present embodiment, the door 15 side with respect to the outer box 11 is the front side of the washing / drying machine 10. The washing / drying machine 10 has a washing function and a heat pump type drying function. The washing / drying machine 10 is a so-called drum-type washing / drying machine in which the rotation axis of the rotary tub 13 is inclined with respect to the installation surface.

  In the present embodiment, the washing / drying machine 10 includes, as main processes, a washing process of washing clothes, a rinsing process of rinsing detergent-washed clothes, and a dehydration process of dehydrating wet clothes after the washing process. And a drying step of drying the clothes after the dehydration step. And in this washing / drying machine 10, although each process can also be performed independently, it is also possible to perform each process in series. The user can select an arbitrary operation from among a washing operation, a drying operation, and a washing / drying operation.

  The outer box 11 is formed in a substantially rectangular box shape by a steel plate or the like. The water tank 12 is accommodated in the outer box 11 and functions as an outer tank. The rotating tank 13 is accommodated in the water tank 12 and functions as an inner tank. The water tank 12 and the rotary tank 13 function as a drying chamber for storing clothes and also serve as a washing tank. That is, the water tub 12 and the rotating tub 13 constituting the washing tub / drying chamber function as a washing tub during the washing process, and function as a drying chamber during the drying process.

  Both the water tank 12 and the rotating tank 13 are formed in a cylindrical shape. The water tank 12 has an opening 121 at one end of a cylindrical shape, and a water tank end plate 122 at the other end. The opening 121 is located above the water tank end plate 122 in the inclined water tank 12. Similarly, the rotating tank 13 has an opening 131 formed at one end of a cylindrical shape, and a rotating tank end plate 132 provided at the other end. The opening 131 is located above the rotating tank end plate 132 in the inclined rotating tank 13. The opening 131 of the rotating tank 13 is covered with the opening 121 of the water tank 12.

  The water tank 12 has an exhaust port 16 and an air supply port 17. The exhaust port 16 is provided in the upper front portion of the peripheral wall constituting the cylindrical portion of the water tank 12. The air supply port 17 is in the water tank end plate 122 and is provided at a portion slightly above the center of the water tank end plate 122. The exhaust port 16 and the air supply port 17 communicate the inside and the outside of the water tank 12.

  Moreover, the water tank 12 has the drainage part 18 in the rear-end side of the bottom part located under the gravity direction. The drainage unit 18 is located below the exhaust port 16 and the air supply port 17. The drainage unit 18 includes a drainage port 123, a drainage valve 19, and a drainage hose 20. By opening the drain valve 19, the water in the water tank 12 is discharged from the drain port 123 to the outside of the washing / drying machine 10 via the drain valve 19 and the drain hose 20.

  The rotary tank 13 has a plurality of holes 21 and a plurality of communication ports 22. The hole 21 and the communication port 22 communicate the inside and the outside of the rotary tank 13. The hole 21 is formed in the whole area of the peripheral wall which comprises the cylindrical cylindrical part of the rotating tank 13. As shown in FIG. The communication port 22 is formed in the entire area of the rotary tank end plate 132. The hole 21 and the communication port 22 function as water holes through which water mainly enters and exits during the washing process and the dewatering process, and function as air holes through which air enters and exits during the drying process. In FIG. 1, only a part of the plurality of holes 21 and the communication ports 22 is shown for simplicity. Further, although not shown in detail, the rotating tub 13 is provided with a plurality of baffles inside the cylindrical portion. The baffle stirs the laundry stored inside the rotating tub 13.

  The motor 14 is provided on the water tank end plate 122 outside the water tank 12. The motor 14 is, for example, an outer rotor type DC brushless motor. The shaft portion 141 of the motor 14 passes through the water tank end plate 122 and protrudes to the inside of the water tank 12, and is fixed to the center portion of the rotary tank end plate 132. Thereby, the motor 14 rotates the rotation tank 13 relatively with respect to the water tank 12. In this case, the shaft portion 141, the rotation axis of the rotating tub 13, and the central axis of the water tub 12 coincide with each other.

  The door 15 is provided on the outer surface side of the outer box 11 via a hinge (not shown). The door 15 rotates about a hinge as a fulcrum, and opens and closes an opening (not shown) formed on the front surface of the outer box 11. The opening formed in the outer box 11 is connected to the opening 121 of the water tank 12 by a bellows 112. Laundry such as clothes is put into and out of the rotating tub 13 through the openings 121 and 131 with the door 15 opened.

An operation panel 24 is provided on the front upper portion of the outer box 11 and includes a display unit 24a and an operation unit 24b shown in FIG.
The washing / drying machine 10 includes the control device 23 shown in FIG. 3, the display unit 24a, the operation unit 24b, and the water supply device 25 shown in FIG. Although not shown in detail, the control device 23 is composed of a microcomputer or the like, and controls the overall operation of the washing / drying machine 10. The display unit 24a and the operation unit 24b are connected to the control device 23 as shown in FIG. The display unit 24a is configured by a liquid crystal display panel or the like, and displays various setting items, operation details, a predicted end time described later, and the like. The operation unit 24b includes various keys, and the user performs various settings such as selection of a driving course by operating the operation unit 24b.

  As shown in FIG. 2, the water supply device 25 includes a water supply case 26, a water supply valve 27, a water supply hose 28, and the like. The water supply valve 27 is connected to the control device 23 and is opened and closed under the control of the control device 23. One end of the water supply hose 28 is connected to the water supply valve 27 and the other end is connected to an external water source such as a water supply. The control device 23 opens and closes the water supply valve 27 to supply water from the water source into the water tank 12 through the water supply hose 28, the water supply valve 27, and the water supply case 26.

  The washing / drying machine 10 includes a circulation air passage 30 as shown in FIG. The circulation air passage 30 connects the exhaust port 16 and the air supply port 17 outside the water tank 12. Specifically, the circulation air passage 30 includes an exhaust duct 31, a filter device 32, a connection duct 33, a heat exchange unit 34, and an air supply duct 35.

  As shown in FIG. 1, the exhaust duct 31 connects the exhaust port 16 of the water tank 12 and the filter device 32. The exhaust duct 31 is composed of, for example, a bellows-like hose. The filter device 32 is provided inside the outer box 11 and above the water tank 12 and the rotary tank 13. A filter 321 is provided in the filter device 32. When the air exhausted from the exhaust port 16 passes through the filter 321 of the filter device 32, foreign matters such as lint are removed.

  The filter device 32 is connected to the upstream side of the heat exchanging section 34 via the connection duct 33. The heat exchanging part 34 is provided in the lower part inside the outer box 11 and below the filter device 32, the water tank 12, and the rotating tank 13. The heat exchanging unit 34 generates dry hot air by dehumidifying and heating the air passing through the inside. An evaporator 36 and a condenser 37 are provided in the heat exchange unit 34. The evaporator 36 is provided on the upstream side of the condenser 37 with respect to the air flow in the heat exchange unit 34 during the drying operation. The evaporator 36 and the condenser 37 constitute a heat pump unit 40 together with a compressor 38 and a decompression device 39 provided outside the heat exchange unit 34. The air passing through the heat exchange section 34 is cooled by the evaporator 36 and dehumidified thereby. The air dehumidified by the evaporator 36 is then heated by the condenser 37 to become warm air.

  The heat pump unit 40 is configured by connecting a condenser 37, a decompression device 39, and an evaporator 36 in order with respect to the refrigerant flow direction with respect to the compressor 38. The evaporator 36 and the condenser 37 are constituted by, for example, a pipe having a large number of fins provided at minute intervals. By flowing the refrigerant through the pipe, heat between the air passing between the fins and the refrigerant is obtained. Exchange. The evaporator 36 and the condenser 37 function as a heat exchanger.

  The compressor 38 supplies the refrigerant to the condenser 37 by pressure feeding. The compressor 38 is connected to the control device 23 and is driven by the control of the control device 23. The compressor 38 is configured such that the drive rotational speed of the compressor 38 can be changed by inverter control, for example. The control device 23 changes the supply pressure of the refrigerant discharged from the compressor 38 by changing the driving rotational speed of the compressor 38, thereby changing the heating capacity of the condenser 37 and the cooling capacity of the evaporator 36. Let The decompression device 39 decompresses the high-pressure liquid refrigerant discharged from the condenser 37 to make a low-pressure gas-liquid mixed state. The decompression device 39 is constituted by, for example, a so-called electric expansion valve capable of adjusting the throttle opening degree under the control of the control device 23.

  The downstream side of the heat exchange unit 34 is connected to the air supply port 17 of the water tank 12 through the air supply duct 35. A blower 41 is provided at a connection portion between the heat exchange unit 34 and the air supply duct 35. The blower 41 and the heat pump unit 40 constitute a drying device 42 corresponding to a drying means. The blower 41 is constituted by, for example, a sirocco fan. The blower 41 is configured to be able to change the rotation speed under the control of the control device 23. The blower 41 sucks the air in the heat exchange unit 34 and discharges it to the air supply duct 35 side. Thereby, the flow of the air which circulates through the water tank 12 and the circulation air path 30 arises as shown by the arrow of FIG.1, FIG2 and FIG.3. In this case, when the air flow in the circulation air passage 30 is viewed, the exhaust port 16 is on the most upstream side, and the air supply port 17 is on the most downstream side.

  In this configuration, when the compressor 38 and the blower 41 are driven for the drying operation, the warm air dehumidified and heated in the heat exchanging section 34 is supplied via the supply duct 35 by the blowing action of the blower 41. It is supplied into the water tank 12 from the air port 17. Thereafter, the warm air mainly enters the rotary tub 13 from the communication port 22, deprives moisture from the laundry in the rotary tub 13, and then mainly exits from the hole 21 to the outside of the rotary tub 13. The air containing moisture is sucked into the circulation air passage 30 from the exhaust port 16. The air sucked into the circulation air passage 30 first passes through the exhaust duct 31 and the filter device 32. At this time, the lint that comes out of the clothes and is contained in the air is collected by the filter 321 provided in the filter device 32. Thereafter, it flows to the heat exchanging section 34 through the connection duct 33. Thus, in the drying process, when the drying device 42 including the heat pump unit 40 and the blower 41 is operated, air is circulated between the water tank 12 and the circulation air passage 30, and the air is circulated in the circulation air passage 30. This is done by dehumidification and heating.

  In addition, a current sensor 43 is connected to the control device 23, and the current sensor 43 detects a current flowing through the motor 14. The control device 23 is provided with a drying garment weight detecting means 44 for detecting the weight of the garment at the end of the dehydration process by software configuration, and also detects the garment weight for time prediction for detecting the weight of the garment before the start of the washing process. Means 45 is provided by software configuration.

In addition, the control device 23 includes a drying capacity setting unit 46 and an end time prediction unit 50 by software configuration.
Further, the control device 23 includes a nonvolatile memory 47 (storage means) composed of an EEPROM, a flash memory, a ROM, and the like. The nonvolatile memory 47 includes a time required for a drying process, a clothing weight, and a drying capacity, for example. The relationship with the rotation speed of the compressor 38 is stored as data. The data contents are schematically shown in FIG.

  In FIG. 5, lines L1, L2, L3, and L4 indicate the rotation speed of the compressor 38 when the weight Wk of the dry-clothed clothes is W1, W2, W3, and W4 (W1 <W2 <W3 <W4), respectively. And the time required for the drying process. Here, the time required for the drying process is the degree of dryness from the start of the drying process when clothing having an arbitrary weight Wk is dried at the rotational speed of the arbitrary compressor 38 (the rotational speed of the blower 41 is constant). Is the time until the dryness reaches the preset dry end criterion.

  In FIG. 5, for example, when the clothing weight Wk is the weight W2 (line L2), if the rotation speed of the compressor 38 is Pa, the required time is ta. Conversely, when the clothing weight Wk is the weight W2, the rotational speed of the compressor 38 is set to Pa in order to set the required time to ta.

Such a relationship between the rotation speed of the compressor 38 and the required time for each clothing weight Wk is stored in the nonvolatile memory 47 as data. In addition, this FIG. 5 is a figure for showing the correlation of required time, compressor rotation speed, and clothing weight in an easy-to-understand manner for convenience, and is not necessarily a linear relationship. The same applies to FIG. 38 described later.
Further, a motor rotation sensor 48 that detects the rotation speed of the motor 14 is connected to the control device 23, and a water level sensor 49 that detects the water level in the water tank 12 is also connected.
Now, the control contents of the control device 23 will be described with reference to FIG.

  When the user accommodates the clothes in the rotating tub 13 and selects a washing / drying operation which is a fully automatic course (a course in which washing, rinsing, dehydration and drying are performed in series), in step R10, The clothing weight detecting means 45 for predicting time detects the weight of the clothing. The time predicting clothing weight detecting means 45 rotates the motor 14 to a predetermined rotational speed and detects the weight of the clothing based on the current detected by the current sensor 43 (current corresponding to the load). This detected weight is referred to as an initial detected weight and is set to Wa [kg]. In this case, the user normally detects the weight of the dry-clothed clothing since the dry-clothed clothing is accommodated and starts washing and drying, but some users seem to have pre-washed in another place. May contain wet clothing.

  In the next step R20, a required time TA from the end of the washing / drying operation (from the start of the washing process to the end of the drying process) is predicted based on the initial detected weight Wa (end time predicting means 50), and this prediction is completed on the display unit 24a. Display time TA. The predicted end time TA includes a predicted required time TB for the washing process, an estimated required time TC for the rinse process, an estimated required time TD for the dehydration process, and an estimated required time TE for the drying process. These predicted times are predicted under the condition that the initial detected weight Wa is the weight in the dry cloth state. The predicted required time TE of the drying process is such that the rotational speed of the blower 41 is set to a predetermined rotational speed (reference rotational speed, for example, 4300 rpm), and the compressor 38 is also set to a predetermined rotational speed (reference rotational speed, for example, 60 rpm). It is set according to the initial detected weight Wa when the drying operation is executed under the drying capacity condition.

  In the next step R30, a soft timer is started. In the next step R40, the washing process is executed in the estimated required time TB. In this washing process, an operation of supplying water into the water tank 2 from the water supply valve 27 through the water supply case 26 (detergent is automatically added at the initial stage of water supply) is performed. Subsequently, when the motor 14 is operated, the rotating tank 13 is alternately rotated in both forward and reverse directions at a low speed.

In the next step R50, the rinsing process is performed for the estimated required time TC. In this rinsing process, an intermediate dehydration process (dehydration process for removing detergent) is performed by first draining and rotating the rotating tank 13 in one direction at a high speed, and then supplying water to the rotating tank 13 at a low speed. Rinsing is performed to rotate. This rinsing process may be performed a plurality of times.
In the next step R60, the dehydration process is executed for the estimated required time TD. In this dehydration process, after the water in the water tank 2 is discharged, an operation of rotating the rotary tank 13 in one direction at a high speed (a predetermined rotation speed, for example, 1400 rpm) is performed. Thereby, the clothes in the rotating tub 13 are centrifugally dehydrated.

In this dehydration process, since the rotation speed (dehydration rotation speed) of the rotating tub 13 is previously determined to be a constant rotation speed (1400 rpm) as described above, the dehydration rate of the clothes is substantially constant.
In the next step R70, the clothes weight detecting means 44 for drying detects the weight of clothes (cloth weight in terms of dry cloth) Wk (this is referred to as detected weight Wk after dehydration). That is, according to the detection result from the current sensor 43, first, the weight of the entire container including the moisture weight and the clothing weight (referred to as Wb) is detected, and the clothing weight (the clothing equivalent to the dry cloth) is detected from the detected weight Wb. Of weight). In this case, since the dehydration rotation speed is controlled to be a constant rotation speed as described above, the moisture weight ratio with respect to the detected weight Wb is constant. At this time, if the moisture weight ratio (moisture weight / (dry cloth weight + moisture weight)) is d [%], the detected weight after dehydration (cloth weight in terms of dry cloth) Wk excluding the moisture weight is
Wk = Wb−Wb × d [kg] (1)
(Weight Wk is detected).

In the next step R80, the rotation speed of the compressor 38, which is one of the drying capacities, is set.
The contents of step R80 are shown in FIG. In FIG. 7, in step S10, the time required for the drying process is calculated. That is, the remaining time tx is obtained by subtracting the elapsed time (this is referred to as ts) from the predicted end time TA of the washing and drying operation.

tx = TA-ts (2)
This remaining time tx is the time required for the drying process. That is, if the drying process is finished at the required time tx, the washing and drying operation is finished at the predicted end time TA. If the washing process, the rinsing process, and the dehydrating process of the washing and drying operation have no time lag and proceed with the originally estimated required times TB, TC, and TD, the required time tx is the estimated required time TE of the drying process. Will be the same. Therefore, when there is almost no time lag, the estimated required time TE may be used without calculating the required time tx.

  In the next step S20, based on the data shown in FIG. 5, the number of rotations of the compressor 38 at which the time required for the drying process is tx is set based on the detected clothing weight Wk. For example, in FIG. 5, when the post-dehydration detected weight Wk is Wx, the rotational speed Px of the compressor 38 for setting the required time to tx is obtained and set. Thereafter, the process returns to Step R90 in FIG.

  In step R90, the drying process is started. This drying process does the following: The rotating tub 13 is rotated in both forward and reverse directions at a low speed, the compressor 38 is driven at the set rotational speed Px, and the blower 41 is driven at a predetermined rotational speed, for example, 4300 rpm. Accordingly, as described above, the drying device 42 including the heat pump unit 40 and the blower 41 is operated, whereby air is circulated between the water tank 12 and the circulation air passage 30, and the air is circulated in the circulation air passage 30. This is done by dehumidification and heating.

In this case, since the rotation speed of the compressor 38 is the set rotation speed Px, the dryness approaches the dryness of the drying end reference as the elapsed time approaches the time tx.
When it is determined in step R100 that the elapsed time has reached the time tx, the operation of the drying device 42 is stopped in step R110, and the drying process is ended. At this time, the dryness is the dryness standard dryness.

  According to such an embodiment, since the drying capacity setting means 46 capable of setting the rotation speed of the compressor 38, which is one of the drying capacities, is provided, if the rotation speed of the compressor 38 is set high, the drying process is performed. The required time can be shortened, and if the rotation speed of the compressor 38 is set low, the required time for the drying process can be increased. That is, the time required for the drying process can be controlled by setting the rotation speed of the compressor 38.

  Furthermore, according to this embodiment, the weight Wk of the garment is detected by the drying garment weight detecting means 44 at the end of the dehydration process, and the drying capacity setting means 46 is a compression that has a drying capacity according to the detected garment weight Wk. Since the rotation speed of the machine 38 is set, the time required for the drying process can be controlled according to the weight Wk of the clothes. Therefore, even if the initial detected weight Wa is the weight of wet clothing, or even when clothing is additionally charged or taken out after obtaining the initial detected weight Wa, the drying process is performed according to the detected weight Wk after dehydration. Time required can be controlled. Since the time required for the drying process can be controlled in this way, the required time is adjusted so that the drying process is completed at the initially set predicted end time by setting the rotation speed of the compressor 38 (setting the drying capacity). it can.

(Second Embodiment)
8 to 9 show a second embodiment. In the second embodiment, the control content of the drying capacity setting means 46 is different from that of the first embodiment. Further, the data stored in the nonvolatile memory 47 is different from that of the first embodiment.
As shown in FIG. 9, the data stored in the non-volatile memory 47 includes an initial detected weight Wa detected by the time-predicting clothing weight detecting means 45 and a post-dehydration detected weight detected by the drying clothing weight detecting means 44. This is data in which a difference ΔW (ΔW = Wk−Wa) with respect to Wk is related to, for example, the rotational speed of the compressor 38, which is a drying capacity.

In addition, the estimated required time TE of the drying process is a drying in which the rotation speed of the blower 41 is set to a predetermined rotation speed (reference rotation speed, for example, 4300 rpm) and the compressor 38 is also set to a predetermined rotation speed (reference rotation speed, for example, 60 rpm) This is set according to the initial detected weight Wa when the drying operation is executed under the capacity condition.
As shown in FIG. 8 (corresponding to FIG. 7), the drying capacity setting means 46 determines the time prediction clothing weight detection means 45 from the post-dehydration detected weight Wk detected by the drying clothing weight detection means 44 in step SA10. The difference ΔW is calculated by subtracting the initial detected weight Wa detected by the above.

ΔW = Wk-Wa
Note that the unit of clothing weight detected by the clothing weight detecting means 45 for predicting time and the clothing weight detecting means 44 for drying is “kg”, and the detected weight is a positive integer. That is, the detected weight is indicated by 1 kg, 2 kg, 3 kg,. Further, it is considered that the difference ΔW hardly deviates from ± 3 kg in actual use. Therefore, the difference ΔW is substantially 0 kg, +2 kg, +1 kg, −1 kg, or −2 kg.

  In step SA20, the drying capacity, in this case, the number of rotations of the compressor 38 is set so that the drying process is completed in the required time according to the difference ΔW. That is, as can be seen from FIG. 9, when ΔW is 0 [kg] (no increase or decrease in weight), the rotation speed of the compressor 38 is set to 60 rpm (reference rotation speed). When ΔW is +1 kg and +2 kg (the detected weight Wk after dehydration is increased with respect to the initial detected weight Wa), the rotation speed of the compressor 38 is set to 65 rpm and 70 rpm, respectively (increased with respect to the reference rotation speed). ) When ΔW is negative (the detected weight Wk after dehydration is reduced with respect to the initial detected weight Wa), the rotational speed of the compressor 38 is set to be decreased with respect to the reference rotational speed according to the negative degree. ing.

  The fact that the difference ΔW is in the negative direction (the detected weight Wk after dehydration is reduced with respect to the initial detected weight Wa) means that the initial detected weight Wa may be a wet cloth or a part of clothing is taken out halfway. The estimated required time TE of the drying process is set to be long with respect to the weight of clothes in the dry cloth state after dehydration. That is, the estimated required time TE is set longer by a difference ΔW (1 kg to 2 kg) equivalent to the actual dry cloth weight after dehydration, and the initial predicted end time TA is also set longer by that amount. Become.

  Therefore, as described above, according to the second embodiment, when the difference ΔW is in the negative direction, the rotation speed of the compressor 38, which is the drying capacity, is set to the reference rotation speed of 60 rpm according to the weight difference ΔW. Set the direction to lower. That is, since the rotation speed of the compressor 38 is set so that the required time for the drying process matches the estimated required time TE, in other words, the compressor 38 is configured so that the drying process is completed at the initial predicted end time TA. Since the rotation speed is set, the washing / drying operation can be ended at the initial predicted end time TA.

  Further, when clothing is additionally put in after obtaining the initial detected weight Wa, the weight difference ΔW becomes positive (the post-dehydration detected weight Wk increases with respect to the initial detected weight Wa). In this case, if the rotation speed of the compressor 38 remains at the original reference value, the actual time required for the drying process exceeds the estimated required time TE.

In this regard, according to the above-described embodiment, when the weight difference ΔW is in the plus direction, the direction in which the rotation speed of the compressor 38 is increased (in order to increase the drying capacity) in order to control in a direction to shorten the time required for the drying process. In other words, since the rotation speed of the compressor 38 is set so that the drying process is completed at the initial predicted end time TA, the washing / drying operation can be ended at the initial predicted end time TA.
Note that the set rotational speed of the compressor 38 described above may be constant from the beginning (at the time of startup) to the end of the drying process, or may be the average rotational speed. Therefore, at the start of the drying process, the rotation speed may be set to a set value and slightly varied in the middle.

(Third embodiment)
10 and 11 show a third embodiment. In this third embodiment, the control content of the drying capacity setting means 46 is different from that of the second embodiment. The data stored in the nonvolatile memory 47 is different from that of the second embodiment.

  As shown in FIG. 11, the data stored in the nonvolatile memory 47 stores data for adjusting the rotation speed of the compressor 38 set according to the difference ΔW according to the post-dehydration detected weight Wk. The post-dehydration detected weight Wk for adjustment is divided into three categories of 2 kg or less, 2 kg or more to 4 kg or less, and 4 kg or more.

  As shown in FIG. 10, the drying capacity setting means 46 is different in step SB20 from step SA20 in FIG. In this step SB20, the rotation speed of the compressor 38 set according to the difference ΔW is adjusted based on the weight classification of the post-dehydration detected weight Wk based on the data stored in the nonvolatile memory 47. For example, when the difference ΔW is −1 kg, it is set to 55 rpm for a standard post-dehydration detected weight Wk (more than 2 kg to 4 kg or less in terms of weight category), but 45 rpm if the difference ΔW is 2 kg or less. In the case of more than 4 kg, it is adjusted to 65 rpm.

  In the third embodiment, the following points are taken into consideration. That is, even when the difference ΔW shows the same value, the case where the weight of the garment is large and the case where the weight is small are different in the amount of drying load, so the time required for the drying process is slightly different ( The latter case is slightly shorter than the former case. To cope with this, the compressor 38 is used in the case where the weight of the clothes is large even when the difference ΔW shows the same value. In the case where the weight of the clothes is small, the rotation speed of the compressor 38 is adjusted to be low.

In the third embodiment, since the rotation speed of the compressor 38 is adjusted according to the weight of the clothes, the washing / drying operation can be completed more accurately with the initial predicted end time TA.
(Fourth embodiment)
12 to 14 show a fourth embodiment. The fourth embodiment is different from the third embodiment in that an ambient temperature sensor 51 is provided as an ambient temperature detection unit, and the control content of the drying capacity setting unit 46 is different. The data stored in the nonvolatile memory 47 is different from that in the third embodiment.

The ambient temperature sensor 51 is provided so as to detect the ambient temperature inside the outer box 11. The ambient temperature sensor 51 may detect room temperature.
As shown in FIG. 14, the data stored in the nonvolatile memory 47 stores data for adjusting the rotation speed of the compressor 38 set according to the difference ΔW according to the ambient temperature. The ambient temperature for use is divided into three categories of 10 ° C. or lower, 10 ° C. to 20 ° C. or lower, and 20 ° C. or higher.

  As shown in FIG. 13, the drying capacity setting means 46 acquires the ambient temperature detected by the ambient temperature sensor 51 in step SC20 following step SA10, and in the next step SC30, the compressor is set according to the difference ΔW. The number of rotations of 38 is adjusted by the above temperature category of the detected ambient temperature based on the data stored in the nonvolatile memory 47. For example, when the difference ΔW is −1 kg, it is set to 55 rpm for a standard atmospheric temperature (over 10 ° C. to 20 ° C. in terms of temperature category). Also, when the temperature exceeds 20 ° C., the speed is adjusted to 45 rpm.

  In the fourth embodiment, the following points are considered. That is, when the atmospheric temperature is high, the temperatures of the compressor 38, the condenser 37, and the evaporator 36 are high, that is, the temperature of the entire heat pump unit 40 is high and the drying capacity is also high. Further, when the atmospheric temperature is lowered, the drying capacity of the entire heat pump unit 40 is also lowered. In consideration of this, the drying capability of the drying device 42 is appropriately adjusted by adjusting the rotation speed of the compressor 38 according to the ambient temperature. In the fourth embodiment, the same effects as in the third embodiment are obtained.

(Fifth embodiment)
15 to 18 show a fifth embodiment, which differs from the fourth embodiment in the following points. That is, the ambient temperature sensor 51 is not provided, and the control device 23 is provided with the cloth quality detection means 52. Further, the control contents of the drying capacity setting means 46 and the data stored in the nonvolatile memory 47 are different.
As shown in FIG. 18, the data stored in the nonvolatile memory 47 stores data for adjusting the rotational speed of the compressor 38 set according to the difference ΔW according to the fabric quality. The cloth quality is classified into three categories: more than 60% cotton (residual fiber) to 100%, more than 30% to 60% cotton, and more than 0% to 30% cotton.

  The cloth quality detection means 52 in the control device 23 detects the cloth quality of the clothing in step R25 following step R20 in FIG. That is, the torque fluctuation of the motor 14 is detected by the fluctuation of the current detected by the current sensor 43 in a state where water of a predetermined water level is put in the water tank 12, and the larger the magnitude of the torque fluctuation (the fluctuation width and the average value), the larger the cloth. It is judged that the ratio of cotton is high (the ratio of synthetic fibers is low) and the ratio of cotton is low as the quality is small (detected).

  As shown in FIG. 17, the drying capacity setting means 46 determines the rotation speed of the compressor 38 set according to the difference ΔW in step SE20 following step SA10 based on the data stored in the nonvolatile memory 47. Adjust by. For example, when the difference ΔW is −1 kg, it is set to 55 rpm for a standard cloth quality (more than 30% cotton to 60% or less in terms of cloth quality), but more than 60% cotton to 100%. %, The speed is adjusted to 65 rpm, and when the cotton content is 0% to 30%, the speed is adjusted to 45 rpm.

  In the fifth embodiment, the following points are taken into consideration. That is, if the ratio of cotton is large, it is difficult to dry and requires a large drying capacity, and if the ratio of cotton is small, it is easy to dry and does not require a large drying capacity. In consideration of this, the drying capacity of the drying device 42 is appropriately adjusted by adjusting the rotation speed of the compressor 38 according to the cloth quality. In the fourth embodiment, the same effects as in the third embodiment are obtained.

(Sixth embodiment)
19 to 21 show a sixth embodiment, which differs from the second embodiment in the following points.
The nonvolatile memory 47 stores data shown in FIG. That is, this data is the data of the start timing of the compressor 38 according to the difference ΔW, and when the difference ΔW is −1 kg, the start time of the drying process (the dehydration process start time) when the start of the compressor 38 is initially predicted. This indicates that the timing is delayed by 5 minutes with respect to (end time). In the same manner, it is indicated that the timing is delayed by 10 for -2 kg, the timing is advanced by 5 minutes for +1 kg, and the timing is advanced by 10 minutes for +2 kg.

In FIG. 19, the control device 23 executes the rinsing process at step Rg50. Immediately after the intermediate dehydration process included in the rinsing process, the controller 23 detects the post-dehydration detected weight Wk. In the next step Rg55, the drying capacity setting means 46 sets the start timing of the compressor 38 as the drying capacity.
In FIG. 20 showing the control contents of step R55a, in step SG20 following step SA10, the activation timing is set from the data stored in the nonvolatile memory 47 in accordance with the difference ΔW.

  According to the sixth embodiment, when the difference ΔW is in the minus direction (the detected weight Wk after dehydration is reduced with respect to the initial detected weight Wa), the compressor 38 that has a drying capacity according to the weight difference ΔW. Set the startup timing to be delayed. Conversely, when the difference ΔW is in the positive direction (the detected weight Wk after dehydration is increased with respect to the initial detected weight Wa), the start timing of the compressor 38 that is the drying capacity is advanced in accordance with the weight difference ΔW. Set. That is, since the operation time of the compressor 38 is ensured as much as necessary according to the difference ΔW, and the end of the required time for the drying process is set to match the end of the predicted required time TE, in other words, the initial time Since the start timing of the compressor 38 is set so that the drying process ends at the predicted end time TA, the washing and drying operation can be ended at the initial predicted end time TA.

(Seventh embodiment)
22 to 25 show a seventh embodiment, which differs from the second embodiment in the following points. In the seventh embodiment, the control means 23 includes a temperature control means 53 and a compressor temperature sensor (compressor temperature detection means) 54. The nonvolatile memory 47 stores data shown in FIG.
Data stored in the non-volatile memory 47 indicates the relationship between the difference ΔW and the control temperature of the temperature control target as the drying capacity (in this case, the control temperature of the compressor 38). When the difference ΔW is 0 kg, the control temperature of the compressor 38 is 90 ° C., and similarly, 85 ° C. for −1 kg, 80 ° C. for −2 kg, 95 ° C. for +1 kg, and 100 ° C. for +2 kg.

The compressor temperature sensor 54 detects the discharge refrigerant temperature, which is the temperature of the refrigerant on the outlet side of the compressor 38.
The temperature control means 53 controls the rotation speed of the compressor 38 so that the temperature detected by the compressor temperature sensor 54 becomes the set control temperature. When the rotation speed of the compressor 38 is increased, the temperature of the compressor 38 (discharged refrigerant temperature) increases, and the drying capacity of the heat pump unit 40 increases.

  As shown in FIG. 23, the control device 23 performs control temperature setting in step Ra80 following step R70. In FIG. 24 showing the contents of this control temperature setting, in step SH20 following step SA10, the control temperature of the compressor 38 (control of the compressor 38) is controlled from the data stored in the nonvolatile memory 47 according to the difference ΔW. The temperature refers to the temperature of refrigerant discharged from the compressor 38). After this step SH20, the process returns to step R90 to start the drying process.

In step Ra95 following step R90, the rotational speed of the compressor 38 is controlled so as to be the set control temperature of the compressor 38 (temperature control means 53).
According to the seventh embodiment, when the difference ΔW is in the minus direction, the control temperature of the compressor 38, which is the drying capacity, is set to be lowered in accordance with the weight difference ΔW. On the contrary, when the difference ΔW is in the plus direction, the control temperature of the compressor 38 is set to be increased according to the weight difference ΔW. That is, the control temperature of the compressor 38 is set in accordance with the difference ΔW so that the drying process ends at the predicted required time TE. In other words, the compression is performed so that the drying process ends at the initial predicted end time TA. Since the control temperature of the machine 38 is set, the washing / drying operation can be ended at the initial predicted end time TA.

(Eighth embodiment)
26 to 29 show an eighth embodiment. The eighth embodiment differs from the seventh embodiment in the control content of the temperature control means 53 and the control content of the drying capacity setting means 46, and in addition to the compressor temperature sensor 54, a condenser temperature sensor (condenser temperature). The difference is that the detection means 55 is provided. Furthermore, the data stored in the nonvolatile memory 47 is different from that in the seventh embodiment.

Data stored in the nonvolatile memory 47 indicates the relationship between the difference ΔW and the control temperature as the drying capacity (in this case, the control temperature of the condenser 37). When the difference ΔW is 0 kg, the control temperature of the condenser 37 is 55 ° C., and similarly, it is 50 ° C. when it is −1 kg, 45 ° C. when it is −2 kg, 60 ° C. when it is +1 kg, and 65 ° C. when it is +2 kg.
The condenser temperature sensor 55 detects the temperature of the condenser 37.
The temperature control means 53 controls the rotational speed of the compressor 38 so that the temperature detected by the condenser temperature sensor 55 becomes the set control temperature. When the rotational speed of the compressor 38 is increased, the temperature of the condenser 37 is increased, and the drying capacity of the heat pump unit 40 is increased.

  As shown in FIG. 27, the control device 23 sets the control temperature in step Rb80 following step R70. In FIG. 28 showing the contents of this control temperature setting, in step SI20 following step SA10, the control temperature of the condenser 37, which is the control temperature, is set from the data stored in the nonvolatile memory 47 in accordance with the difference ΔW. After this step SI20, the process returns to step R90 to start the drying process.

In step Rb95 following step R90, the rotational speed of the compressor 38 is controlled so as to be the set control temperature of the condenser 37 (temperature control means 53).
According to the eighth embodiment, when the difference ΔW is in the negative direction, the control temperature of the condenser 37, which is the drying capacity, is set to be lowered in accordance with the weight difference ΔW. On the contrary, when the difference ΔW is in the plus direction, the control temperature of the condenser 37 is increased in accordance with the weight difference ΔW. That is, the control temperature of the condenser 37 is set in accordance with the difference ΔW so that the drying process ends at the predicted required time TE, in other words, the condensation is performed so that the drying process ends at the initial predicted end time TA. Since the control temperature of the container 37 is set, the washing / drying operation can be ended at the initial predicted end time TA.

(Ninth embodiment)
30 to 33 show a ninth embodiment. The ninth embodiment is different from the seventh embodiment in the control content of the temperature control means 53 and the control content of the drying capacity setting means 46, and in addition to the compressor temperature sensor 54, the circulating air temperature sensor (circulating air temperature). The difference is that a detecting means) 56 is provided. Furthermore, the data stored in the nonvolatile memory 47 is different from that in the seventh embodiment.

  Data stored in the non-volatile memory 47 indicates the relationship between the difference ΔW and the control temperature as the drying capacity (in this case, the control temperature of the air temperature (circulation air) of the circulation air passage 30). When the difference ΔW is 0 kg, the control temperature of the circulating air is 50 ° C., and similarly, 45 ° C. for −1 kg, 40 ° C. for −2 kg, 55 ° C. for +1 kg, and 60 ° C. for +2 kg.

The circulating air temperature sensor 56 is provided at a portion for detecting the temperature of the air flowing through the circulating air passage 30 (the temperature of the air leaving the condenser 37 toward the water tank 12).
The temperature control means 53 controls the rotational speed of the compressor 38 so that the temperature detected by the circulating air temperature sensor 56 becomes the set control temperature. When the rotation speed of the compressor 38 is increased, the temperature of the condenser 37 and thus the circulating air temperature is increased, and the drying capacity of the heat pump unit 40 is increased.

  As shown in FIG. 31, the control device 23 performs control temperature setting in step Rc80 following step R70. In FIG. 32 showing the contents of this control temperature setting, in step SJ20 following step SA10, the control temperature of the circulating air, which is the control temperature, is set from the data stored in the nonvolatile memory 47 in accordance with the difference ΔW. After this step SJ20, the process returns to step R90 to start the drying process.

In step Rc95 subsequent to step R90, the rotational speed of the compressor 38 is controlled so as to reach the set circulating air control temperature (temperature control means 53).
According to the ninth embodiment, when the difference ΔW is in the minus direction, the control temperature of the circulating air, which is the drying capacity, is set to be lowered in accordance with the weight difference ΔW. Conversely, when the difference ΔW is in the plus direction, the control is set to increase the control temperature of the circulating air in accordance with the weight difference ΔW. That is, the control temperature of the circulating air is set in accordance with the difference ΔW so that the drying process ends at the estimated required time TE. In other words, the circulating wind is controlled so that the drying process ends at the initial predicted end time TA. Since the control temperature is set, the washing / drying operation can be ended at the initial predicted end time TA.

(10th Embodiment)
FIG. 34 (a) shows a tenth embodiment, in which the temperature of the compressor 38, which is a control temperature set according to the difference ΔW, is further adjusted according to the detected weight Wk after dehydration. Different from the form (FIGS. 22 to 25). That is, the nonvolatile memory 47 stores data (FIG. 34 (a)) for adjusting the control temperature of the compressor 38 set according to the difference ΔW according to the post-dehydration detected weight Wk. The post-dehydration detected weight Wk for adjustment is divided into two sections of 3 kg or less and over 3 kg.

Therefore, in the tenth embodiment, for example, when the difference ΔW is −1 kg, the standard post-dehydration detected weight Wk (more than 3 kg in the weight category) is set to 85 ° C., In the case of 3 kg or less, the temperature is adjusted to 75 ° C. Hereinafter, the control temperature is adjusted for each difference ΔW in the same way.
According to the tenth embodiment, since the control temperature of the compressor 38 is adjusted according to the weight of the clothes, the washing / drying operation can be completed with the initial predicted end time TA with higher accuracy.

(Eleventh embodiment)
FIG. 34B shows an eleventh embodiment, which is different from the seventh embodiment in that the temperature of the compressor 38, which is a control temperature set according to the difference ΔW, is further adjusted according to the ambient temperature. . That is, the data stored in the non-volatile memory 47 stores data for adjusting the control temperature of the compressor 38 set according to the difference ΔW according to the ambient temperature (FIG. 34B). The adjustment atmospheric temperature is divided into two categories of 20 ° C. or lower and higher than 20 ° C. In addition, although not shown, an ambient temperature detecting means for detecting the ambient temperature (the temperature in the outer box 11) is provided.

Therefore, in the eleventh embodiment, for example, when the difference ΔW is −1 kg, the standard atmospheric temperature (20 ° C. or lower in terms of temperature classification) is set to 85 ° C., but 20 ° C. In the case of exceeding, it is adjusted to 75 ° C. Hereinafter, the control temperature is adjusted for each difference ΔW in the same way.
According to the eleventh embodiment, since the control temperature of the compressor 38 is adjusted according to the ambient temperature, the washing and drying operation can be completed with higher accuracy at the initial predicted end time TA.

(Twelfth embodiment)
FIG. 34C shows a twelfth embodiment, which differs from the seventh embodiment in that the temperature of the compressor 38, which is a control temperature set according to the difference ΔW, is further adjusted according to the fabric quality. . That is, the data stored in the nonvolatile memory 47 stores data for adjusting the control temperature of the compressor 38 set according to the difference ΔW according to the cloth quality (FIG. 34C). The quality of the fabric for adjustment is divided into two categories of more than 50% cotton to 100% and less than 50% cotton. Although not shown, cloth quality detecting means is provided.

  Therefore, in the twelfth embodiment, for example, when the difference ΔW is −1 kg, 85 ° C. is set for a standard cloth quality (more than 50% cotton to 100% in the cloth quality classification). However, in the case of 50% or less of cotton, the fiber is adjusted to 75 ° C. because there are many synthetic fibers and the drying time is short. Hereinafter, the control temperature is adjusted for each difference ΔW in the same way.

According to the twelfth embodiment, since the control temperature of the compressor 38 is adjusted according to the cloth quality, the washing and drying operation can be completed with higher accuracy at the initial predicted end time TA.
(13th Embodiment)
FIG. 35A shows a thirteenth embodiment, in which the temperature of the condenser 37, which is a control temperature set according to the difference ΔW, is further adjusted according to the detected weight Wk after dehydration. It differs from the form (FIGS. 26 to 29). That is, the nonvolatile memory 47 stores data (FIG. 35A) for adjusting the control temperature of the condenser 37 set according to the difference ΔW according to the post-dehydration detected weight Wk. The post-dehydration detected weight Wk for adjustment is divided into two sections of 3 kg or less and over 3 kg.

Therefore, in the thirteenth embodiment, for example, when the difference ΔW is −1 kg, the standard post-dehydration detected weight Wk (more than 3 kg in the weight category) is set to 50 ° C., In the case of 3 kg or less, the temperature is adjusted to 45 ° C. Hereinafter, the control temperature is adjusted for each difference ΔW in the same way.
According to the thirteenth embodiment, since the control temperature of the condenser 37 is adjusted according to the weight of the clothes, the washing / drying operation can be completed with the initial predicted end time TA with higher accuracy.

(14th Embodiment)
FIG. 35B shows a fourteenth embodiment, which differs from the eighth embodiment in that the temperature of the condenser 37, which is a control temperature set according to the difference ΔW, is further adjusted according to the ambient temperature. . That is, the data stored in the non-volatile memory 47 stores data for adjusting the control temperature of the condenser 37 set according to the difference ΔW according to the ambient temperature (FIG. 35B). The adjustment atmospheric temperature is divided into two categories of 20 ° C. or lower and higher than 20 ° C. In addition, although not shown, an ambient temperature detecting means for detecting the ambient temperature (the temperature in the outer box 11) is provided.

Therefore, in the fourteenth embodiment, for example, when the difference ΔW is −1 kg, the standard atmospheric temperature (20 ° C. or less in terms of temperature classification) is set to 50 ° C., but 20 ° C. In the case of exceeding, it is adjusted to 45 ° C. Hereinafter, the control temperature is adjusted for each difference ΔW in the same way.
According to the fourteenth embodiment, since the control temperature of the condenser 37 is adjusted according to the ambient temperature, the washing and drying operation can be completed with higher accuracy at the initial predicted end time TA.

(Fifteenth embodiment)
FIG. 35 (c) shows the twelfth embodiment, which differs from the eighth embodiment in that the temperature of the condenser 37, which is the control temperature set according to the difference ΔW, is further adjusted according to the fabric quality. . That is, the non-volatile memory 47 stores data for adjusting the control temperature of the condenser 37 set according to the difference ΔW according to the cloth quality (FIG. 35C). The quality of the fabric is divided into two categories: more than 50% cotton to 100% and less than 50% cotton. Although not shown, cloth quality detecting means is provided.

  Therefore, in the fifteenth embodiment, for example, when the difference ΔW is −1 kg, the standard cloth quality (over 50% to 100% cotton in the cloth quality classification) is set to 50 ° C. However, in the case of 50% or less of cotton, the fiber is adjusted to 45 ° C. because there are many synthetic fibers and the drying time is short. Hereinafter, the control temperature is adjusted for each difference ΔW in the same way.

According to the fifteenth embodiment, since the control temperature of the condenser 37 is adjusted according to the cloth quality, the washing and drying operation can be completed with higher accuracy at the initial predicted end time TA.
(Sixteenth embodiment)
FIG. 36A shows the sixteenth embodiment, in which the temperature of the circulating air, which is the control temperature set according to the difference ΔW, is further adjusted according to the detected weight Wk after dehydration. (FIGS. 30 to 33). That is, the non-volatile memory 47 stores data (FIG. 36 (a)) for adjusting the control temperature of the circulating air set according to the difference ΔW according to the post-dehydration detected weight Wk. The post-dehydration detected weight Wk for adjustment is divided into two categories of 3 kg or less and more than 3 kg.

  Therefore, in the sixteenth embodiment, for example, when the difference ΔW is −1 kg, the standard post-dehydration detected weight Wk (more than 3 kg in the weight category) is set to 45 ° C., In the case of 3 kg or less, the temperature is adjusted to 40 ° C. Hereinafter, the control temperature is adjusted for each difference ΔW in the same way.

According to the sixteenth embodiment, since the control temperature of the circulating air is adjusted according to the weight of the clothes, the washing / drying operation can be finished with the initial predicted end time TA with higher accuracy.
(17th Embodiment)
FIG. 36B shows a seventeenth embodiment, which differs from the ninth embodiment in that the temperature of the circulating air, which is the control temperature set according to the difference ΔW, is further adjusted according to the ambient temperature. That is, the data stored in the nonvolatile memory 47 stores data (FIG. 36 (b)) for adjusting the control temperature of the circulating air set according to the difference ΔW according to the ambient temperature. The atmospheric temperature for adjustment is divided into two categories of 20 ° C. or lower and higher than 20 ° C. In addition, although not shown, an ambient temperature detecting means for detecting the ambient temperature (the temperature in the outer box 11) is provided.

  Therefore, in the seventeenth embodiment, for example, when the difference ΔW is −1 kg, the standard atmospheric temperature (20 ° C. or less in terms of temperature classification) is set to 45 ° C., but 20 ° C. In the case of exceeding, it is adjusted to 40 ° C. Hereinafter, the control temperature is adjusted for each difference ΔW in the same way.

According to the seventeenth embodiment, since the control temperature of the circulating air is adjusted according to the ambient temperature, the washing and drying operation can be completed with higher accuracy at the initial predicted end time TA.
(Eighteenth embodiment)
FIG. 36C shows the eighteenth embodiment, which differs from the ninth embodiment in that the temperature of the circulating air, which is the control temperature set according to the difference ΔW, is further adjusted according to the cloth quality. That is, the nonvolatile memory 47 stores data (FIG. 36 (c)) for adjusting the control temperature of the circulating air set according to the difference ΔW according to the cloth quality. The fabric quality is divided into two categories: more than 50% cotton to 100% and less than 50% cotton. Although not shown, cloth quality detecting means is provided.

  Therefore, in the eighteenth embodiment, for example, when the difference ΔW is −1 kg, it is set to 45 ° C. when it is standard fabric quality (more than 50% cotton to 100% in the fabric classification). However, in the case of 50% or less of cotton, the fiber is adjusted to 40 ° C. because there are many synthetic fibers and the drying time is short. Hereinafter, the control temperature is adjusted for each difference ΔW in the same way.

According to the eighteenth embodiment, since the control temperature of the circulating air is adjusted according to the cloth quality, the washing / drying operation can be completed more accurately with the initial predicted end time TA.
(Nineteenth embodiment)
37 and 38 show the nineteenth embodiment, and the following points are different from the first embodiment. That is, in the first embodiment, the drying garment weight detection means 44 first detects the weight Wb of the entire contents including the moisture weight and the garment weight according to the detection result from the current sensor 43, and this detected weight Wb. In the nineteenth embodiment, a constant power is supplied to the motor 14 in the dehydration process (constant power control), and the maximum dehydration rotation speed at that time (the lower the heavier the clothes, the lower the weight). The weight Wb of the entire package is detected. In this case, the moisture weight ratio is known for each maximum rotation speed, and the post-dehydration detected weight Wk is calculated (detected) based on the weight Wb detected based on the maximum rotation speed and the moisture weight ratio for each maximum rotation speed. It is configured. As can be seen from FIG. 38, the post-dehydration detected weight Wk decreases as the maximum rotational speed Nk increases.

In the nineteenth embodiment, as shown in step Rn60 and step Rn70 of FIG. 37, the post-dehydration detection weight Wk is detected based on the maximum rotational speed Nk (drying clothing weight detection means 44), and this post-dehydration detection is performed. The time required for the drying process is controlled by setting the rotation speed of the compressor 38, which is the drying capacity, according to the weight Wk. The nineteenth embodiment also has the same effects as the first embodiment.
In the tenth to eighteenth embodiments described above, the clothes weight detecting means 44 for drying (detecting the detected weight Wk after dehydration based on the maximum rotation speed Nk of the dehydration process) according to the nineteenth embodiment is adopted. You may do it.

(20th embodiment)
39 to 43 show a twentieth embodiment. In the twentieth embodiment, a compressor current sensor 57 is provided as a compressor current detection means for detecting an input current of the compressor, and the control device 23 further includes a power consumption prediction means 58, a power consumption measurement means. The point provided with 59 is different from the first embodiment. Further, the control content of the drying capacity setting means 46 and the data stored in the nonvolatile memory 47 are different from those of the first embodiment.

  The power consumption amount measuring means 59 calculates (measures) the power consumption amount (integrated power amount) of the drying device 42 from the detected current of the compressor current sensor 57 under the condition that the rotation speed of the blower 41 is constant.

  The nonvolatile memory 47 stores data shown in FIGS. That is, FIG. 41 shows the relationship between the post-dehydration detected weight Wk and the required power consumption amount Hy (described later) corresponding thereto, and FIG. 42 corresponds to the unit power consumption amount Hα (described later). FIG. 43 shows the relationship between the determination power consumption amount Hh (described later) and the rotation speed Nc of the compressor 38 adjusted accordingly. Yes. However, FIG. 41 and FIG. 42 are diagrams for easy understanding of the respective correlations, and are not necessarily linear relationships.

  The control contents of the control device 23 including the drying capacity setting means 46 and the power consumption amount prediction means 58 will be described with reference to FIG. 40 differs from the first embodiment in that steps Rp71 to Rp80 are executed instead of steps 80 to R90 in FIG. 6 of the first embodiment. In step Rp71 following step R70, the power consumption amount Hy necessary for drying is predicted from the post-dehydration detected weight Wk (power consumption amount prediction means 58). That is, since the detected weight Wk after dehydration is originally obtained from the above-described equation (1), the moisture weight ratio is known, and the moisture weight is determined from this moisture weight ratio. The amount of power consumption of the drying device 42 necessary for drying the moisture of the moisture weight is also known. Therefore, the power consumption necessary for drying is predicted based on the data shown in FIG. 41 from the post-dehydration detected weight Wk correlated with the moisture weight.

In the next step Rp72, the required time tx for the drying process is calculated in the same manner as in step S10 of FIG. 7 of the first embodiment (see the above-described equation (2)).
In the next step Rp73, a unit power consumption amount Hα required per unit time is calculated from the predicted power consumption amount Hy and the required time tx.

Hα = Hy / tx
In the next step Rp74, the rotation speed Nc of the compressor 38 corresponding to the unit power consumption Hα is set based on the data in FIG. 42 (drying capacity setting means 46). That is, under the condition that the rotational speed of the blower 41 is constant, the unit power consumption Hα is determined by the rotational speed Nc of the compressor 38, and conversely, the rotational speed Nc of the compressor 38 can be set from the unit power consumption Hα. The rotational speed Nc is approximately 40 to 60 rpm.

Therefore, if the compressor 38 is operated at the rotation speed Nc for the time tx, the predicted power consumption Hy, that is, the predetermined dryness is usually obtained at the required time tx. However, although the unit power consumption in the actual drying operation is close to the unit power consumption Hα, it may be slightly deviated. In order to eliminate this point, Step Rp75 to Step Rp80 are executed.
In Step Rp75, the determination power consumption Hh (integrated power consumption at time th) after a predetermined time th is set according to the unit power consumption Hα. In this case, the predetermined time th is set to be shorter than the predicted drying time (required time).

In the next step Rp76, the compressor 38 is started to operate at the rotational speed Nc and the blower 41 is started to operate at a predetermined constant rotational speed to start the drying process.
In the next step Rp77 and step Rp78, it is determined whether or not the power consumption at the time when the predetermined time th has elapsed (this is measured by the power consumption measuring means 59) exceeds the determination power consumption Hh. . If it exceeds, it can be predicted that when the required time tx expires, the predicted power consumption Hy or higher can be obtained and a predetermined dryness can be obtained. In step Rp79, the compressor 38 is operated based on the data of FIG. The number of rotations remains Nc. If the power consumption at the time when the predetermined time th has elapsed is equal to or less than the determination power consumption Hh, when the required time tx expires, the predicted power consumption Hy cannot be obtained and a predetermined dryness is obtained. In step Rp80, the rotation speed of the compressor 38 is set to “Nc + predetermined value, for example, 5” rpm (drying capacity setting means 46).

According to the twentieth embodiment, the power consumption amount Hy corresponding to the post-dehydration detected weight Wk is predicted,
The drying capacity setting means 46 sets the rotational speed Nc of the compressor 38 as the drying capacity of the drying means so that the measured power consumption after the start of the drying process becomes the power consumption Hy predicted by the power consumption prediction means 58. Therefore, the time required for the drying process can be controlled by setting the rotational speed Nc of the compressor 38. Since the time required for the drying process can be controlled in this way, the required time can be adjusted so that the drying process is completed at the initially set predicted end time by setting the rotation speed of the compressor 38.

  In addition, according to the twentieth embodiment, the power consumption is measured during the drying process, and the rotational speed Nc of the compressor 38 is changed and set (adjusted) according to the measurement result. Even if there is a fluctuation in the amount of electric power, the required time can be adjusted so that the drying process is completed at the initially set predicted end time.

(21st Embodiment)
44 and 45 show a twenty-first embodiment. The difference from the twentieth embodiment is that the rotational speed Nc of the compressor 38 is further adjusted according to the ambient temperature. That is, the non-volatile memory 47 stores data for adjusting the rotational speed Nc of the compressor 38 in accordance with the ambient temperature. The ambient temperature for adjustment is 10 ° C. or lower and over 10 ° C. It is divided into three sections of -20 ° C or lower and higher than 20 ° C. In addition, an ambient temperature sensor 51 is provided as an ambient temperature detection means for detecting the ambient temperature (the temperature in the outer box 11).

  Therefore, in the twenty-first embodiment, when the measured power consumption is equal to or higher than the determination power consumption Hh, the rotation speed of the compressor 38 is set to Nc when the ambient temperature is higher than 10 ° C. to 20 ° C. or lower. When the atmospheric temperature is 10 ° C. or lower, the temperature is adjusted to Nc + 10 rpm, and when it is higher than 20 ° C., the temperature is adjusted to Nc−10 rpm.

Further, when the measured power consumption is less than the determination power consumption Hh, the rotation speed of the compressor 38 is set to Nc + 5 rpm when the ambient temperature is higher than 10 ° C. to 20 ° C. or lower. When the atmospheric temperature is 10 ° C. or lower, the temperature is adjusted to Nc + 15 rpm, and when it is higher than 20 ° C., the temperature is adjusted to Nc-5 rpm.
According to the twenty-first embodiment, since the rotation speed Nc of the compressor 38 is adjusted according to the ambient temperature, the washing / drying operation can be completed more accurately with the initial predicted end time TA.

(Twenty-second embodiment)
46 and 47 show a twenty-second embodiment. The difference from the twentieth embodiment is that the rotational speed Nc of the compressor 38 is further adjusted according to the cloth quality. That is, the non-volatile memory 47 stores data for adjusting the rotational speed Nc of the compressor 38 in accordance with the cloth quality, and the adjustment cloth quality is more than 60% cotton (residual fibers). ) ~ 100%, more than 30% cotton ~ 60% or less, cotton 0% or more ~ 30% or less is divided into three categories. In addition, the control device 23 includes a cloth quality detection means 52.

  Therefore, in the twenty-second embodiment, when the measured power consumption is equal to or greater than the determination power consumption Hh, the rotation speed of the compressor 38 is set to Nc when the fabric quality is more than 30% cotton and less than 60%. . When the fabric quality is more than 60% cotton to 100%, it is adjusted to Nc + 10 rpm, and when the fabric quality is 0% to 30%, it is adjusted to Nc-10 rpm.

  When the measured power consumption is less than the determination power consumption Hh, the rotation speed of the compressor 38 is set to Nc + 5 rpm when the cloth quality is more than 30% cotton to 60% or less. When the fabric quality is more than 60% to 100% cotton, the speed is adjusted to Nc + 15 rpm. When the fabric quality is 0% to 30%, the speed is adjusted to Nc-5 rpm.

According to the twenty-second embodiment, since the rotation speed Nc of the compressor 38 is adjusted according to the cloth quality, the washing / drying operation can be completed with higher accuracy at the initial predicted end time TA.
(23rd Embodiment)
48 to 52 show the 23rd embodiment, and the following points are different from the 20th embodiment. In the twenty-third embodiment, the control means 23 includes a temperature control means 53 (described in the seventh embodiment), and a compressor temperature sensor (compressor temperature detecting means) 54 (described in the seventh embodiment). ). The control temperature (in this case, the control temperature of the compressor 38) is set as the drying capacity to be set. The nonvolatile memory 47 stores data shown in FIGS.

  In step Rp74s following step Rp73, the controller 23 sets the compressor control temperature Tc according to the unit power consumption Hα based on the data in FIG. As can be seen from the data in FIG. 51, the unit power consumption Hα increases as the compressor control temperature Tc increases. The compressor control temperature Tc is set to approximately 80 to 90 ° C. In step Rp76s following step Rp75, temperature control (temperature control means 53) for controlling the rotation speed of the compressor 38 so that the temperature of the compressor 38 becomes the control temperature Tc is started and the blower 41 is kept at a predetermined constant level. The operation starts at the rotation speed and the drying process is started.

  In step Rp77 and step Rp78, if it is determined that the power consumption at the time when the predetermined time th has passed exceeds the determination power consumption Hh, the control temperature is set based on the data of FIG. 52 in step Rp79s. If it is determined as follows, the control temperature Tc is set to “Tc + predetermined value, for example, 5” ° C. in step Rp80s (drying capacity setting means 46).

According to the twenty-third embodiment, the power consumption amount Hy corresponding to the post-dehydration detected weight Wk is predicted,
The drying capacity setting means 46 sets the compressor control temperature Tc, which is the drying capacity of the drying means, so that the measured power consumption after the start of the drying process becomes the power consumption Hy predicted by the power consumption prediction means 58. The time required for the drying process can be controlled by setting the compressor control temperature Tc. Since the time required for the drying process can be controlled in this way, the required time can be adjusted so that the drying process ends at the initially set predicted end time by setting the compressor control temperature Tc.
Further, according to the twenty-third embodiment, the power consumption is measured during the drying process, and the compressor control temperature Tc is changed (adjusted) according to the measurement result. Even if there is a variation in the required time, the required time can be adjusted so that the drying process is completed at the initially set predicted end time.

(24th Embodiment)
FIGS. 53 to 57 show the twenty-fourth embodiment. In the twenty-fourth embodiment, the drying capacity to be set is not the compressor control temperature Tc of the twenty-third embodiment but the condenser control temperature Tg. Concomitantly, a condenser temperature sensor 55 (described above in the eighth embodiment) is provided instead of the compressor temperature sensor 54. The nonvolatile memory 47 stores data shown in FIGS. As can be seen from the data in FIG. 56, the unit power consumption Hα increases as the condenser control temperature Tg increases.

  In the twenty-fourth embodiment, the controller 23 sets the condenser control temperature Tg corresponding to the unit power consumption amount Hα based on the data in FIG. 56 in step Rp74t following step Rp73, and thereafter the twenty-third embodiment. The drying process is executed according to the same concept as the embodiment (concept of replacing the compressor control temperature Tc with the condenser control temperature Tg).

According to the twenty-fourth embodiment, the same effects as in the twenty-third embodiment are achieved.
(25th Embodiment)
58 to 62 show a twenty-fifth embodiment. In the twenty-fifth embodiment, the drying capacity to be set is not the compressor control temperature Tc of the twenty-third embodiment but the circulating wind control temperature Tj. Along with this, a circulating air temperature sensor 56 (described above in the ninth embodiment) is provided instead of the compressor temperature sensor 54. The nonvolatile memory 47 stores the data shown in FIGS. As can be seen from the data in FIG. 61, the unit power consumption Hα increases as the circulating air control temperature Tj increases.

  In the twenty-fifth embodiment, the control device 23 sets the circulating wind control temperature Tj according to the unit power consumption Hα based on the data in FIG. 61 in step Rp74u following step Rp73, and thereafter the twenty-third embodiment. The drying process is executed according to the same concept as the embodiment (concept of replacing the compressor control temperature Tc with the circulating air control temperature Tj).

According to the twenty-fifth embodiment, the same effects as in the twenty-third embodiment are achieved.
(26th Embodiment)
FIG. 63A shows a twenty-sixth embodiment, which differs from the twenty-third embodiment (FIGS. 48 to 52) in that the temperature of the compressor 38, which is a control temperature, is further adjusted according to the ambient temperature. . That is, the nonvolatile memory 47 stores data for adjusting the control temperature of the compressor 38 according to the ambient temperature (FIG. 63 (a)). It is divided into two categories of below 20 ° C and above 20 ° C. In addition, although not shown, an ambient temperature detecting means for detecting the ambient temperature (the temperature in the outer box 11) is provided.

Therefore, in the twenty-sixth embodiment, for example, when the power consumption amount at the predetermined time th is equal to or higher than Hh, the standard ambient temperature (20 ° C or lower in terms of temperature category) is set to Tc ° C. However, if it exceeds 20 ° C, it will be adjusted to Tc-5 ° C.
According to the twenty-sixth embodiment, since the control temperature of the compressor 38 is adjusted according to the ambient temperature, the washing and drying operation can be completed with higher accuracy at the initial predicted end time TA.

(27th Embodiment)
FIG. 63B shows a twenty-seventh embodiment, which differs from the twenty-third embodiment in that the temperature of the compressor 38, which is the control temperature, is further adjusted according to the fabric quality. That is, the non-volatile memory 47 stores data for adjusting the control temperature of the compressor 38 in accordance with the cloth quality (FIG. 63 (b)). It is divided into two categories of more than 50% to 100% and less than 50% cotton. Although not shown, cloth quality detecting means is provided.

  Therefore, in the twenty-seventh embodiment, for example, when the power consumption at the predetermined time th is equal to or higher than Hh, Tc is a standard fabric quality (over 50% to 100% cotton in the fabric classification). Although it is set to ° C., in the case of 50% or less of cotton, it is adjusted to Tc-5 ° C. because there are many synthetic fibers and the drying time is short.

According to the twenty-seventh embodiment, since the control temperature of the compressor 38 is adjusted according to the cloth quality, the washing and drying operation can be completed with higher accuracy at the initial predicted end time TA.
(Twenty-eighth embodiment)
FIG. 64 (a) differs from the twenty-fourth embodiment (FIGS. 53 to 57) in that the temperature of the condenser 37, which is the control temperature, is further adjusted according to the ambient temperature. That is, the non-volatile memory 47 stores data (FIG. 64A) for adjusting the control temperature of the condenser 37 in accordance with the ambient temperature. It is divided into two categories of below 20 ° C and above 20 ° C. In addition, although not shown, an ambient temperature detecting means for detecting the ambient temperature (the temperature in the outer box 11) is provided.

Therefore, in the twenty-eighth embodiment, for example, when the power consumption amount at the predetermined time th is Hh or more, the standard ambient temperature (20 ° C. or less in terms of temperature category) is set to Tg ° C. However, when it exceeds 20 ° C, it is adjusted to Tg-5 ° C.
According to the twenty-eighth embodiment, since the control temperature of the condenser 37 is adjusted according to the ambient temperature, the washing and drying operation can be completed with higher accuracy at the initial predicted end time TA.

(Twenty-ninth embodiment)
FIG. 64 (b) differs from the twenty-fourth embodiment in that the temperature of the condenser 37, which is the control temperature, is further adjusted according to the cloth quality. That is, the nonvolatile memory 47 stores data (FIG. 64B) for adjusting the control temperature of the condenser 37 in accordance with the cloth quality. It is divided into two categories of more than 50% to 100% and less than 50% cotton. Although not shown, cloth quality detecting means is provided.
Therefore, in the 29th embodiment, for example, when the power consumption at the predetermined time th is equal to or higher than Hh, it is condensed that it is standard cloth quality (over 50% to 100% cotton in the cloth classification). The control temperature of the vessel 37 is set to Tg ° C. However, when the cotton is 50% or less, there are many synthetic fibers and the drying time is short, so that the temperature is adjusted to Tg-5 ° C.

According to the twenty-ninth embodiment, since the control temperature of the condenser 37 is adjusted according to the cloth quality, the washing / drying operation can be finished with the initial predicted end time TA with higher accuracy.
(Thirty Embodiment)
FIG. 65 (a) differs from the twenty-fifth embodiment (FIGS. 58 to 62) in that the temperature of the circulating air, which is the control temperature, is further adjusted according to the ambient temperature. That is, the non-volatile memory 47 stores data (FIG. 65 (a)) for adjusting the control temperature of the circulating air according to the ambient temperature, and the ambient temperature for adjustment is 20 ° C. Below, it is divided into two categories of over 20 ° C. In addition, although not shown, an ambient temperature detecting means for detecting the ambient temperature (the temperature in the outer box 11) is provided.
Therefore, in the thirtieth embodiment, for example, when the power consumption at the predetermined time th is equal to or higher than Hh, the standard ambient temperature (20 ° C or lower in terms of temperature category) is set to Tj ° C. However, when it exceeds 20 ° C., it is adjusted to Tj−5 ° C.

According to the twenty-eighth embodiment, since the control temperature of the circulating air is adjusted according to the ambient temperature, the washing and drying operation can be completed with higher accuracy at the initial predicted end time TA.
(Thirty-first embodiment)
FIG. 65B is different from the twenty-fifth embodiment in that the temperature of the circulating air, which is the control temperature, is further adjusted according to the cloth quality. That is, the non-volatile memory 47 stores data (FIG. 65 (b)) for adjusting the control temperature of the circulating air in accordance with the cloth quality. It is divided into two categories of more than% to 100% and less than 50% cotton. Although not shown, cloth quality detecting means is provided.

  Therefore, in the thirty-first embodiment, for example, when the power consumption at the predetermined time th is equal to or higher than Hh, it is circulated when it is a standard cloth quality (over 50% to 100% cotton in the cloth quality classification). The control temperature of the wind is set to Tj ° C., but when the amount is 50% or less, the fiber is adjusted to Tj−5 ° C. because there are many synthetic fibers and the drying time is short.

According to the thirty-first embodiment, since the control temperature of the circulating air is adjusted according to the cloth quality, the washing and drying operation can be finished with higher accuracy at the initial predicted end time TA.
(Thirty-second embodiment)
66 to 68 show the thirty-second embodiment, which differs from the first embodiment in the following points. That is, in the first embodiment, the drying capacity to be set is the rotational speed of the compressor 38, but in the 32nd embodiment, the drying capacity to be set is the rotational speed of the blower 41. As can be seen from FIG. 66, the required time can be controlled by setting the rotational speed of the blower 41 in accordance with the weight of clothing (detected weight after dehydration Wk). The relationship of FIG. 66 is stored in the nonvolatile memory 47.
In FIG. 67, step PQ80 is provided instead of step R80 in FIG. In step RQ80, the rotational speed of the blower 41 is set as the drying capacity. In FIG. 68 showing the control content of step RQ, the rotation speed Qx corresponding to the required time tx is set in step SQ20.

The thirty-second embodiment has the same effects as the first embodiment.
(Thirty-third embodiment)
69 and 70 show a thirty-third embodiment. In the thirty-third embodiment, the rotation speed of the compressor 38, which is the drying capacity set based on the difference ΔW in the second embodiment, is determined by the fan 41. The point which changed to the number of rotations is different. In this case, the rotation speed of the compressor 38 is set to a constant rotation speed, for example, 60 rpm. The drying capacity of the entire drying device 42 can be changed and set by changing the rotational speed of the blower 41 as long as the rotational speed of the compressor 38 is constant. The nonvolatile memory 47 stores the data shown in FIG.

This 33rd embodiment also has the same effect as the second embodiment.
In the twentieth embodiment, the rotational speed of the compressor 38 is set by the unit power consumption amount Hα as shown in step Rp74. However, as described above, the blower is used instead of the rotational speed of the compressor 38. Since the rotational speed of 41 is also applicable, the rotational speed of the blower 41 may be set instead of the rotational speed of the compressor 38 in the twentieth embodiment.

  In the washing and drying machine of the embodiment, in the washing and drying machine that performs each process of washing, rinsing, dehydration, and drying, a water tank having an exhaust port and an air supply port, and a clothes rotatably provided in the water tank are washed, A rotating tank accommodated inside for rinsing and drying, a circulation air passage provided outside the water tank and connecting the exhaust port and the air supply port, and a circulation air passage provided in the circulation air passage. A heat pump unit having an evaporator for dehumidifying air, a condenser provided on the downstream side of the evaporator in the circulation air passage, for heating the air in the circulation air passage, and a compressor for supplying refrigerant to the condenser And a blower which is provided in the circulation air passage and which is dehumidified and heated by the heat pump unit and is supplied to the water tank from the air supply port and forms drying means with the heat pump, and at the end of the dehydration process Clothing And drying the clothes weight detecting means for detecting the weight, and a drying capacity setting means which can set a drying capacity of the drying means in accordance with a garment weight detected by said drying clothes weight detecting means. According to this, the time required for the drying process can be controlled according to the clothing weight detected by the drying clothing weight detection means. Since the time required for the drying process can be controlled in this way, the required time can be adjusted so that the drying process ends at the predicted end time set initially by setting the drying capacity by the drying capacity setting means.

  Although several embodiments of the present invention have been described, these embodiments are presented by way of example and are not intended to limit the scope of the invention. These novel embodiments can be implemented in various other forms, and various omissions, replacements, and changes can be made without departing from the scope of the invention. These embodiments and modifications thereof are included in the scope and gist of the invention, and are included in the invention described in the claims and equivalents thereof.

  In the drawings, 10 is a washing / drying machine, 11 is an outer box, 12 is a water tank, 13 is a rotating tank, 14 is a motor, 16 is an exhaust port, 17 is an air supply port, 23 is a control device, 30 is a circulation air path, 36 Is an evaporator, 37 is a condenser, 38 is a compressor, 40 is a heat pump unit, 41 is a blower, 42 is a drying device (drying means), 44 is a clothing weight detecting means for drying, and 45 is a clothing weight detecting means for time prediction. , 46 is a drying capacity setting means, 47 is a non-volatile memory (storage means), 50 is an end time prediction means, 51 is an ambient temperature sensor (atmosphere temperature detection means), 52 is a cloth quality detection means, 53 is a temperature control means, 54 is a compressor temperature sensor (compressor temperature detecting means), 55 is a condenser temperature sensor (condenser temperature detecting means), 56 is a circulating air temperature sensor (circulating air temperature detecting means), 57 is a compressor current sensor, 58 Is a predictor of power consumption 59 shows the power consumption measuring means.

Claims (31)

In washing and drying machines that perform washing, rinsing, dehydration, and drying processes,
A water tank having an exhaust port and an air supply port;
A rotating tub provided for rotation in the water tub and housed therein for washing, rinsing, dehydrating and drying;
A circulation air passage provided outside the water tank and connecting the exhaust port and the air supply port;
Wherein a condenser for heating the air in the air circulation path provided downstream of the evaporator of the air circulation path and the evaporator for dehumidifying the air in the air circulation path is provided in the air circulation duct condensation A heat pump unit having a compressor for supplying refrigerant to the vessel;
A blower that is provided in the circulation air passage, and that is supplied from the exhaust port and dehumidified and heated by the heat pump unit, is supplied from the supply port into the water tank, and constitutes a drying means with the heat pump unit ;
Clothing weight detection means for drying for detecting the weight of the clothing at the end of the dehydration process;
A washing / drying machine comprising: a drying capacity setting means capable of setting the drying capacity of the drying means in accordance with the clothing weight detected by the drying clothes weight detection means. further,
A clothing weight detecting means for predicting time for detecting the weight of clothing before the washing step when performing the washing, rinsing, dehydration and drying steps in a series;
An end time predicting means for predicting a required time from the washing process to the end of the drying process according to the clothing weight detected by the time predicting clothes weight detecting means,
The drying capacity setting unit is configured to predict the drying process according to a difference between the clothing weight detected by the time prediction clothing weight detection unit and the clothing weight detected by the drying clothing weight detection unit. The washing / drying machine according to claim 1, wherein the drying capacity of the drying means is set so as to be completed in a required time. The drying capacity set by the drying capacity setting means is the rotational speed of the compressor,
The drying capacity setting means is a compressor having the drying capacity set according to the difference between the clothing weight detected by the time prediction clothing weight detection means and the clothing weight detected by the drying clothing weight detection means. The washing / drying machine according to claim 2, further comprising adjusting the number of rotations according to a clothing weight detected by the drying clothing weight detection means. The drying capacity set by the drying capacity setting means is the rotational speed of the compressor,
An ambient temperature detecting means for detecting the ambient temperature is provided.
The drying capacity setting means is the compression capacity that is the drying capacity that is set in accordance with a difference between the clothing weight detected by the time prediction clothing weight detection means and the clothing weight detected by the drying clothing weight detection means. The washing / drying machine according to claim 2, wherein the number of rotations of the machine is further adjusted according to the atmospheric temperature detected by the atmospheric temperature detecting means. The drying capacity set by the drying capacity setting means is the rotational speed of the compressor,
A cloth quality detecting means for detecting the cloth quality of the clothes;
The drying capacity setting means is a compressor having the drying capacity set according to the difference between the clothing weight detected by the time prediction clothing weight detection means and the clothing weight detected by the drying clothing weight detection means. The washing / drying machine according to claim 2, further comprising adjusting the number of rotations according to the cloth quality detected by the cloth quality detecting means.   The washing / drying machine according to claim 1 or 2, wherein the drying capacity set by the drying capacity setting means is a rotational speed of the blower. The rinsing process includes an intermediate dehydration process,
The drying clothing weight detection means detects the clothing weight at the end of the intermediate dehydration process,
The washing / drying machine according to claim 1 or 2, wherein the drying capacity set by the drying capacity setting means is a start timing of the compressor. A temperature control means for controlling the number of revolutions of the compressor so as to maintain a temperature control target in the drying means at a predetermined control temperature;
The washing / drying machine according to claim 2, wherein the drying capacity set by the drying capacity setting unit is the predetermined control temperature in the temperature control unit. The temperature control object in the temperature control means is the refrigerant discharge refrigerant temperature, and the predetermined control temperature is a control temperature for the compressor,
Compressor temperature detecting means for detecting the refrigerant discharge temperature of the compressor,
The laundry dryer according to claim 8, wherein the temperature control means controls the number of revolutions of the compressor so that the temperature detected by the compressor temperature detection means becomes the predetermined control temperature as the drying capacity. The temperature control object in the temperature control means is the temperature of the condenser, and the predetermined control temperature is a control temperature for the condenser,
Condenser temperature detection means for detecting the temperature of the condenser,
The laundry dryer according to claim 8, wherein the temperature control means controls the number of revolutions of the compressor so that the temperature detected by the condenser temperature detection means becomes the predetermined control temperature as the drying capacity. The temperature control object in the temperature control means is the temperature of the air in the circulation air passage, and the predetermined control temperature is the control temperature for the air in the circulation air passage,
A circulating wind temperature detecting means for detecting the temperature of the air in the circulating wind path;
The laundry dryer according to claim 8, wherein the temperature control means controls the number of revolutions of the compressor so that the temperature detected by the circulating air temperature detection means becomes the predetermined control temperature as the drying capacity.   The drying capacity setting means is the predetermined drying capacity that is set according to a difference between the clothing weight detected by the time prediction clothing weight detection means and the clothing weight detected by the drying clothing weight detection means. The laundry dryer according to any one of claims 9 to 11, wherein the control temperature is further adjusted in accordance with a clothing weight detected by the drying clothing weight detection means. An ambient temperature detecting means for detecting the ambient temperature is provided.
The drying capacity setting means is the predetermined drying capacity that is set according to a difference between the clothing weight detected by the time prediction clothing weight detection means and the clothing weight detected by the drying clothing weight detection means. The washing / drying machine according to any one of claims 9 to 11, wherein the control temperature is further adjusted according to the ambient temperature detected by the ambient temperature detection means. A cloth quality detecting means for detecting the cloth quality of the clothes;
The drying capacity setting means is the predetermined drying capacity that is set according to a difference between the clothing weight detected by the time prediction clothing weight detection means and the clothing weight detected by the drying clothing weight detection means. The washing / drying machine according to any one of claims 9 to 11, wherein the control temperature is further adjusted according to the cloth quality of the clothing detected by the cloth quality detecting means. The drying garment weight detection means detects the weight of the garment according to the dehydration speed in the dehydration process before the drying process,
A temperature control means for controlling the number of revolutions of the compressor so as to maintain a temperature control target in the drying means at a predetermined control temperature;
The washing / drying machine according to claim 2, wherein the drying capacity set by the drying capacity setting unit is the predetermined control temperature in the temperature control unit. The temperature control object in the temperature control means is the refrigerant discharge refrigerant temperature, and the predetermined control temperature is a control temperature for the compressor,
Compressor temperature detecting means for detecting the refrigerant discharge temperature of the compressor,
The laundry dryer according to claim 15, wherein the temperature control means controls the number of rotations of the compressor so that the temperature detected by the compressor temperature detection means becomes the predetermined control temperature as the drying capacity. The temperature control object in the temperature control means is the temperature of the condenser, and the predetermined control temperature is a control temperature for the condenser,
Condenser temperature detection means for detecting the temperature of the condenser,
The laundry dryer according to claim 15, wherein the temperature control unit controls the rotation speed of the compressor so that a temperature detected by the condenser temperature detection unit becomes the predetermined control temperature as the drying capacity. The temperature control object in the temperature control means is the temperature of the air in the circulation air passage, and the predetermined control temperature is the control temperature for the air in the circulation air passage,
A circulating wind temperature detecting means for detecting the temperature of the air in the circulating wind path;
The washing / drying machine according to claim 15, wherein the temperature control unit controls the rotation speed of the compressor so that a temperature detected by the circulating air temperature detection unit becomes the predetermined control temperature as the drying capacity.   The drying capacity setting means is the predetermined drying capacity that is set according to a difference between the clothing weight detected by the time prediction clothing weight detection means and the clothing weight detected by the drying clothing weight detection means. The washing / drying machine according to any one of claims 16 to 18, wherein the control temperature is further adjusted according to a clothing weight detected by the drying clothing weight detection means. An ambient temperature detecting means for detecting the ambient temperature is provided.
The drying capacity setting means is the predetermined drying capacity that is set according to a difference between the clothing weight detected by the time prediction clothing weight detection means and the clothing weight detected by the drying clothing weight detection means. The washing / drying machine according to any one of claims 16 to 18, wherein the control temperature is further adjusted according to the ambient temperature detected by the ambient temperature detection means. A cloth quality detecting means for detecting the cloth quality of the clothes;
The drying capacity setting means is the predetermined drying capacity that is set according to a difference between the clothing weight detected by the time prediction clothing weight detection means and the clothing weight detected by the drying clothing weight detection means. The washing / drying machine according to any one of claims 16 to 18, wherein the control temperature is further adjusted according to the cloth quality of the clothing detected by the cloth quality detecting means. further,
A clothing weight detecting means for predicting time for detecting the weight of clothing before the washing step when performing the washing, rinsing, dehydration and drying steps in a series;
An end time predicting means for predicting a required time from the washing process to the end of the drying process according to the clothing weight detected by the time predicting clothes weight detecting means,
Power consumption prediction means for predicting power consumption in the drying process according to the clothing weight detected by the drying clothing weight detection means;
Power consumption measuring means for measuring the power consumption in the drying step,
The drying capacity setting unit is configured so that the measured power consumption measured by the power consumption measuring unit after the start of the drying process becomes the power consumption predicted by the power consumption prediction unit. The washing / drying machine according to claim 1, wherein: The drying capacity set by the drying capacity setting means is the rotational speed of the compressor,
An ambient temperature detecting means for detecting the ambient temperature is provided.
The washing / drying machine according to claim 22, wherein the drying capacity setting means further adjusts the rotation speed of the compressor, which is the drying capacity, according to the atmospheric temperature detected by the atmospheric temperature detection means. The drying capacity set by the drying capacity setting means is the rotational speed of the compressor,
A cloth quality detecting means for detecting the cloth quality of the clothes;
The washing / drying machine according to claim 22, wherein the drying capacity setting means further adjusts the rotation speed of the compressor, which is the drying capacity, according to the cloth quality detected by the cloth quality detection means. A temperature control means for controlling the number of revolutions of the compressor so as to maintain a temperature control target in the drying means at a predetermined control temperature;
The washing / drying machine according to claim 22, wherein the drying capacity set by the drying capacity setting unit is the predetermined control temperature in the temperature control unit. The temperature control object in the temperature control means is the refrigerant discharge refrigerant temperature, and the predetermined control temperature is a control temperature for the compressor,
Compressor temperature detecting means for detecting the refrigerant discharge temperature of the compressor,
26. The laundry dryer according to claim 25, wherein the temperature control unit controls the rotation speed of the compressor so that a temperature detected by the compressor temperature detection unit becomes the predetermined control temperature as the drying capacity. The temperature control object in the temperature control means is the temperature of the condenser, and the predetermined control temperature is a control temperature for the condenser,
Condenser temperature detection means for detecting the temperature of the condenser,
26. The laundry dryer according to claim 25, wherein the temperature control unit controls the rotation speed of the compressor so that a temperature detected by the condenser temperature detection unit becomes the predetermined control temperature as the drying capacity. The temperature control object in the temperature control means is the temperature of the air in the circulation air passage, and the predetermined control temperature is the control temperature for the air in the circulation air passage,
A circulating wind temperature detecting means for detecting the temperature of the air in the circulating wind path;
26. The laundry dryer according to claim 25, wherein the temperature control unit controls the rotation speed of the compressor so that a temperature detected by the circulating air temperature detection unit becomes the predetermined control temperature as the drying capacity. An ambient temperature detecting means for detecting the ambient temperature is provided.
29. The washing / drying machine according to claim 26, wherein the drying capacity setting unit further adjusts the predetermined control temperature according to the atmospheric temperature detected by the atmospheric temperature detection unit. A cloth quality detecting means for detecting the cloth quality of the clothes;
The washing and drying machine according to any one of claims 26 to 28, wherein the drying capacity setting means further adjusts the predetermined control temperature according to the cloth quality of the clothing detected by the cloth quality detection means.   The washing / drying machine according to claim 22, wherein the drying capacity set by the drying capacity setting unit is a rotational speed of the blower.

Images