JP3867809B1 - Dishwasher - Google Patents

Abstract

[PROBLEMS] To improve the quiet performance while improving the cleaning performance, and improve the ease of use for the user.
A dishwasher has a function of executing a preliminary cleaning step of intermittently injecting cleaning water before the start of the main cleaning step of continuously injecting cleaning water, and in response to a user, It has a function of selecting whether to execute or omit the cleaning process. When the preliminary cleaning process is omitted, the execution time of the main cleaning process is extended as compared with the case where the preliminary cleaning process is performed. By performing the preliminary cleaning step, high cleaning performance can be exhibited, but noise increases. By performing the preliminary cleaning process, the silent performance can be improved, and the high cleaning performance can be secured by extending the time of the main cleaning process.
[Selection] Figure 5

Description

  The present invention relates to a dishwasher, and more particularly to improvement of silent performance.

  When it is set to start washing after waiting for a predetermined time with the reservation switch, for example, every 20 minutes during the waiting time, the washing pump is operated at a rotation speed lower than that at the time of washing for 30 seconds to sprinkle the dishes. Thus, a dishwasher is disclosed in Patent Document 1, which prevents the dirt attached to the tableware from drying and solidifying.

Japanese Patent Laid-Open No. 2002-539

  Needless to say, it is important to improve the cleaning performance of the dishwasher. On the other hand, it is also important to improve the silent performance. For example, when the operation and stop of the cleaning pump are repeated as in the watering operation during the standby time described above, relatively large noise is likely to be generated due to intermittent contact of the cleaning pump and intermittent collision of the spray water. When a user sets a reservation before going to bed, the above watering operation is performed while the user is sleeping, and the noise may become a problem.

  Accordingly, an object of the present invention is to improve the ease of use for the user in the dishwasher while improving the cleaning performance on the one hand and also improving the silent performance on the other hand.

  According to the invention concerning Claim 1, the dishwasher which injects wash water and wash | cleans tableware is discharged from the heater which heats wash water, the injection pump which discharges the heated wash water, and an injection pump. An injection nozzle for injecting the washed water into the tableware, and a control means for controlling the heater to heat the wash water and for controlling the injection pump to control the injection of the wash water. The main cleaning means for executing the main cleaning process for injecting the liquid almost continuously, the preliminary cleaning means for executing the preliminary cleaning process for intermittently injecting cleaning water before the main cleaning process, and the preliminary cleaning process are executed. When the preliminary cleaning process is omitted, the execution time of the main cleaning process is extended as compared with the case of executing the preliminary cleaning process.

  According to this dishwasher, it is possible to improve the cleaning power by performing a preliminary cleaning process that intermittently drives the cleaning pump, but on the other hand, intermittent collision of the fountain on the tableware and the cleaning pump Noise is likely to occur due to intermittent operation. However, the ability to select whether or not to perform the pre-cleaning step can be selected, so that depending on the case, the pre-cleaning step can be performed to achieve high cleaning performance or the pre-cleaning step can be omitted to ensure quietness. This is convenient for the user. Furthermore, when omitting the preliminary cleaning step, it is possible to achieve both the ensuring of quietness and high cleaning performance by performing control to extend the execution time of the main cleaning step.

Furthermore, according to the invention concerning claim 1 , in the above-mentioned dishwasher, it is provided with a silent mode for reducing the jetting power of the washing water in the main cleaning step, and the control means is configured to set the silent mode when the silent mode is set. The pre-cleaning process is omitted. As a result, in the silent mode where high silence is required, not only the noise in the main cleaning process is suppressed by lowering the jetting power of the cleaning water, but also the pre-cleaning process with high noise is omitted. Can better meet your needs. Further, high cleaning power can be secured by extending the cleaning time described above.

According to the invention according to claim 2 , in the above-described dishwasher, the control means further includes a reservation timer that delays the start time of the main cleaning step when set, and reserves when the reservation timer is set. The cleaning process is omitted. According to this configuration, quietness can be ensured by omitting the noisy preliminary cleaning step when setting a reservation timer that is likely to be driven while the user is sleeping. Further, high cleaning power can be secured by extending the cleaning time described above.

According to the invention according to claim 3, in dishwashing machine according to claim 1, the control means includes a reservation timer to delay the start time of the main cleaning process is set, the first washing course, the first Means for selecting any one of the second cleaning courses having a higher cleaning ability than the cleaning course, means for selecting any one of the silent mode and the normal mode; When the cleaning course is selected and the reservation timer is set, when the normal mode is selected, the preliminary cleaning process is executed, and when the silent mode is selected, the preliminary cleaning process is omitted and the normal mode is selected. The execution time of this cleaning process is extended from time to time.

  According to this configuration, even when the reservation timer is set, if the user selects a cleaning course that requires high cleaning power, the preliminary cleaning process is executed unless the user selects the silent mode. In the case where the high cleaning power is secured and the silent mode is selected, the preliminary cleaning process is omitted and the execution time of the main cleaning process is extended, so that the high cleaning power can be secured while ensuring the quietness. This increases the number of options that can better satisfy the user's needs, and is convenient.

According to the invention according to claim 4 , in the dishwasher according to claim 1 or 2 , the preliminary washing step includes a steaming step, and the control means supplies the washing water while heating the washing water in the steaming step. The first intermittent injection cycle of intermittently injecting for one injection time and then stopping for the first stop time is repeated a plurality of times, and washing water is supplied during the first injection time in the first intermittent injection cycle. The second intermittent injection cycle of injecting for a second injection time shorter than the first injection time and then stopping for a second stop time shorter than the first injection time is repeated a plurality of times.

  According to this configuration, in the steaming step in the preliminary cleaning step, the double intermittent injection operation in which the second intermittent injection cycle is inserted into the first intermittent injection cycle is repeated. According to this double intermittent jet operation, the amount of washing water that touches low-temperature tableware is small, so heat exchange between the jetted washing water and tableware is suppressed, the temperature drop of the washing water is suppressed, and washing water is easy Can be heated to high temperatures. By spraying this high-temperature washing water, the atmosphere in the washing tank can be brought into a hot and humid state in a short time. Accordingly, starch stains on the surface of the tableware can be effectively swollen in a short time, and high detergency can be obtained. On the other hand, in the double intermittent injection operation performed in the steaming process, the injection is repeated in a very short period and the injection force becomes high, so the problem of noise becomes significant. The significance of saving the steaming process in areas where there is a high demand for silence is extremely significant.

According to the invention according to claim 5 , in the dishwasher according to claim 1 or 2 , the preliminary cleaning step includes an initial cleaning step and a steaming step executed after the initial cleaning step is completed, and the initial cleaning step Is set to be longer than the intermittent injection time of the cleaning water in the steaming process.

  According to this configuration, the initial washing process in which intermittent spraying is performed in a longer time than the steaming process can remove vegetable pieces and other large leftovers on the tableware before starting the steaming process, so that the tableware surface adheres more strongly. Troublesome dirt can be exposed, and the effect of swelling the dirt in the subsequent steaming process can be exhibited more effectively.

  According to the present invention, while improving the cleaning performance on the one hand, the silent performance can also be improved on the other hand, and the usability for the user can be improved.

  FIG. 1 is a cross-sectional view illustrating a configuration of a main part of a dishwasher according to an embodiment of the present invention.

  In FIG. 1, reference numeral 1 indicates the housing of the dishwasher according to the present embodiment, the left side of the housing 1 in the figure is the front of the dishwasher, and the right side is the back of the dishwasher. It is. There is a region for storing cleaning water 22 at the bottom of the housing 1, and a cleaning heater 2 for heating the cleaning water 22 is provided in the region. Most of the area in the casing 1 above the area is a washing tank 18 for washing and drying the tableware 19.

  A cupboard 3 for placing tableware 19 is provided at the bottom of the washing tub 18. Immediately below the cupboard 3, an injection nozzle 4 for injecting cleaning water into almost the entire region of the cleaning tank 18 is arranged. A water outlet of a cleaning pump 5 that sucks and discharges cleaning water is connected to the spray nozzle 4. The water suction port of the cleaning pump 5 opens into a region for storing the cleaning water 22 at the bottom of the housing 1. A water level sensor 7 for measuring the water level of the cleaning water 22 is provided in the vicinity of the rear wall of the cleaning tank 18.

  A drying fan 10 that sucks outside air and blows dry air is also provided in the housing 1. A drying heater 11 that heats the drying air is provided downstream of the blower outlet of the drying fan 10. The drying air blown from the drying fan 10 is heated by the drying heater 11 and then supplied into the cleaning tank 18 from behind the cleaning tank 18. An exhaust port 12 is provided in the upper part of the front surface of the cleaning tank 18. A door 13 for opening the cleaning tank 18 is provided on the front wall of the housing 1. Although not shown in FIG. 1, a water supply valve for controlling the supply of cleaning water into the housing 1, a drainage valve for controlling the drainage of cleaning water from the housing 1, and Alarms and the like for notifying the user of the state of the dishwasher are also provided at appropriate positions.

  An operation panel 9 is provided on the bottom of the outer surface of the housing 1, and various buttons that can be operated by the user and various displays for notifying the user of the operation results of these buttons are provided. A control device 8 is provided behind the operation panel 9. The control device 8 controls the cleaning heater 2, the cleaning pump 5, the drying fan 10, the drying heater 11, the water supply valve (not shown), the drain valve (not shown) and the like in response to the button operation on the operation panel 9. Then, the dish washing operation and the table drying operation are controlled.

  Further, a water level sensor 7 for measuring the water level of the cleaning water 22 is provided in the vicinity of the rear wall of the cleaning tank 18. An air temperature sensor 15 for detecting the temperature of the drying air is provided downstream of the drying heater 11. A water / air temperature sensor 16 is provided in the vicinity of the washing heater 2, which detects the temperature of the washing water 22 when washing dishes, and measures the temperature of the washing tank 18 when drying dishes. A door switch 17 that detects the open / closed state of the door 13 is provided in the vicinity of the door 13. Output signals from the water level sensor 7, the water / air temperature sensor 16, the air temperature sensor 15, and the door switch 17 are input to the control device 8 described above, and are used for controlling the dish washing operation and the table drying operation.

  FIG. 2 shows the configuration of the control device 8 of the dishwasher.

  As shown in FIG. 2, the control device 8 includes a CPU 30 that is programmed in advance and executes a control program (not shown), and interface circuits 31 and 32 that are connected to an external device to input and output signals. The interface circuit 31 is connected to the water level sensor 7, the air temperature sensor 15, the water / temperature sensor 16, the door switch 17 and the operation panel 9, and inputs signals from these devices, and detection data corresponding to the input signals or user requests Is output to the CPU 30. The CPU 30 receives the detection data or the user request from the interface circuit 31 by executing the control program, and executes the control program in response to the control command or the control command for controlling the dish washing operation and the dish drying operation. The control data is output to the interface circuit 32. The interface circuit 32 is connected to the drying fan 10, the cleaning pump (motor that drives the pump) 5, the drying heater 11, the cleaning heater 2, the alarm device 33, the water supply valve 34, the drainage valve 35, and the like. Alternatively, these devices are driven and controlled in response to control data.

  FIG. 3 shows various buttons and indicators provided on the operation panel 9 of the dishwasher.

  As shown in FIG. 3, on the operation panel 9, a power button 41 for turning on and off the main power of the dishwasher, a start button 42 for starting and pausing the dishwasher, A course button 43 for selecting an arbitrary course from a plurality of cleaning courses, a mode related to silent performance, that is, a silent button 45 for selecting one of a silent mode with high silent performance and a normal mode that is not so. A drying button 47 for selecting an arbitrary course from among the drying courses, a reservation button 48 for reserving the start time of dishwashing, and a ventilation button 50 for selecting an arbitrary course from a plurality of ventilation courses Etc. are provided.

  The course button 43 allows the user to select a course desired by the user from among five types of cleaning courses of “short time”, “no detergent”, “standard”, “high power”, and “bleaching”. Different cleaning courses have different control conditions for the main cleaning step and / or the preliminary cleaning step, which will be described later, which will be described in detail later. Which course is selected is displayed on the course display 44. In addition, when one of the cleaning courses selected among “short time”, “no detergent”, “standard” and “high power” is selected, the silent mode or the normal mode is further selected for quietness. The silent button 45 can be selected. The silent button 45 is turned on when the silent mode is selected, and is turned off when the normal mode is selected. Even when the same cleaning course is selected, the control conditions differ depending on whether the mode is silent mode or normal mode. Considering this difference in mode, there are nine cleaning options. When one of the cleaning courses is selected, the selected cleaning course is started as soon as the start button 42 is pressed, and when a reservation course to be described later is selected, it is set from the reservation setting time. The operation schedule is controlled so that the main cleaning process (described later) of the selected cleaning course is started when the time has elapsed.

  By using the drying button 43, a course desired by the user can be selected from among four types of drying courses of “30 minutes”, “60 minutes”, “fan”, and “altitude”. The “30 minutes” and “60 minutes” courses are courses in which heated dry air is allowed to flow for 30 minutes and 60 minutes, respectively. The “blower” course is a course in which dry air at room temperature that is not heated is continuously flowed. In addition, as described in detail later, the “highly dry” course was judged to be highly dry by determining whether or not the tableware was highly dried while intermittently flowing heated drying air. It is a course that sometimes stops the drying operation automatically. Which drying course is selected is displayed on the drying indicator 46.

  The reservation button 48 can be used to set reservations having two types of standby times “after 2 hours” and “after 4 hours”. The reservations “after 2 hours” and “after 4 hours” are courses in which waiting times of 2 hours and 4 hours are set in a reservation timer (not shown) in the control device 8, respectively. Which reservation is set is displayed on the reservation display 49. When any cleaning course is selected and a reservation is set, the operation schedule is set so that the main cleaning process (described later) in the selected cleaning course is started when the set waiting time has elapsed since the reservation was set. Is controlled. If the start button 42 is pressed without setting a reservation, the selected cleaning course is started immediately.

  With the ventilation button 50, two types of ventilation courses of “continuous” and “8 hours” can be selected. The “continuous” course is a course in which the washing tank 18 is continuously ventilated until the power is turned off or temporarily stopped, and the “8 hours” course is a course in which ventilation is continuously performed for 8 hours. . Which ventilation course has been selected is displayed on the ventilation indicator 51.

  FIG. 4 shows a modified example of the buttons on the operation panel 9 and the display that can be used instead of the one shown in FIG.

  In the modification shown in FIG. 4, in addition to the five cleaning courses described above, a “silent” course can be selected by the course button 43 as the sixth cleaning course. In this “silent” course, the cleaning control conditions are set so that the quietness is improved as compared with the other five cleaning courses.

  Next, the operation of the dishwasher according to this embodiment will be described. In the following description, it is assumed that a cleaning course, a silent mode and a normal mode, a drying mode, and a reservation can be set using the operation panel 9 having the configuration shown in FIG.

  First, the operation of the cleaning course will be described.

  The cleaning course basically includes four steps of “hot water supply step”, “preliminary cleaning step”, “main cleaning step” and “drainage step” which are sequentially executed in this order. However, as will be described in detail later, the preliminary cleaning step may be omitted.

  In the first “hot water supply process”, a predetermined amount of hot water (washing water) having a predetermined temperature (for example, 60 degrees Celsius) is introduced into the dishwasher and stored in the housing 1. As shown in FIG. 1, the water inlets of the cleaning heater 2 and the cleaning pump 5 are submerged under the cleaning water 22 in the housing 1.

  In the subsequent “preliminary cleaning step”, the cleaning water 22 in the housing 1 is heated by the cleaning heater 2 so that the temperature of the cleaning water 22 becomes a predetermined target temperature (about 60 to 65 degrees Celsius, for example, 65 degrees Celsius). The intermittent injection operation of intermittently injecting the cleaning water from the injection nozzle 4 by intermittently driving the cleaning pump 5 is performed for a predetermined number of cycles. The basic role of the pre-cleaning process is to first remove large pieces of dirt such as vegetable scraps adhering to the tableware 19 and then to heat up the starch stains on the surface of the tableware 19 and swell it with moisture. It is to make it easy to remove dirt from starch. Here, the target temperature of washing water (about 60 to 65 degrees Celsius, for example, 65 degrees Celsius) is lower than the temperature for solidifying protein stains (about 70 degrees Celsius), and the starch stains are swollen. The temperature is selected from the viewpoint of a temperature suitable for the temperature (about 60 degrees Celsius or more). As will be described in detail later, in the preliminary cleaning step in the present embodiment, in order to achieve the above-mentioned role as quickly as possible in a short time, an intermittent injection operation by a novel method is adopted.

  In the subsequent “main cleaning step”, the cleaning water 22 in the housing 1 is heated by the cleaning heater 2 so that the temperature of the cleaning water 22 becomes a predetermined target temperature (about 50 to 55 degrees Celsius, for example, 55 degrees Celsius). In this way, a continuous spraying operation is performed in which the cleaning pump 5 is driven almost continuously to spray the cleaning water from the spray nozzle 4 almost continuously. The role of this cleaning step is to remove all soils such as starches, oils and proteins. Here, the target temperature (about 50 to 55 degrees Celsius, for example, 55 degrees Celsius) of the cleaning water in the main cleaning step is a temperature at which the detergent exhibits the most cleaning effect (about 50 to 60 degrees Celsius) (hereinafter, “ "Optimum cleaning temperature").

  In the final “drainage process”, the washing water 22 in the housing 1 is discharged out of the dishwasher.

  The above is the basic operation of the cleaning course, but an operation different from this may be performed. That is, the control device 8 of the dishwasher performs various control conditions in the cleaning course, such as the presence or absence of a pre-cleaning step, the intermittent injection operation of the pre-cleaning, depending on the selection of the silent / normal mode and the presence or absence of the reservation setting. The number of cycles, the execution time of the main cleaning process, etc.) are changed. FIG. 5 shows a control condition table in each cleaning course controlled by the control device 8.

  As shown in FIG. 5, it is possible to switch between two types of modes related to the silent performance, that is, the normal mode and the silent mode in which the performance is improved from the normal mode. In each silent mode, the standard mode, the high power mode, There are four types of cleaning options (no bleaching and short time) (the bleaching course described in FIG. 3 is omitted in FIG. 5), and there are a total of eight types of cleaning options. The “basic control condition” column in FIG. 5 shows the control condition adopted for each cleaning option when no reservation is set, and the “correction of control condition at the time of reservation” column shows a reservation. When the setting is made, correction points (differences) from the “basic control conditions” of the control conditions adopted for each cleaning option are shown.

  Here, the standard course is a course that exhibits standard detergency. The high power course is a course that exhibits the highest cleaning power, and the execution time of the main cleaning process is set to be significantly longer (for example, twice) than the standard course. The course without the detergent is a course in which the main cleaning process is performed without using the detergent, and the execution time of the main cleaning process is slightly longer than the standard course in order to compensate for a decrease in the cleaning power due to the absence of the detergent (for example, 2 Set). The short course is a course in which the cleaning course is completed in a very short time instead of having the weakest cleaning power. The preliminary cleaning process is omitted, and the execution time of the main cleaning process is significantly shorter than the standard course (for example, 3 Set to 1 / minute).

  As can be seen from the “basic control condition” column in FIG. 5, in the silent mode, the preliminary cleaning step is omitted in any cleaning course in order to improve the silent performance as compared with the normal mode. In the preliminary cleaning process, intermittent cleaning water injection is performed, so that noise due to intermittent switching of the cleaning pump 5 and intermittent collision of the spray water to the tableware is larger than in the main cleaning process in which continuous cleaning water injection is performed. Because. Further, in the silent mode, although not shown in FIG. 5, the noise output is improved also in the main cleaning step by lowering (for example, halving) the output power of the motor of the cleaning pump 5 from the normal mode. In addition, in the silent mode, the cleaning time for the main cleaning is set to be longer than that in the normal mode (for example, basically doubled and shorter in order to compensate for the decrease in the cleaning performance due to the improvement in the quietness). For courses other than the hour / hour course, additional time is added according to the course).

  By the way, for the short course, it is a course that should be applied to tableware with very light dirt, and it is desired to finish the course in a short time, so the pre-cleaning step that lengthens the course required time Is omitted and there is no additional extension time when in silent mode.

  As can be seen from the “Correction of control conditions at the time of reservation” column in FIG. 5, when the reservation setting is made, the preliminary cleaning process is omitted in most courses and the reservation setting is not made. Thus, the execution time of the main cleaning is extended by a predetermined time. The reason why the pre-cleaning process is omitted when the reservation setting is made is that the user often makes a reservation setting before going to bed so that the cleaning course and the drying course are completed when waking up. This is to prevent noise caused by noise and to ensure quietness. Further, the reason for extending the main cleaning time is to compensate for a decrease in cleaning ability due to omission of preliminary cleaning and a progress of adhesion of dirt due to waiting for a set time. Therefore, the extra time in this case is compensated for the extra time to compensate for the omission of pre-cleaning (ie, the extra time in the silent mode when no reservation is made), and also the contamination due to waiting. It is set to a value obtained by adding the extension time for Here, the extended time for compensating for adhesion of dirt due to standby is set to a longer value as the standby time is longer. The reason is that the longer the waiting time, the stronger the dirt adheres.

  By the way, in the case of the high power course, even if the reservation setting is made, the preliminary cleaning process is not omitted, and in return, the number of cycles of intermittent injection in the preliminary cleaning process is larger than that in the case where the reservation setting is not made ( For example, it is set to 2). The reason is that, in the high power course, a policy is adopted in which emphasis is placed on securing a high cleaning ability rather than enhancing the quietness. Therefore, a sufficient number of cycles is set for the pre-cleaning step so that even if the dirt adheres strongly during the waiting time, it can be surely swollen and removed.

  FIG. 6 is a timing chart showing how to control the temperature and jetting of the cleaning water in the hot water supply, pre-cleaning and main cleaning steps of the cleaning course.

  As shown in FIG. 6A (control process), in the cleaning course, a hot water supply process is performed first, followed by a preliminary cleaning process, and then a main cleaning process. Here, the preliminary cleaning process is composed of two sub-processes “initial cleaning process” and “high-speed steaming process” which are sequentially performed in this order. The initial cleaning process is a process for removing large pieces of dirt on the tableware (for example, leftovers such as vegetable pieces and meat pieces). The high-speed steaming process is a process for swelling and easily removing the most troublesome starch stains among the stains attached to the tableware surface exposed by removing large pieces of dirt.

  As shown in FIG. 6B (water supply valve), in the first hot water supply process, the water supply valve 34 is turned on (opened), and washing water at a predetermined temperature (for example, about 60 degrees Celsius) is introduced into the dishwasher. The washing water introduced here is retained in the dishwasher through the preliminary washing process and the main washing process.

  As shown in FIG. 6C (cleaning water target temperature), the cleaning water is heated by the cleaning heater 2 in the preliminary cleaning process and the main cleaning process. The target temperature of the cleaning water used in the cleaning water heating control is about 60 to 65 degrees Celsius in the preliminary cleaning process, for example, 65 degrees Celsius, and about 50 to 55 degrees Celsius in the main cleaning process, for example, 55 degrees Celsius. is there. A target temperature such as 65 degrees Celsius in the pre-cleaning process can swell starch soils (about 60 degrees Celsius or higher) and does not solidify protein soils (about 70 degrees Celsius or lower). The temperature is selected from the viewpoint of. On the other hand, the target temperature such as 55 degrees Celsius in the present cleaning process is a temperature selected from the optimum cleaning temperature (about 50 to 60 degrees Celsius) that can best utilize the ability of the detergent.

  As shown in FIG. 6D (cleaning pump), the cleaning pump 5 is operated in the preliminary cleaning process and the main cleaning process to inject cleaning water. In the main cleaning step, the cleaning pump 5 is substantially continuously operated and the cleaning water is sprayed continuously. However, a pause of a very short time (for example, 1 second) is entered at intervals of about several tens of seconds (for example, 30 seconds). In order to avoid the occurrence of a situation in which the water level of the cleaning water 22 in the housing 1 is excessively lowered and the cleaning pump 5 sucks air, this short pause is performed in order for the injected water to drop. This is to wait for the water level to rise. By the way, the reference number 56 indicates the start time of the main cleaning process, and when the reservation setting is made, the reserved time of “2 hours later” or “4 hours later” is the main cleaning start time. 56.

  On the other hand, in the preliminary cleaning process, the cleaning pump 5 is intermittently driven to perform intermittent injection operation of cleaning water. In particular, in the steaming step, this intermittent injection operation is a double intermittent injection operation in which a long cycle intermittent injection operation and a very short cycle intermittent injection operation are combined. . That is, as shown in FIG. 6D, in the steaming process, the injection operation is performed for a long first injection time (within 30 seconds, for example, 20 seconds) 54, and thereafter, significantly larger than the first injection time 54. The injection is stopped for a long first stop time 55 (90 seconds or longer, for example, 2 minutes) 55. Then, a plurality of cycles are repeatedly executed by setting one injection at the first injection time 54 and one injection stop at the first stop time 55 as one cycle of the intermittent injection operation.

  And the intermittent injection operation | movement of a very short period is performed within the 1st injection time 54 mentioned above. That is, as shown in detail in FIG. 7, during the second injection time 57 (within 1 second, for example 0.6 second) 57, which is significantly shorter than the first injection time 54, the cleaning pump 5 is driven in a pulsed manner to perform a pulsed washing water injection operation, and then a second stop time (within 1 second, for example, 0.8 seconds) which is also significantly shorter than the first injection time 54. During 58, the cleaning pump 5 is stopped. The set of the pulse injection at the second injection time 57 and the injection stop at the second stop time 58 is repeated many times over the first injection time 54.

  Refer to FIG. 6D again. Also in the initial cleaning process preceding the high-speed steaming process described above, a double intermittent injection operation similar to that in the high-speed steaming process is performed. However, the double intermittent injection operation in the initial cleaning process is performed for one cycle in the present embodiment, and the longer injection time 52 and the stop time 53 are respectively longer injection time 54 in the high-speed steaming process. And longer than the stop time 55. That is, in the initial cleaning step, an intermittent injection operation with a very short cycle is performed for a third injection time (for example, 40 seconds) longer than the first injection time 54, and thereafter, from the first stop time 55. The injection is stopped for a long third stop time 53 (eg 2 minutes 30 seconds). The intermittent injection operation with a very short cycle within the third injection time 54 may be based on a time setting different from that of the high-speed steaming process, but in this embodiment, it is the same as that of the high-speed steaming process. That is, the pulse injection at the second injection time 57 and the injection stop at the second stop time 58 shown in FIG. 7 are repeated many times.

  By adopting the above-described double intermittent injection operation with time setting, the conventional technique aims to increase the temperature to a temperature range (for example, about 60 degrees Celsius) suitable for swelling of starches in the high-speed steaming process. It becomes possible to achieve faster and in a shorter time. In addition, since a similar double intermittent injection operation is also performed in the initial cleaning process, the initial cleaning process achieves the original purpose of increasing the amount of cleaning water and washing away residual vegetables and the like that are large dirt pieces attached to the tableware. In addition, it contributes to achieving the swelling of starch stains in a short time, which is the purpose of the high-speed steaming process. In that sense, it can be said that the initial cleaning process is an extension of the high-speed steaming process. Incidentally, the number of cycles shown in FIG. 5 means the number of repeated cycles of the double intermittent injection operation throughout the preliminary cleaning step in which the initial cleaning step and the high-speed steaming step are connected.

  The reason why the above-described double intermittent injection operation with the time setting produces the above-described effect is as follows. That is, according to this double intermittent injection operation, since the amount of washing water sprayed is small, the amount of water exchanged with the tableware 19 by touching the tableware 19 is also reduced. Since the amount returned to the wash water storage chamber in the tank is also reduced, the temperature drop of the wash water is suppressed. Therefore, since the temperature of the cleaning water sprayed can be maintained at a high temperature, the ambient temperature in the cleaning tank 18 that rises with the spraying of the cleaning water can also be increased.

  In addition, while the injection amount is reduced, the injection force is increased by intermittent injection instead of continuous injection, so that when the injected cleaning water collides with the tableware, the water drops vigorously. Therefore, it is possible to wet the entire tableware even with a small amount of washing water, and since many fine water droplets are formed by splashing the washing water, the surface area is increased and the evaporation rate can be increased. Can be generated. Therefore, the atmospheric temperature in the cleaning tank 18 can be raised in a short time. Needless to say, since the temperature of the cleaning water is increased by jetting the cleaning water, the humidity of the atmosphere can be saturated quickly in a short time as the temperature rises, and the temperature of the cleaning water itself can be quickly set to the target temperature (for example, Celsius). 65 degrees). As a result, it is possible to reach a temperature suitable for swelling starch stains at a high speed in a short time.

  As is clear from the above, since the tableware 19 is not heated, the atmosphere in the washing tub 18 is sufficiently hot and humid even if the internal temperature of the tableware 19 is particularly low. The dirt such as starch attached to the surface can be surely swollen in a short time by touching the hot and humid air in the washing tank 18 without receiving heat from the tableware.

  FIG. 8 shows the results of experiments conducted by the inventors on the temperature rise of the atmosphere in the cleaning tank 18 when the above-described double intermittent injection operation and the injection operation according to the prior art are performed, respectively.

  In this experiment, in a state in which 62 dishes corresponding to the maximum load capacity are packed in a certain dishwasher and washing water of 60 degrees Celsius is stored, the above-described double intermittent injection operation and the related art The preliminary cleaning operation based on simple intermittent injection according to the above is performed. In the double intermittent injection operation, the first injection time 54 is 20 seconds, the first stop time 55 is 2 minutes, the second injection time is 0.6 seconds, and the second stop time is 0.8 seconds. Executed under. On the other hand, the injection operation according to the conventional technique is performed by a method of repeatedly stopping for a length of about several tens of seconds after the injection of a length of about several tens of seconds. In addition, although the conventional technique used general intermittent injection this time, the same tendency is observed in the conventional technique in which continuous injection is performed.

  In FIG. 8, the solid line graph 60 shows the change in the atmospheric temperature of the cleaning tank 18 when the double intermittent injection operation is performed for 8 minutes (4 cycles) under the above control conditions. On the other hand, the broken line graph 62 shows the tendency of the temperature change when performing the injection operation according to the conventional technique. As shown by the solid line graph 60, in the double intermittent injection operation, the ambient temperature of the cleaning tank 18 decreases from the initial hot water supply temperature of 60 ° C., but the injection amount is small and the time during which the injection is not performed is very long. It can be understood that the amount of decrease is significantly less than that of the prior art. In addition, each time intermittent injection is performed for the first injection time 54, the temperature rapidly increases, and thereafter, the temperature gradually decreases until the next injection is performed. Further, as the cycle becomes the second half, the temperature of the cleaning water sprayed surely becomes high due to the action of the heater, so that the ambient temperature in the cleaning tank 18 rises stepwise as shown in the figure. And when 8 minutes passed, it reached 55 degrees Celsius. On the other hand, according to the conventional jetting operation, since the amount of water is large and the heat exchange with the tableware is large, the washing water rapidly decreases to near the temperature of the tableware. Therefore, the temperature of the cleaning water injected is low and the ambient temperature does not increase. Further, since the cleaning water cooled by the tableware is returned to the cleaning water storage chamber in the cleaning tank 18 while the cleaning water is heated by the heater, the temperature rise of the cleaning water does not increase rapidly. Therefore, as shown in the broken line graph 62, the rate of temperature increase is lower than in the case of the double intermittent injection operation, and when 8 minutes have passed, it is 46 degrees Celsius (that is, about the temperature at the same point in the case of the double intermittent injection operation). Only 9 degrees lower). In order to reach the temperature at the lapse of 8 minutes in the case of the double intermittent injection operation, an operation time of about 14 minutes is required.

  In short, the present invention prevents the warming up to the inside of the tableware 19 even if the outer surface of the tableware 19 becomes the same as the washing water by the newly found double intermittent injection. Thus, the temperature drop of the washing water is suppressed, and further, the evaporation rate is increased by this injection method, the amount of high-temperature steam generated is increased, and the atmosphere temperature of the washing tank 18 is rapidly increased. In contrast, in the conventional technology, the temperature of the cleaning water, the temperature of the tableware including not only the outer surface of the tableware but also the internal temperature, and all of the inside of the cleaning tank are substantially the same temperature. The temperature rise in the washing tank is delayed.

  As described above, it was confirmed from this experiment that the temperature of the atmosphere in the cleaning tank 18 can be increased at a higher speed than in the prior art by the double intermittent injection operation. By the way, in this experiment, tableware corresponding to almost the maximum load amount was packed in the dishwasher, but it is estimated that the number of tableware loads is considerably smaller in the actual use situation. Therefore, in an actual use situation, the double intermittent injection operation is performed for about 8 minutes or about 4 cycles, thereby raising the atmosphere of the washing tub 18 to a temperature of about 60 degrees Celsius or higher, and thus the surface of the tableware. It is thought that the soil of starch can be swollen well.

  In addition, when the preliminary cleaning process (high-speed steaming process) in which the double intermittent injection operation described above is repeated for a predetermined number of cycles is completed, the temperature of the cleaning water itself is equal to the target temperature (for example, 65 degrees Celsius) in the preliminary cleaning process. It has reached a temperature in the vicinity, and this temperature is higher than or substantially equivalent to the target temperature in the next main cleaning step, that is, the optimal cleaning temperature. Therefore, in the present embodiment, control is performed so that the cleaning water at the completion of the preliminary cleaning process is continuously used (that is, the cleaning water is not replaced) and the process moves to the main cleaning process. At the beginning of the main cleaning process, as described above, in the present invention, since the temperature inside the tableware 19 has not increased, the amount of heat of the cleaning water is deprived by the tableware 19 due to continuous injection of the main cleaning process. As a result, the temperature of the washing water decreases. However, as described above, since the temperature of the cleaning water is already higher than or almost equivalent to the optimal temperature for cleaning, the temperature of the cleaning water quickly reaches the optimal cleaning temperature. Can be reached. Incidentally, if the injection operation according to the prior art as shown by the broken line graph 62 in FIG. 8 is adopted in the preliminary cleaning process, the cleaning is performed at the time of completion of the preliminary cleaning process unless the preliminary cleaning process is performed for a very long time. The temperature of the water is likely to be lower than the optimal cleaning temperature, so it was expected that the old cleaning water would be drained once and new cleaning water of about 60 degrees Celsius was introduced before starting this cleaning process. There is a possibility that the power of cleaning cannot be demonstrated. Thus, the pre-cleaning process of the present embodiment adopting the double intermittent injection operation also in that it is not necessary to replace the cleaning water during the transition from the pre-cleaning process (high-speed steaming process) to the main cleaning process. The (high-speed steaming step) contributes to obtaining a desired cleaning effect in a short time.

  Furthermore, the double intermittent injection operation in the pre-cleaning process not only swells starch stains in a short time, but also has an additional advantage of removing dirt with a stronger spraying force than in the main cleaning step. Can also be played. This effect is particularly effective when the cleaning pump 5 has a characteristic in which the discharge pressure overshoots when the discharge pressure rises at the beginning of the start, that is, a pump having a region where the initial discharge pressure is higher than the discharge pressure during steady operation. Can be obtained when using. A typical example of a pump having such an overshoot characteristic and suitable for application to a dishwasher is a centrifugal pump driven by a capacitor starting single phase induction motor, which is generally used in a dishwasher. is there. In the case of using the cleaning pump 5 having such characteristics, when the pulse injection is performed for the second injection time (for example, 0.6 seconds) in the short cycle intermittent injection operation shown in FIG. Since the high region is effectively used, it is possible to obtain a higher injection force than in the case of continuous injection.

  FIG. 9 shows the principle of utilizing the region where the initial discharge pressure of the cleaning pump 5 is high in this way.

  As shown in FIG. 9, the discharge pressure of the cleaning pump 5 changes as shown in the graph 70 when the cleaning pump 5 is started, and the initial discharge pressure overshoots in the region 62 (becomes higher than the steady discharge pressure). The second injection time (for example, 0.6 seconds) 57 in the short cycle intermittent injection operation in the preliminary cleaning step overlaps with or includes the main portion of the region 62 having a high initial discharge pressure. Is set as follows. Therefore, in the pulse injection of the second injection time 57 (for example, 0.6 seconds) 57, a strong injection force with a discharge pressure higher than the steady discharge pressure is obtained, and the impinging force of the injected wash water on the tableware 19 is improved. . This strong impact force improves the ability to remove dirt from the tableware surface. Furthermore, in addition to the increase in impact force due to intermittent injection, if a stronger impact force can be obtained due to this pump characteristic, the amount of water splashing and colliding with tableware will increase, and water droplets will also become smaller. The speed is increased, the generation of high-temperature water vapor can be further increased, and the ambient temperature in the cleaning tank 18 can be increased more quickly.

  As described above, by adopting the preliminary cleaning process that performs the double intermittent injection operation, it is possible to obtain the same cleaning ability in a shorter time than in the case of the conventional technique, and the same time as in the case of the conventional technique. If thin, higher cleaning ability can be obtained. However, in the double intermittent injection operation, particularly in the short cycle intermittent injection operation as shown in FIG. 7, the cleaning pump 5 is frequently turned on and off in a short cycle, so that there is a problem in quietness. Therefore, as already described with reference to FIG. 5, when a predetermined cleaning option in which noise reduction is important is selected, the noise reduction is ensured by omitting the preliminary cleaning step. As a modification, instead of omitting the pre-cleaning step, the injection operation method of the pre-cleaning step is a method that is quieter than the double intermittent injection operation (for example, lowering the output power of the pump motor, For example, the injection time 54 may be changed to a continuous injection instead of a short cycle intermittent injection.

  Next, the operation of the drying course will be described. As already described with reference to FIG. 3, the drying course includes “30 minutes”, “60 minutes”, “fan” and “altitude” courses.

  FIG. 10 shows how the drying heater 11 and the drying fan 10 are controlled in the “60 minutes” drying course, and how the temperature of the cleaning tank 18 changes. As shown in FIG. 10, in the “60 minutes” drying course, the drying fan 10 is continuously driven for 60 minutes, and the drying heater 11 is continuously driven to heat the drying air for cleaning. The temperature of the tank 18 is maintained substantially constant at a predetermined target temperature. The operation other than the execution time is the same for the “30 minutes” course. In the “air blowing” course, the drying heater 11 is not driven. In the control of these courses, the degree of drying of the tableware 19 is not considered at all.

  On the other hand, in the “advanced” drying course, it is periodically determined whether the tableware 19 is highly dried. If the determination result is negative, the drying course is further continued. If the determination result is positive, At that time, control is performed to automatically end the drying course. Hereinafter, the control of this “advanced” drying course will be described in detail.

  FIG. 11 shows how the drying heater 11 and the drying fan 10 are controlled in the “altitude” drying course, and the temperature change in the cleaning tank 18.

  As shown in FIG. 11, the drying fan 10 is continuously driven, and the drying air is continuously blown out. In parallel with this, the drying heater 11 is continuously driven for a predetermined heating time (for example, 28 minutes) 80 to control the temperature of the cleaning tank 18 to a predetermined target temperature, and thereafter, the predetermined heating is performed. During the stop time (for example, 2 minutes) 82, the drying heater 11 is stopped, and an intermittent drying operation is performed in which heating of the drying air is stopped. Then, a set of the heating operation for one heating time 80 and the heating stopping operation for one heating stop time 82 is set as one cycle of the intermittent drying operation, and a plurality of cycles are repeatedly executed.

  As shown in the graph 84, the temperature of the cleaning tank 18 is kept substantially constant during the heating time 80, but falls monotonically with the passage of time during the heating stop time 82. Here, it is considered that the temperature drop of the washing tank 18 during the heating stop time 82 corresponds to the temperature drop of the tableware 19 during the heating stop time 82. As the number of cycles increases, the temperature drop amounts ΔH1, ΔH2, and ΔH3 during the heating stop time 82 monotonously decrease. The reason will be described with reference to FIG.

  FIG. 12 shows changes in the heat capacity of the tableware 19 and the water adhering to the tableware 19 as the cycle of the intermittent drying operation is repeated.

  As shown in FIG. 12, the heat capacity 92 of the tableware 19 itself is unchanged, but the amount of water adhering to the tableware 19 decreases as it goes to a later cycle. It decreases as you go to a later cycle. Therefore, the substantial heat capacity of the tableware 19 including the attached water decreases as the cycle proceeds. Therefore, as shown in FIG. 11, the lowering of the temperature ΔH1, ΔH2, ΔH3 of the cleaning tank 18 during the heating stop time 82 becomes smaller as the cycle is later.

  As illustrated in the fourth and fifth cycles in FIG. 12, when the tableware 19 is highly dried and there is almost no adhering water, the reduction in heat capacity described above no longer occurs. As a result, even if it becomes a later cycle, the amount of temperature drop in the cleaning tank 18 during the heating stop time 82 hardly changes. Therefore, in the present embodiment, the control device 8 reduces the temperature drop in the cleaning tank 18 during the heating stop time 82 in a predetermined cycle (for example, each cycle after the second cycle) among a plurality of cycles of the intermittent drying operation. (Temperature drop width or temperature drop rate during a certain period of time, etc.) is compared with that of the previous cycle, and it is determined whether or not the difference in temperature drop amount between both cycles is within a predetermined threshold. If the determination result is negative, another cycle is added and the drying course is continued. If the determination result is affirmative, the drying course is terminated at that time. By this control, it is possible to judge whether or not the tableware 19 is highly dried more accurately than in the prior art, and at the time of high drying, the drying course can be terminated without further continuing the extra drying course. .

  FIG. 13 shows a detailed flow of the control of the advanced drying course performed by the control device 8.

  As shown in FIG. 13, it is checked whether the “advanced” drying course is selected (step S1). If the determination result is yes, the drying heater 11 and the drying fan 10 are turned on and the nth (first time) The heating operation of the cycle of n = 1) is started (S2). The first timer T1 starts time counting simultaneously with the start of the heating operation, and then when the first timer T1 counts a predetermined heating time (for example, 28 minutes) 80 (Yes in S3), the drying heater 11 is turned off. (The drying fan 10 remains on). Thereby, the heating operation in the n-th cycle is completed (S4).

  Simultaneously with the end of the heating operation, the temperature value H1 of the cleaning tank 18 is read (S57). Simultaneously with the end of the heating operation, the second timer T2 and the third timer T3 start counting time, and then the second timer T2 counts a predetermined intermediate check time (for example, 30 seconds) (Yes in S5). The temperature value H2 of the cleaning tank 18 is read (S7). By the way, the temperature value of the washing tank 18 can be obtained from the output signal of the water / temperature sensor 16 shown in FIG. The water / air temperature sensor 16 is submerged in the cleaning water 22 during the cleaning course and is used to measure the temperature of the cleaning water 22. However, the cleaning water 22 does not exist in the housing 1 during the drying course. This is because it exists in the atmosphere of the cleaning tank 18. Thus, the cost of the dishwasher can be reduced by using the water / air temperature sensor 16 both for measuring the temperature of the washing water and measuring the temperature of the washing tub 18. Of course, a separate temperature sensor is provided in another part of the cleaning tank 18 or the exhaust port 12, and the temperature sensor is used or the temperature sensor and the water / temperature sensor 16 are used. You may measure the temperature.

  Now, after the temperature value H2 after the intermediate check time has elapsed in step S7 above, the difference H1-H2 between the temperature value H1 before the intermediate check time has elapsed and the temperature value H2 after the elapsed time is calculated. It is checked whether H1-H2 is greater than a preset direct wind influence determination threshold value Hc (S8). If the result of the check is yes, the dry wind is directly applied to the tableware 19 and the tableware 19 cools faster than the tableware 19 naturally cools in the absence of wind (hereinafter referred to as “direct wind effect”). In this case, the control proceeds to step S16. On the other hand, if it is determined that there is no direct wind influence (No in S8), the control proceeds to step S9.

  In step S9, it is checked whether the third timer T3 has counted a predetermined heating stop time (for example, 2 minutes) 82. When the heat stop time has elapsed (Yes in S9), the temperature value H3 of the cleaning bath 18 is set. Read (S10). Then, the difference between the temperature value H1 before the elapse of the heating stop time (for example, 2 minutes) 82 and the temperature value H3 after the elapse of time, that is, the temperature drop amount ΔHn (= H1−H3) during the heating stop time 82 is calculated. Is memorized (S11). If the current cycle is the predetermined cycle (for example, each cycle after the second cycle), the control proceeds to step S12, where the temperature drop amount ΔHn−1 calculated in the previous cycle is determined. Then, a predetermined drying completion determination threshold value Han corresponding to the current cycle is read. Then, the difference ΔHn-1−ΔHn between the temperature drop amounts ΔHn−1 and ΔHn in the previous and current cycles is calculated, and whether the absolute value of the temperature drop amount difference ΔHn−1−ΔHn is larger than the drying completion determination threshold value Han. Checked (S13).

  Here, the drying completion determination threshold value Han means that the difference between the temperature drop amounts ΔHn-1 and ΔHn in the previous and current cycles ΔHn-1−ΔHn is within the drying completion determination threshold value Han. It is a reference value that can be regarded as dry. FIG. 14 shows an example of the drying completion determination threshold value Han. As shown in FIG. 14, the drying completion determination threshold value Han differs depending on the cycle to which it is applied, and is set to a smaller value in the earlier cycle and a larger value in the later cycle. The reason for this is that the earlier the cycle, the lower the possibility that the tableware 19 will be highly dried, and the more likely that the later cycle is, so the condition for determining the completion of drying is more stringent than the earlier cycle, This is to make it sweeter in later cycles. As a modified example, only the first drying completion determination threshold value Han may be made smaller than other drying completion determination threshold values Han, or the same value of the drying completion determination threshold value Han may be applied to any cycle.

  Now, if the result of the check in step S13 described above is yes, it means that the tableware 19 is not yet highly dried. In that case, it is checked whether the number of times of the current cycle has reached a predetermined maximum number N (for example, 6 times) (S14). If the result is YES, the drying course is ended (S23). Otherwise, one cycle of intermittent drying operation is added (S15), and the drying course is continued by returning the control to step S1. On the other hand, if the result of the check in step S13 described above is no, it means that the tableware 19 has been highly dried. Therefore, the control proceeds to step S23, and the drying course ends.

  Although not shown, if the current cycle is not the predetermined cycle described above (for example, each cycle after the second cycle), after storing the temperature drop amount ΔHn of the current cycle in step S11 described above, The control passes the above-described determination of the temperature drop amount difference between steps S12 and S13, and jumps to step S14 described above.

  As a result of the check in step S8 described above, if it is determined that there is a direct wind influence (Yes in S8), the control proceeds to step S16, and the third timer is set to the heating stop time (for example, 2 minutes). It is checked whether a predetermined time shorter than 82 (for example, 100 seconds shorter than 2 minutes by 20 seconds) is counted, and when the predetermined time is counted (Yes in S16), not only the drying heater 11 but also the drying fan 10 Stop and eliminate direct wind effects (S17). Thereafter, a state where there is no direct wind influence continues for a predetermined time (for example, 20 seconds), and after the direct wind influence is corrected, the heating stop time 82 elapses (Yes in S18). When the heating stop time 82 elapses, the temperature value H4 of the washing tank 18 is read (S19), and the heating stop time is calculated from the temperature value H1 before the heating stop time 82 and the temperature value H4 after the heating stop time 82 elapses. The temperature drop amount ΔHn (= H1−H4) in 82 is calculated and stored (S20). If the current cycle is the predetermined cycle described above (for example, each cycle after the second cycle), the control proceeds to step S21, where the amount of temperature drop ΔHn−1 calculated in the previous cycle is determined. Then, a predetermined drying completion determination threshold value Hbn at the time of direct wind influence corresponding to the current cycle is read. Then, the difference ΔHn-1−ΔHn between the temperature drop amounts ΔHn-1 and ΔHn in the previous and current cycles is calculated, and the absolute value of the temperature drop amount difference ΔHn-1−ΔHn is determined as the completion of drying under the direct wind influence. It is checked whether it is larger than the threshold value Hbn (S22).

  Here, the drying completion determination threshold value Hbn at the time of direct wind influence is a reference value having the same meaning as the already described drying completion determination threshold value Han, but is illustrated in FIG. 14 as illustrated in FIG. A value smaller than the drying completion determination threshold value Han is set. The reason for this is that the direct wind effect is when the amount of tableware 19 in the dishwasher is small and the gap is large, and therefore the amount of water adhering to the tableware 19 is small, and therefore between the cycles. This is because the difference in temperature drop is small.

  Now, if the result of the check in step S22 described above is yes, it means that the tableware 19 has not been highly dried yet, and control proceeds to step S14 described above. On the other hand, if the result of the check in step S22 described above is no, it means that the tableware 19 has been highly dried, and therefore the control proceeds to step S23 and the drying course ends. Although not shown, if the current cycle is not the predetermined cycle described above (for example, each cycle after the second cycle), after storing the temperature drop amount ΔHn of the current cycle in step S20 described above, The control passes the above-described determination of the temperature drop amount difference between steps S21 and S22, and jumps to step S14 described above.

  The above is the control flow of the advanced drying course. As a modified example, it is assumed that a plurality of predetermined cycles (for example, the first and second cycles) in the initial stage of the drying course are always executed, and whether or not the drying is completed in the subsequent cycles (for example, the third and subsequent cycles). It is also possible to determine whether or not the drying course has ended / continue by determining as described above. In that case, as illustrated in FIG. 16, for example, only a value for the third and subsequent cycles may be set as the drying determination threshold value Han (or Hbn).

  As another modification, the execution time of the advanced drying course may be controlled to be at least longer than a course that ends at a set time such as a “30 minutes” or “60 minutes” course. As a result, the user selects the course that ends at the set time when time is more important than the degree of drying of the tableware, and selects the advanced drying course when the priority is given to the degree of drying of the tableware. In addition, the course selection can be easily determined.

  As another modification, the drying fan 10 may be stopped during the heating stop time so that there is no direct wind influence.

  As mentioned above, although embodiment of this invention was described, this embodiment is only the illustration for description of this invention, and is not the meaning which limits the scope of the present invention only to this embodiment. The present invention can be implemented in various other modes without departing from the gist thereof.

Sectional drawing which shows the structure of the principal part of the dishwasher concerning one Embodiment of this invention. FIG. 3 is a block diagram showing a configuration of a control device 8. The front view which shows the button and display on the operation panel 9. FIG. The front view which shows the modification on the button on the operation panel 9, and a display. The figure which shows the variation of the control conditions of the cleaning course controlled by the control apparatus. The timing chart which shows the method of control of the temperature of a washing water and injection in the process of hot water supply of a washing course, preliminary washing, and main washing. The timing chart which shows the detail of the intermittent injection operation | movement of the very short period within the 1st injection time 54 shown by FIG. The figure which shows the experimental result investigated about the temperature rise of the atmosphere in the cleaning tank 18 at the time of implementing the double intermittent injection operation | movement like this embodiment, and the injection operation according to a prior art, respectively. The figure which shows the principle which utilizes the area | region where the initial discharge pressure of a washing pump is high. The timing chart which shows the control method of the drying heater 11 and the drying fan 10 in the "60 minutes" drying course, and the air temperature change of the washing tank 18. FIG. The timing chart which shows the control method of the drying heater 11 and the drying fan 10 in the "altitude" drying course, and the temperature change of the washing tank 18. The timing chart which shows the change of the heat capacity of the water which adhered to the tableware 19 this with the repetition of the cycle of intermittent drying operation | movement. The flowchart of control of the advanced drying course which the control apparatus 8 performs. The figure which shows the example of the threshold value Han used for drying completion determination. The figure which shows the example of the threshold value Hbn used for the completion determination of drying when there exists an influence of a direct wind. The figure which shows another example of the threshold value Han used for drying completion determination.

Explanation of symbols

1 Housing 2 Washing heater 3 Cupboard 4 Spray nozzle 5 Washing pump 5 Washing pump 7 Water level sensor 8 Control device 9 Operation panel 10 Drying fan 11 Drying heater 12 Exhaust port 13 Door 15 Air temperature sensor 16 Water / temperature sensor 17 Door switch 18 Washing tank 19 Tableware 22 Washing water 30 CPU
31 Interface circuit 32 Interface circuit 54 Injection time 55 Stop time 56 Main cleaning start time 57 Injection time 58 Stop time 62 High initial discharge pressure area 80 Heating time 82 Heating stop time

Claims (5)

In a dishwasher that jets wash water to wash dishes,
A heater for heating the washing water;
An injection pump for discharging the heated washing water;
An injection nozzle for injecting the wash water discharged from the injection pump into the tableware;
Control means for controlling the heater to heat the wash water, and controlling the jet pump to control the jet of the wash water;
With
The control means includes
A main cleaning means for performing a main cleaning step of spraying the cleaning water almost continuously;
Pre-cleaning means for performing a pre-cleaning step of intermittently spraying the cleaning water before the start of the main cleaning step;
A cleaning mode in which the main cleaning step is performed after the preliminary cleaning step is performed;
A silent mode for reducing the jetting power of the cleaning water in the main cleaning step;
With
Further, the control means omits the execution of the preliminary cleaning step performed before the start of the main cleaning step when the silent mode is executed, and executes the main cleaning step without the preliminary cleaning step, and executes the preliminary cleaning step. A dishwasher configured to execute the main cleaning step by extending the execution time of the main cleaning step so as to be longer than the execution time of the main cleaning step in the case of . In a dishwasher that jets wash water to wash dishes,
A heater for heating the washing water;
An injection pump for discharging the heated washing water;
An injection nozzle for injecting the wash water discharged from the injection pump into the tableware;
Control means for controlling the heater to heat the wash water, and controlling the jet pump to control the jet of the wash water;
With
The control means includes
A main cleaning means for performing a main cleaning step of spraying the cleaning water almost continuously;
Pre-cleaning means for performing a pre-cleaning step of intermittently spraying the cleaning water before the start of the main cleaning step;
A cleaning mode in which the main cleaning step is performed after the preliminary cleaning step is performed;
A reservation timer to be set delaying the starting time of the main cleaning step
With
Further, when the reservation timer is set , the control means omits the execution of the preliminary cleaning process in the cleaning mode in which the main cleaning process is performed after the preliminary cleaning process is performed, and the main cleaning process is performed without the preliminary cleaning process. The cleaning process is executed, and the main cleaning process is executed by extending the execution time of the main cleaning process to be longer than the execution time of the main cleaning process when the preliminary cleaning process is executed. Have
A dishwasher characterized by that. The dishwasher according to claim 1 ,
The control means includes
A reservation timer that delays the start time of the main cleaning step when set;
Means for selecting one of the first cleaning course and the second cleaning course having a higher cleaning ability than the first cleaning course;
Means for selecting one of the silent mode and the normal mode;
In addition, when the second cleaning course is selected and the reservation timer is set,
When the normal mode is selected, the preliminary cleaning step is executed,
When the silent mode is selected, the preliminary cleaning step is omitted, and the execution time of the main cleaning step is extended from when the normal mode is selected.
A dishwasher characterized by that. The dishwasher according to claim 1 or 2 ,
The preliminary cleaning step includes a steaming step,
In the steaming step, the control means performs a plurality of first intermittent injection cycles in which the cleaning water is heated and intermittently injected during the first injection time and then stopped during the first stop time. And after the first injection time in the first intermittent injection cycle, the cleaning water is injected for a second injection time shorter than the first injection time and then shorter than the first injection time. Repeating the second intermittent injection cycle of stopping for two stop times a plurality of times,
A dishwasher characterized by that. The dishwasher according to claim 1 or 2 ,
The preliminary cleaning step includes an initial cleaning step, and a steaming step performed after the initial cleaning step is completed,
The injection time of the intermittent injection of the cleaning water in the initial cleaning step is longer than the injection time of the intermittent injection of the cleaning water in the steaming step.
A dishwasher characterized by that.

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