JP5786676B2 - Cooking device - Google Patents

Description

  The present invention relates to a cooker capable of producing bread and the like mainly in a general household.

  As a cooker for producing bread from rice, for example, Patent Document 1 discloses a bread maker that pulverizes rice into a paste by milling, kneading to make bread dough, and baking and finishing the bread.

  Cookers that make bread from leftovers are also known. This is a mixture of rice and water at the same time, kneaded to make bread dough, baked and finished into bread.

JP 2011-45410 A

  However, in the former case, there is a problem of noise when the rice is crushed by a mill, and in the latter case, there is a trouble of preparing rice in advance and putting in the rice.

  In view of the above problems, an object of the present invention is to provide a cooking device that can achieve a reduction in noise and can be finished in a bread without the trouble of putting rice.

In the invention of claim 1, since the dough is made with rice cooked from rice instead of pulverizing the rice put into the container, without using a mill for crushing rice, Low noise can be achieved. In addition, pre-cooked rice is not required, and if rice is prepared, it can be made into bread and the labor of putting rice can be omitted. Furthermore, by providing the first heating means for heating the side portion of the container and the second heating means for heating the lower portion of the container, it is possible to heat the bottom of the container where the heat from the heating means is difficult to travel, By suitably using these first heating means and second heating means, it becomes possible to bake bread in the container more uniformly. Moreover, the baking of the optimal bread | pan or the cooking of rice can be performed by switching the heating to the container by a 1st heating means or a 2nd heating means as needed.

In the invention of claim 2, since the dough is made with rice cooked from rice instead of pulverizing the rice put into the container, without using a mill for crushing rice, Low noise can be achieved. In addition, pre-cooked rice is not required, and if rice is prepared, it can be made into bread and the labor of putting rice can be omitted. Furthermore, various breads and rice cakes can be easily created by selecting a specific course. In addition, it is possible to make either bread or rice from the food to be cooked in the container, and the functions of the home bakery and the rice cooker can be realized by one unit, so it is possible to provide a cooking device that is convenient and economical. .

In the invention of claim 3 , since the dough is made with rice cooked from rice, rather than pulverizing the rice put into the container, without using a mill for crushing rice, Low noise can be achieved. In addition, pre-cooked rice is not required, and if rice is prepared, it can be made into bread and the labor of putting rice can be omitted. Furthermore, since the inner lid prevents heat from escaping from the inside of the container, delicious rice can be cooked, and steam generated from the inside of the container is discharged from the hole of the inner lid to the outside of the container. Can be adjusted appropriately.

In the invention of claim 4 , by closing the space between the container storage portion and the container with the inner lid, it is possible to suppress the escape of heat from the heating means and efficiently cook rice.

In the invention of claim 5 , when the user selects and executes the “baking course from rice cooking”, it can be understood by alarm notification that the inner lid is attached to the container, and the usability as a cooker is improved. Further, when the user selects and executes the “cooking course”, the user can understand that the inner lid is not attached by alarm notification, and the usability as a cooker is improved.

  In the invention of claim 6, since yeast is automatically charged into the container at a predetermined timing from the charging device, a user-friendly cooker can be provided.

In the invention of claim 7 , since the dough is made with rice cooked from rice instead of pulverizing the rice put into the container, without using a mill for crushing rice, Low noise can be achieved. In addition, pre-cooked rice is not required, and if rice is prepared, it can be made into bread and the labor of putting rice can be omitted. Furthermore, when performing the “cooking course”, it is not necessary to bother to attach the kneading tool to the mounting part, and by using the cooking and baking containers in common, the usability can be improved and the cost can be reduced.

According to the first aspect of the present invention, it is possible to provide a cooking device that can achieve low noise and can be finished into bread without the need for rice. Moreover, it becomes possible to bake bread more uniformly in a container. Moreover, optimal baking of bread or cooking of rice can be performed.

According to the second aspect of the present invention, it is possible to provide a cooking device that can achieve low noise and can be finished into bread without the need for rice. In addition, various bread and rice cakes can be made easily. Moreover, since the functions of the home bakery and the rice cooker can be realized by one unit, it is possible to provide a cooking device that is convenient and economical.

According to the invention of claim 3 , it is possible to provide a cooking device that can achieve low noise and can be finished into bread without the trouble of putting rice. Moreover, delicious rice can be cooked, and the amount of steam released can be adjusted appropriately by the hole in the inner lid.

According to the invention of claim 4, to suppress the escape of heat from the heating means, it is possible to efficiently perform cooking.

According to the fifth aspect of the present invention, the ease of use as a cooking device can be improved by alarm notification.

  According to the invention of claim 6, since yeast is automatically charged into the container at a predetermined timing from the charging device, it is possible to provide an easy-to-use cooker.

According to the seventh aspect of the present invention, it is possible to provide a cooking device that can achieve low noise and can be finished into bread without the need for rice. Further, it is possible to improve usability and reduce costs as a cooking device.

It is the whole cooker longitudinal cross-sectional view in this invention. It is a whole longitudinal cross-section which shows another example of the cooking appliance of FIG. 1 same as the above. 3 is an enlarged cross-sectional view of the vicinity of the kneading tool mounting portion when the kneading tool is present in the cooking device shown in FIG. 3 is an enlarged cross-sectional view around the kneading tool mounting portion when there is no kneading tool in the cooking device shown in FIG. 3 is an enlarged cross-sectional view of a lid body portion in the cooking device shown in FIG. 1 and FIG. It is a block diagram which shows an electrical structure same as the above. It is a graph and timing chart which show the detection temperature of a temperature sensor, and the interruption state of each control object except a display body same as the above. It is a schematic sectional drawing of the cooking appliance equipped with the inner cover same as the above. FIG. 9 is a schematic cross-sectional view of a cooking device equipped with an inner lid of an example different from FIG. 9 is a graph showing the temperature change of each part when there is no inner lid in the cooking device of FIG. 9 is a graph showing the temperature change of each part when the inner lid is provided in the cooking device of FIG. FIG. 10 is a graph showing the temperature change of each part when the power consumption of the first heater is 360 W in the cooking device of FIG. 9. 10 is a graph showing the temperature change of each part when the power consumption of the first heater is 450 W in the cooking device of FIG.

  Hereinafter, preferred embodiments of a cooker according to the present invention will be described with reference to the accompanying drawings.

  1 and 2 are overall longitudinal sectional views of a cooking device having an automatic bread-making function in the present embodiment. The cooking device shown in FIG. 1 and the cooking device shown in FIG. 2 have the same configuration except for the heating means 8 described later.

  In each of these drawings, reference numeral 1 denotes a box-shaped main body, and an operation unit 2 is provided on the front upper surface of the main body 1. The operation unit 2 is instructed to start cooking, a reservation key that instructs to start cooking at a reserved time, a time adjustment key that enables adjustment of the current time and the reserved time, and an instruction to cancel various operations. The operation body 3 including a cancel key, a course selection key for selecting a specific cooking course from a plurality of cooking courses, the current time and / or reserved time, the selected cooking course, the operation state, and the like are displayed. Display bodies 4 such as LEDs and liquid crystal panels are provided.

  A bottomed cylindrical container storage chamber 6 is provided inside the main body 1. The container storage chamber 6 has an open top surface, from which the container 7 is placed. The container 7 is made of metal, is detachably attached to the main body 1, and is formed in a bottomed cylindrical shape having an open top surface, similar to the container housing portion 6. Heating means 8 is arranged inside the container storage chamber 6 so as to surround the container 7 stored in the container storage chamber 6. The heating means 8 is constituted by, for example, a sheathed heater, but in the cooking device shown in FIG. 1, the heating means 8 is constituted only by the first heater 8A provided facing the side portion of the container 7, and in the cooking device shown in FIG. One heater 8A and a second heater 8B provided below the first heater 8A and facing the lower part of the container 7 are configured.

  A base 11 is installed inside the main body 1. A container support portion 13 is fixed to the base 11 at a location corresponding to the center of the container storage chamber 6. The container support portion 13 has a concave shape that falls downward, and its inside is exposed to the inside of the container storage chamber 6. The container support part 13 receives the cylindrical base 14 fixed to the bottom surface of the container 7 and supports the container 7, and the base 14 is configured to fit into the container support part 13. A rotatable shaft portion 15 is vertically supported at the center of the container support portion 13. The lower end of the shaft portion 15 protrudes from the lower surface of the container support portion 13, and the shaft portion 15 is fixed to the center of the pulley 16.

  At the center of the bottom of the container 7, the upper end of the above-described shaft portion 15 is vertically supported after taking measures against sealing. In order to attach the kneading tool 18 to the shaft portion 15, a mounting portion 19 having a non-circular cross section of the shaft portion 15 is provided at the upper end of the shaft portion 15. 3 shows a state where the kneading tool 18 is mounted on the mounting portion 19 in the cooking device shown in FIG. 2, and FIG. 4 shows the cooking device shown in FIG. The kneading tool 18 has a plate-like blade 20 and a fitting portion 21 that can be attached to or detached from the mounting portion 19. Thus, the kneading tool 18 is detachably provided on the mounting portion 19. The mounting portion 19 positioned at the upper end of the shaft portion 15 protrudes upward from the center of the inner bottom surface of the container 7, and the kneading tool 18 can be easily attached or detached by inserting a hand from the upper surface opening of the container 7. be able to. Then, as shown in FIG. 3, when the shaft portion 15 rotates with the kneading tool 18 attached to the mounting portion 19, the blade 20 turns around the shaft portion 15 inside the container 7.

  A motor 24 serving as a drive source for the shaft portion 15 is attached and fixed to the base 11. A rotating output shaft 25 protrudes from the lower surface of the motor 24, and a pulley 26 is fixed to the output shaft 25. The pulley 26 is connected by a belt 27 to the pulley 16 to which the shaft portion 15 is fixed. The shaft 15 that rotates the kneading tool 18 is required to rotate at low speed and high torque. Therefore, the diameter ratio between the pulleys 16 and 26 is set so that the pulley 26 rotates the pulley 16 at a reduced speed.

  The upper surface of the main body 1 behind the operation unit 2 is covered with a lid 31. The lid 31 is attached to the back surface side of the main body 1 with a hinge shaft 32, and is configured to pivotably open and close the opening on the upper surface of the main body 1 with the hinge shaft 32 as a fulcrum. FIG. 5 is an enlarged view of the lid portion including the operation unit 2 and the lid 31 in common with the cooking device of FIGS. 1 and 2.

  The lid 31 includes an outer lid 34 that forms the skeleton of the lid 31, an outer lid cover 35 that covers the upper surface of the outer lid 34, and a lid lower surface plate 36 that is attached to the lower surface of the outer lid 34 and covers the upper surface opening of the container storage chamber 6. It consists of. In addition, a storage hole 38 penetrating vertically is formed in the substantially central portion of the lid 31 so as to face the upper surface opening of the container 7 stored in the container storage chamber 6. The storage hole 38 is equipped with a charging device 41 for automatically charging a powder such as yeast into the container 7 during cooking.

  The charging device 41 includes a powder container 42 for storing the powder, a powder container lid 43 that closes the upper surface opening of the powder container 42, and a charging port lid 44 that closes the lower surface opening of the powder container 42. The storage hole 38 is detachably provided. One side of the powder container lid 43 is attached to one side upper part of the powder container 42 by a hinge shaft 46, and the upper surface opening of the powder container 42 can be manually rotated to be freely opened and closed with the hinge shaft 45 as a fulcrum. It has become.

  The powder container 42 has a funnel shape in which the area of the lower surface opening serving as the powder outlet is narrower than the area of the upper surface opening serving as the powder storage inlet, and the lower part of the powder container 42 has a ring shape as an elastic member. A packing 46 is attached. The base end side of the charging port lid 44 is attached to one side lower part of the powder container 42 with a hinge shaft 48, and the distal end of the charging port cover 44 is engaged with a rotatable movable part 49 provided at the lower part of the powder container 42. When stopped, the upper surface of the charging port lid 44 presses the packing 46 so that the lower surface opening of the powder container 42 is sealed with the charging port lid 44.

  In the present embodiment, a solenoid 51 is disposed inside the main body 1 and an opening / closing lever 55 is disposed inside the lid 31 as a configuration in which the movable portion 49 of the input device 41 is movable with the lid 31 closed. Is done. The solenoid 51 is a drive source for switching the closing port cover 44 from the closed state to the open state, and includes a drive shaft 52 that can be moved in and out. The open / close lever 55 includes a lever main body 56 that is arranged coaxially with the drive shaft 52 and a coil spring 57 as an elastic body that biases the lever main body 56 toward the drive shaft 52. The tip of the lever body 56 is exposed toward the movable part 49. The movable portion 49 has an inverted L-shaped or V-shaped cross section, and includes a vertical piece 58 and a horizontal piece 59 orthogonal to the vertical piece 57. The elastic piece (not shown) causes the vertical piece 58 to be a lever body. The horizontal piece 59 is always biased to a position facing the tip of 56 and supporting the tip of the insertion port lid 44.

  When a predetermined operating voltage is supplied to the solenoid 51, the drive shaft 52 protrudes in the direction of the opening / closing lever 55 and hits the base end of the lever body 56, against the urging of the coil spring 57, and the vertical of the movable portion 49. The piece 58 is pressed. Then, as shown by the dotted line in FIG. 5, the movable piece 49 also rotates against the urging force of the elastic body (not shown), so that the engagement between the horizontal piece 59 and the insertion port lid 44 is released, and the insertion port lid 44 is It rotates with its own weight around the hinge shaft 48. Therefore, the powder housed in the powder container 42 is dropped into the container 7 located immediately below through the lower surface opening of the opened powder container 42.

  In addition, a temperature sensor 61 is provided inside the main body 1 as temperature detection means for detecting the temperature of the container 7 and converting it into an electrical detection signal, and heating means according to the detected temperature from the temperature sensor 61. For example, a control unit 62 such as a microcomputer is provided as a control means for adjusting the heating amount of 8. The temperature sensor 61 of the present embodiment is mounted on the outer surface of the container storage chamber 6 surrounding the container 7 and is configured to indirectly detect the temperature of the container 7, for example, elastically on the outer surface of the container 7. It is good also as a structure which makes it contact, and detects the temperature of a container directly.

  Here, in order to discharge steam generated from the inside of the container 7, a discharge path (not shown) that communicates between the container storage chamber 6 and the outside of the main body 1 is provided. The discharge path is provided with a fan 64 (see FIG. 6) as a blower, and when a predetermined operating voltage is supplied to the fan 64, steam generated from inside the container 7 is forcibly applied to the main body 1. It is configured to be discharged to the outside.

  Next, a control system related to the cooking device will be described with reference to FIG. In the figure, the control unit 62 includes an operating body 3, a temperature sensor 61, and an inner lid detection sensor 63 that are electrically connected to an input port. The inner lid detection sensor 63 is provided as an inner lid detection device that detects the presence or absence of an inner lid 81 to be described later and converts this into an electrical detection signal. Further, common to the cooker shown in FIGS. 1 and 2, the first heater driving circuit 65 for driving the first heater 8 </ b> A, the motor driving circuit 67 for driving the motor 24, and the solenoid 51 are driven. A solenoid drive circuit 68 for driving, a fan drive circuit 69 for driving the fan 64, and a display drive circuit 70 for driving the display body 4 are connected to the output port of the control unit 62, respectively. Further, in the cooker shown in FIG. 2, a second heater drive circuit 66 for driving the second heater 8 </ b> B is also electrically connected to the output port of the control unit 62. The first heater 8A and the second heater 8B are independently controlled by the control unit 62.

  Based on the operation signal from the operating body 3 and the detection signal from the temperature sensor 61, the control unit 62 reads out a program related to the cooking process built in the storage unit (not shown), and the first heater drive circuit 65. , A second heater drive circuit 66, a motor drive circuit 67, a solenoid drive circuit 68, and a display drive circuit 69 to send control signals to the first heater 8A, the second heater 8B, the motor 24, the solenoid 51, and the control target. Each of the display bodies 4 is controlled. Further, the control unit 62 bakes bread from rice grains such as glutinous rice grains as a bread generating means for generating bread from the cooked food in the container 7 in the program built in the storage section. The first bread baking control means 71 for executing the "course" and the second bread baking control means 72 for executing the "bread baking course from rice kneading" to bake bread from variously cooked grains as raw materials. And a third baking control means 73 for executing a “baking course from wheat flour” for baking bread from wheat flour, which is a kind of wheat, and in addition, rice grains such as glutinous rice grains in the container 7 as raw materials Mochi generation control means 74 for executing the “rice-kneading course from rice cooking” to generate rice cake, and “cooking rice cooking rice to cook rice from the food to be cooked in the container 7” A cooking control means 75 for performing a scan ", the are provided respectively. One of these cooking courses is selected by operating the course selection key of the operating body 3.

  Next, the operation of the cooking device having the above configuration will be described with reference to control data shown in FIG. In this figure, here, in the cooking of “rice bread” which is finished from rice to bread, the temperature detected by the temperature sensor 61 and the control objects (first heater 8A, second heater 8B, motor 24, fan 64) excluding the display body 4 are shown. , Solenoid 51) is shown in a disconnected state. In FIG. 7, for the cooking of “wheat bread” finished from flour to bread and “mochi” finished from glutinous rice grains, the power interruption state of the controlled object except the display body 4 is shown.

  First, the operation of the “baking course from rice cooking” by the first baking control means 71 will be described. When the course is executed, the kneading tool 18 is previously attached to the mounting portion 19 at the upper end of the shaft portion 15, and a predetermined amount of rice grains (glutinous rice grains) and water are put into the container 7 as an object to be cooked. Then, with the lid 31 opened, the container 7 is accommodated from the upper opening of the container accommodating chamber 6 and the lid 31 is closed. In this case, rice grains of other varieties that replace the glutinous rice grains, and liquids that have, for example, taste components instead of water may be introduced into the container 7. Further, the charging device 41 is taken out from the lid 31, the powder container lid 43 is opened, strong powder or the like is put into the powder container 42, and then yeast is introduced into the upper surface thereof. And after closing the powder container lid | cover 43, the charging device 41 which accommodated strong powder, yeast, etc. is mounted | worn with the lid | cover 32 again.

  After that, by selecting the “baking course from rice cooking” with the course selection key of the operation body 3 and operating another start key (rice cooking switch) of the operation body 3, the first bread baking control means 71 generates bread. The process begins.

  The first bread baking control means 71 captures the detection signal from the temperature sensor 61 and monitors the temperature of the container 7, while “heating control” as shown in FIG. 7, “cooling process”, , “Kone # 1”, “Nekashi” and “Kone # 2” kneading process, “Primary fermentation”, “Secondary fermentation” and “Molding fermentation” fermentation process, “Baking” and “Finish” A baking process is performed in order.

  Specifically, in the first rice cooking step, the second heater 8B is energized continuously until the temperature sensor 61 detects that the inside of the container 7 has reached the boiling temperature of 100 ° C., and the second heater 8B is energized. The lower part of the container 7 is strongly heated with a high heating amount from 8B (heating control # 1 shown in FIG. 7). When the inside of the container 7 reaches the boiling temperature, the heating amount of the second heater 8B is adjusted, Thereafter, boiling in the container 7 is continued until a certain time has elapsed (# 2 of heating control shown in FIG. 7). Eventually, if this boiling is continued for a certain period of time, it is determined that the rice cooking process has ended, the process proceeds to the cooling process, the energization of the second heater 8B is interrupted, and the heating to the container 7 is stopped, The fan 64 is operated to forcibly discharge the steam generated from the food to be cooked in the container 7 to the outside of the main body 1 so that the temperature of the container 7 is quickly reduced. The end of the rice cooking process may be a timing when a certain time has elapsed after operating the start key. By these rice cooking process and cooling process, the 1st bread baking control means 71 controls the heating means 8, performs the rice cooking heating with respect to the to-be-cooked thing in the container 7, and finishes it into the bowl-shaped rice which a rice grain does not remain.

  The first baking control means 71 executes the next kneading process when the cooling process for a certain time is completed or the temperature of the container 7 becomes a predetermined temperature of 40 ° C. or lower in the cooling process. In the kneading process, the motor 24 is operated to rotate and drive the kneading tool 18 attached to the mounting portion 19 for a predetermined time to knead the bowl-shaped rice in the container 7 (see FIG. 7). The kneading step # 1), the operation of the motor 24 is temporarily stopped, the kneading process in the container 7 is kneaded (the kneading shown in FIG. 7), the motor 24 is operated again, and the mounting portion 19 The kneading tool 18 attached to is rotated for a predetermined time to further knead the kneaded material in the container 7 and knead it into bread dough (kneading # 2 shown in FIG. 7) in order. In the kneading step, the first heater 8A is controlled to cut off electricity, and the side portion of the container 7 is mainly heated intermittently to maintain the inside of the container 7 at a constant temperature t1.

  In the first kneading process described above, the rice in the container 7 gradually changes into a kneaded product, but a predetermined operating voltage is supplied to the solenoid 51 in the middle of the operation, and the solenoid 51 is operated and closed until then. The charging port lid 44 is opened, and powder such as strong powder and yeast stored in the powder container 42 is automatically charged into the container 7. The operation timing of the solenoid 51 is the time when a certain time has elapsed after the rice cooking process is completed, or the time when the temperature sensor 61 detects that the container 7 has decreased to a certain temperature (for example, 60 ° C.) or less. Further, as shown in FIG. 7, in the present embodiment, the first baking control means 71 performs control to repeatedly supply a predetermined operating voltage to the solenoid 51 so that the charging port cover 44 is reliably opened.

  As described above, in this embodiment, the powder is automatically charged into the container 7 at a predetermined timing from the powder container 42 constituting the charging device 41 in response to the control signal from the first baking control means 71. Thus, it is possible to provide an easy-to-use cooker by omitting the trouble of opening the lid 31 in the middle of the kneading process and putting the powder into the container 7.

  The 1st bread baking control means 71 will perform the next fermentation process, after a kneading | mixing process is complete | finished. In the fermentation process, as the primary fermentation process, the first heater 8A is controlled to cut off electricity, the container 7 is maintained at a temperature t2 at which fermentation is promoted, and the motor 24 is not operated for a predetermined time. “Fermentation” is controlled by turning off the first heater 8A to maintain the container 7 at the temperature t2, and the motor 24 is intermittently operated to rotate the kneading tool 18 at regular intervals. “Degassing” is performed to remove the gas contained in the bread dough in 7, and as a subsequent secondary fermentation process, the first heater 8 </ b> A is cut off and the temperature of the container 7 is set to a temperature t <b> 3 at which fermentation is promoted. “Fermentation” in which the motor 24 is left as it is for a predetermined period of time without being operated, and the first heater 8A is controlled to be cut off and the container 7 is continuously maintained at the temperature t3. The kneading tool 18 is kept constant. Rotate between every "venting" is performed removing the gas contained in the dough in the container 7. Furthermore, after this secondary fermentation, the first heater 8A is controlled to cut off electricity, the container 7 is maintained at a temperature t4 at which fermentation is promoted, and the motor 24 is not operated and left as it is for a predetermined time. Productive fermentation takes place.

  As an example, in the primary fermentation process, the temperature t2 of the container 7 is set to approximately 40 ° C. for 30 minutes, and in the secondary fermentation process, the temperature t3 of the container 7 is set to approximately 33 ° C. for 10 minutes. These fermentation temperatures and times vary depending on the temperature (room temperature) and the cooking menu that can be selected in the same course.

  When the kneading process is finished, the first bread baking control means 71 next executes the baking process. In the baking process, the first heater 8A is continuously energized to raise the container 7 to a temperature t5 necessary for baking bread (baking # 1 shown in FIG. 7), and the container 7 has a temperature t5. When the temperature sensor 61 detects that the temperature reaches 61, a second baking process (baking shown in FIG. 7) is performed by cutting off the first heater 8A so as to maintain the temperature t5 and baking the dough in the container 7. # 2) and a finishing process for finishing the bread baked in the container 7 while the temperature of the container 7 is gradually lowered by controlling the disconnection of the first heater 8A.

  As an example, in the first baking process, the temperature of the container 7 is increased to 155 ° C. under a predetermined temperature (room temperature), and the temperature sensor 61 detects that the temperature of the container 7 has reached t5 = 155 ° C. Then, it transfers to a 2nd baking process and the container 7 is heated so that the temperature t5 may be maintained. And after shifting to a 2nd baking process, if predetermined | prescribed 40 minutes pass, it will be judged that baking is completed and a 2nd baking process or a baking process will be complete | finished.

  Thus, in the “bread baking course from rice cooking rice” performed by the first bread baking control means 71, the rice grains put into the container 7 are not crushed into a paste form, but are kneaded with cooked rice cake-like rice. And finally baked bread. Therefore, the mill which grind | pulverizes a rice grain is not required, and the noise at the time of a grinding | pulverization as a cooking device does not generate | occur | produce. In addition, when making bread with leftover rice, there is a problem of putting rice, and there is a problem that the shape of the rice remains in the state of bread, but by cooking rice grains in bowl shape, the trouble of putting rice into container 7 is saved. You can make bread without leaving a grain shape.

  Further, by providing the first heater 8A for heating the side portion of the container 7 and the second heater 8B for heating the lower portion of the container 7, the bottom of the container 7 where the heat from the heating means 8 is hardly transmitted is also heated. It is possible to bake bread in the container 7 more uniformly by appropriately using the first heater 8A and the second heater 8B.

  Next, the operation of the “baking course from rice kneading” by the second baking control means 72 will be described. When the course is executed, the kneading tool 18 is attached to the mounting portion 19 at the upper end of the shaft portion 15 in advance, and a predetermined amount of cooked rice and liquid such as water are poured into the container 7 as an object to be cooked. Here, powders such as yeast are also put into the container 7 from the beginning. Then, with the lid 31 opened, the container 7 is accommodated from the upper opening of the container accommodating chamber 6 and the lid 31 is closed.

  Thereafter, the “baking course from rice kneading” is selected by the course selection key of the operation body 3, and the start key of the operation body 3 is operated, whereby the bread production process by the second baking control means 72 is started.

  The second bread baking control means 72 omits the rice cooking process and the cooling process in the bread production process by the first bread baking control means 71 described above, and each remaining remaining from the kneading process through the fermentation process to the baking process. The steps are executed in order (see the power interruption state of each part corresponding to “wheat bread” in FIG. 7). However, the setting of the temperature and time in each of these steps may be different from the above-described “bake course from rice cooking”. Further, since powder such as yeast is previously put in the container 7, it is not necessary to operate the solenoid 51 during the first kneading process. Accordingly, the second baking control means 72 keeps the second heater 8B, the fan 64, and the solenoid 51 in the OFF state, and controls the power interruption only for the first heater 8A and the motor 24.

  Next, the operation of the “baking course from wheat flour” by the third baking control means 73 will be described. At the time of executing the course, a kneading tool 18 is previously attached to the mounting portion 19 at the upper end of the shaft portion 15, and flour (strong powder), butter, salt, sugar, dry yeast, nonfat dry milk, water, etc. are to be cooked as containers 7 In. Here, powders such as yeast are also put into the container 7 from the beginning. Then, with the lid 31 opened, the container 7 is accommodated from the upper opening of the container accommodating chamber 6 and the lid 31 is closed.

  Thereafter, the “baking course from wheat flour” is selected by the course selection key of the operation body 3 and the start key of the operation body 3 is operated, whereby the bread production process by the third baking control means 73 is started.

  The third bread baking control means 73 also omits the rice cooking process and the cooling process in the bread production process by the first bread baking control means 71 described above, and performs the remaining steps from the kneading process to the baking process through the fermentation process. The steps are executed in order (see the power interruption state of each part corresponding to “wheat bread” in FIG. 7). However, the setting of the temperature and time in each of these steps may be different from the above-described “bread course from rice cooking” or “bread course from rice cooking”. Further, since powder such as yeast is previously put in the container 7, it is not necessary to operate the solenoid 51 during the first kneading process. Therefore, the third baking control means 73 keeps the second heater 8B, the fan 64, and the solenoid 51 in the OFF state, and controls only the first heater 8A and the motor 24 to be cut off.

  In the baking process performed by the first bread baking control means 71, the second bread baking control means 72, and the third bread baking control means 73 described above, when the baking color at the bottom of the bread is to be increased, for example, a specific key of the operation unit 2 is used. In addition to the first heater 8A, the second heater 8B may be used in combination so as to selectively heat not only the side but also the bottom of the container 7 by operating. By doing so, the baking color of the bottom of the bread can be easily increased according to the preference of the user.

  Next, the operation of the “rice cooking course from rice cooking” by the rice cake generation control means 74 will be described. When the course is executed, the kneading tool 18 is attached to the mounting portion 19 at the upper end of the shaft portion 15 in advance, and rice grains such as glutinous rice grains and liquid such as water are put into the container 7 as cooking objects. Do not put powder. Then, with the lid 31 opened, the container 7 is accommodated from the upper opening of the container accommodating chamber 6 and the lid 31 is closed.

  Referring to the power interruption state of each part corresponding to “mochi” in FIG. 7, the mochi generation control unit 74 cooks and cooks the glutinous rice grains in the container 7 in the rice cooking process by the heating control described above. The second heater 8B is energized continuously until the temperature sensor 61 detects that the inside of the container 7 has reached the boiling temperature of 100 ° C., and the container 7 is mainly heated at a high heating amount from the second heater 8B. When the lower part is heated strongly (# 1 of the heating control shown in FIG. 7) and the inside of the container 7 reaches the boiling temperature, the heating amount of the second heater 8B is adjusted, and then the inside of the container 7 is kept until a certain time elapses. Is continued (# 2 in the heating control shown in FIG. 7), and the glutinous rice is cooked. Moreover, the motor 24 is operated appropriately, the kneading tool 18 attached to the mounting part 19 is rotationally driven, and the cooked cooked cooked rice is finished into a grainless rice cake shape. In FIG. 7, the motor 24 is operated at the same time as the second heater 8B is energized in the rice cooking process, but after the rice cooking process is finished, the motor 24 is operated to mix the cooked glutinous rice with the kneading tool 18. It may be tempered and finished in a sticky shape. In any case, the mochi generation control means 74 keeps the first heater 8A, the fan 64, and the solenoid 51 in the OFF state, and controls only the second heater 8B and the motor 24 to cut-off. However, in the “bread baking course from rice cooked rice”, the cooked food is cooked into rice cake-like rice, whereas in the “rice cooked rice cooked rice course”, the rice is cooked with less moisture. Therefore, the amount of liquid with respect to the rice grains and the heating duration after detecting the boiling temperature in the container 7 are changed.

  Finally, the operation of the “rice cooking course” by the rice cooking control means 75 will be described. When executing the course, rice grains such as glutinous rice grains and liquid such as water are introduced into the container 7 as the cooking object, but the kneading tool 18 is not attached to the attachment part 19 at the upper end of the shaft part 15. No powder such as yeast is put into the container 7. Then, with the lid 31 opened, the container 7 is stored from the upper opening of the container storage chamber 6, and an inner lid 81 as shown in FIGS. Close.

  Thereafter, the “rice cooking course” is selected by the course selection key of the operation body 3 and another start key of the operation body 3 is operated, whereby the bread generating process by the rice cooking control means 75 is started.

  Here, the configuration of the inner lid 81 will be described with reference to FIG. 8 and FIG. 9. The inner lid 81 is used only for the above-described “rice cooking course” and is detachably provided on the upper surface opening of the container 7. . As an example, an inner lid 81 shown in FIG. 8 is formed by penetrating the cap portion 82 so as to face the upper surface opening of the container 7 and a cap portion 82 having a U-shaped cross-section that fits over the upper side wall of the container 7. And one or a plurality of holes 83. Further, another example of the inner lid 81 shown in FIG. 9 further includes a flange 84 extending outward from the side portion of the cap 82. The flange 84 has a shape that extends to the outer periphery of the container 7 and closes the space between the container 7 and the inner wall of the container storage chamber 6 when the inner lid 81 is attached to the container 7.

  When receiving the operation signal from the start key, the rice cooking control means 75 first determines whether or not the inner lid 81 is correctly mounted so as to cover the upper portion of the container 7 based on the detection signal from the inner lid detection sensor 63. At this time, if the inner lid 81 is not properly attached to the container 7, the rice 7 is not heated to the container 7, and an alarm is displayed to urge the display body 4 as a notification unit to attach the inner lid 81. . Thereby, when the user selects and executes the “rice cooking course”, the user can understand from the alarm display that the inner lid 81 is not attached, and the usability as a cooking device is improved.

  On the other hand, if the inner lid 81 is correctly attached to the container 7, the rice cooking control means 75 cooks and cooks the food to be cooked in the container 7 based on the rice cooking process based on the heating control described above. In this rice cooking step, the second heater 8B is energized continuously with a high heating amount from the second heater 8B until the temperature sensor 61 detects that the inside of the container 7 has reached the boiling temperature of 100 ° C. The lower part of the container 7 is mainly heated strongly (heating control # 1 shown in FIG. 7), and when the inside of the container 7 reaches the boiling temperature, the heating amount of the second heater 8B is adjusted, and then a certain time elapses. Until the boiling in the container 7 continues (# 2 in the heating control shown in FIG. 7), the rice is cooked. After the rice is cooked, the heating amount of the second heater 8B may be appropriately adjusted by the rice cooking control means 75 to keep the container 7 at a predetermined temperature. As described above, the rice cooking control means 75 keeps the first heater 8A, the motor 24, the fan 64, and the solenoid 51 in the OFF state, and controls only the second heater 8B to be cut off. However, in the “baked rice course from rice cooked rice”, the cooked food is cooked and finished into bowl-shaped rice, whereas in the “cooked rice course”, rice with less water is finished, so the liquid to the rice grains The heating duration time after detecting the amount and the boiling temperature in the container 7 is changed.

  As described above, the rice cooking control means 75 displays an alarm on the display body 4 if the inner lid 81 is not attached to the container 7, but instead of or in addition to this, the inner lid 81 If it is attached to the container 7, the first baking control means does not perform the rice cooking to the container 7, and causes the display body 4 as the notification unit to display an alarm prompting the user to remove the inner lid 81. 71 may be configured. Thereby, the user can understand that the inner lid 81 is attached to the container 7 by the alarm display when selecting and executing “bread baking course from rice cooking”, and the usability as a cooking device is improved. In addition, it is possible to prevent a problem in which the charging of powder from the powder container 42 into the container 7 is blocked by the inner lid 81.

  As described above, when the “cooking course” is selected and executed, it is not necessary to attach the kneading tool 18 to the mounting portion 19 and the usability as a cooking device can be improved. In addition, the container 7 for baking in the “baking course from rice cooking” and the container 7 for cooking in the “cooking course” are not separate but can be shared, thereby reducing costs. it can.

  Further, when baking bread in the baking process, the side of the container 8 is mainly heated by the first heater 8A, and when cooking rice in the rice cooking process, the bottom of the container 8 is mainly heated by the second heater 8B. In this way, by switching the heating of the container 7 by the first heater 8A or the second heater 8B as necessary, it is possible to perform optimum baking of bread or cooking of rice.

  10 and 11 show the first heater 8A in the cooking device shown in FIG. 8 when the inner lid 81 is removed from the upper surface opening of the container 7 and when the upper surface opening of the container 7 is covered with the inner lid 81. The graph shows how the power interruption and the temperature of each part change. The power consumption of the first heater 8 </ b> A here is 360 W regardless of the presence or absence of the inner lid 81. In each of these figures, “ON-OFF” indicates the power interruption of the first heater 8A, “room temperature” indicates the room temperature around the cooker, “upper” indicates the upper temperature in the container 7, and “middle” "" Indicates the center temperature in the container 7, "bottom" indicates the lower temperature in the container 7, "side" indicates the side temperature of the container 7, and "bottom" indicates the bottom temperature of the container 7. Yes.

  Comparing the graphs of FIG. 10 and FIG. 11, it can be seen that when the inner lid 81 is attached, the temperature rises rapidly, particularly in the central part and upper part of the container 7 away from the first heater 8A. . This is because the inner lid 81 prevents heat escape from the upper opening of the container 7. Therefore, in the “rice cooking course”, if the inner lid 81 as shown in FIG. 8 is used, the whole cooking object in the container 7 can be quickly heated to cook delicious rice. Further, when the inside of the container 7 reaches the boiling temperature, the steam generated from the inside of the container 7 is discharged from the hole 83 of the inner lid 81 to the outside of the container 7, so that the amount of released steam can be appropriately adjusted by the hole 83. .

  12 and 13 show that the first heater 8A is disconnected when the power consumption of the first heater 8A is 360 W and the power consumption of the first heater 8A is 450 W in the cooking device shown in FIG. It shows how electricity and the temperature of each part change. Further, here, the first heater 8A is disposed at the position of the second heater 8B of the cooking device shown in FIG. 2 so as to heat the lower portion of the container 7. Also in each of these figures, “ON-OFF” indicates the power interruption of the first heater 8A, “room temperature” indicates the room temperature around the cooker, “upper” indicates the upper temperature in the container 7, and “ "Middle" indicates the center temperature in the container 7, "Lower" indicates the lower temperature in the container 7, "Side" indicates the side temperature of the container 7, and "Bottom" indicates the bottom temperature of the container 7. ing.

  Comparing the graphs of FIG. 11 and FIG. 12, in the cooking device shown in FIG. 9, the first heater 8 </ b> A mainly heats the bottom rather than the side of the container 7. It can be seen that the temperature rises rapidly at the bottom of the screen. Further, since the flange 84 provided on the inner lid 81 prevents heat from escaping from the first heater 8A between the container housing chamber 6 and the container 7, the temperature in the upper part of the container 7 rises as quickly as ever. doing. Therefore, by closing the space between the container storage chamber 6 and the container 7 with the flange 84 of the inner lid 81, even when the bottom of the container 7 is heated by the heating means 8, it is possible to efficiently cook rice.

  Comparing the graphs of FIG. 12 and FIG. 13, it can be seen that the temperature rises more quickly in any part of the container 7 when the power consumption of the first heater 8A is increased.

  In the above-described cooker, using the course selection key of the operation body 3, the “bread baking course from rice cooking”, “bread baking course from rice kneading”, “bread baking course from wheat flour”, “ You can choose either “rice cooking course from rice cooking” or “rice cooking course”. Therefore, by putting any of rice grains, rice, and wheat flour into the container 7, various breads can be easily made, and rice cakes made from rice grains can be made. In addition to bread and rice cake, the rice cooking course can be used to cook rice from rice grains, and a cooker with excellent usability and economy that combines the functions of a rice cooker and a mochi rice cooker and a home bakery. Can be provided.

  Furthermore, when the “baking course from rice cooked rice” is selected, since the charging device 41 capable of automatically adding powder such as yeast is provided, it is possible to save the trouble of putting such powder into the container 7 during cooking. It is possible to further improve the usability as a cooking device.

  As described above, the cooking device in the present embodiment is provided on the bottomed cylindrical container 7 that is detachably attached to the main body 1, the lid 31 that covers the upper opening of the container 7, and the inner bottom surface of the container 7. As a rotatable mounting part 19, a kneading tool 18 detachably attached to the mounting part 19, a heating means 8 for heating the container 7, and a temperature detecting means for directly or indirectly detecting the temperature of the container 7 Temperature sensor 61 and a control unit 62 as control means for adjusting the heating amount of the heating means 8 in accordance with the temperature detected by the temperature sensor 61.

  And especially the control part 62 of this embodiment cooks rice with respect to the rice grain and the liquid which were thrown in in the container 7 by controlling the heating means 8 in order to perform "the bread baking course from rice cooking". When the rice cake-like rice cooked in the container 7 is kneaded with the kneading tool 18 at the bottom of the container 7 after rice cooking, and the yeast is put into the rice in the container 7 Then, after the kneaded material in the container 7 is further kneaded by the kneading tool 18 by controlling the mounting portion 19 and the heating means 8 is controlled to ferment the kneaded material at a predetermined temperature, the container 7 The first baking control means 71 is provided to bake the bread by heating it.

  In this case, the rice grains thrown into the container 7 are not crushed and made into a paste, but the dough is made with rice cooked from the rice grains, so the noise can be reduced without using a mill for crushing the rice grains. Can be achieved. In addition, pre-cooked rice is not required, and if rice grains are prepared, it can be finished into bread and the labor of putting rice can be omitted. Therefore, it is possible to provide a cooker that can achieve low noise and can be finished into bread without the need for rice.

  Moreover, the control part 62 of this embodiment controls the heating means 8 other than the said 1st baking control means 71, performs rice cooking heating with respect to the rice grain and liquid with which it put in the container 7, and a mounting part The rice cake generation control means 74 which performs "the rice kneading course from rice rice cooking" which controls 19 and finishes the rice in the container 7 by kneading with the kneading tool 18 at the bottom of the container 7 after rice cooking, By controlling the mounting portion 19, the rice thrown into the container 7 is kneaded by the kneading tool 18, the heating means 8 is controlled, and the container 7 is heated and baked into a bread shape. The second baking control means 72 for performing the “bread baking course” and the mounting portion 19 are controlled to knead the wheat flour charged in the container 7 with the kneading tool 18, and the heating means 8 is controlled to control the container 7 Baked into a bread shape by heating A third baking control unit 73 for performing a course ", and configured to select.

  In this case, select a specific course from "Bread-baking course from rice-cooked rice", "Boil-kneaded course from rice-cooked rice", "Bake-baked course from rice-kneaded", "Bake-baked course from wheat flour" This makes it easy to make a variety of bread and rice cakes.

  Further, the control unit 62 of the present embodiment controls the heating unit 8 in addition to the first bread baking control unit 71 and the second bread baking control unit 72, and controls the rice grains and liquid charged in the container 7. The rice cooking control means 75 which performs rice cooking heating and performs the "rice cooking course" finished as rice is comprised so that it can select.

  In this case, in addition, it is possible to make either bread or rice from the food to be cooked in the container 7, and the functions of the home bakery and the rice cooker can be realized by one unit, so cooking that is easy to use and economical is excellent. Can be provided.

  Moreover, the control part 62 of this embodiment is comprised so that at least the 1st bread baking control means 71 and the rice cooking control means 75 can be selected, and also the "baking course from rice cooking" by the 1st bread baking control means 71 is carried out. When performing, while opening the container 7 upper part, when performing the "rice cooking course" by the rice cooking control means 75, the inner cover 81 which covers the upper part of the container 7 is provided, and it generate | occur | produces from the container 7 with rice cooking. It has the structure which discharges | emits vapor | steam from the hole 83 with which the inner cover 81 was equipped.

  In this case, when the “cooking course” is performed, the inner lid 81 prevents the escape of heat from the inside of the container 7, so that delicious rice can be cooked. Further, since the steam generated from the inside of the container 7 is discharged to the outside of the container 7 from the hole 83 of the inner lid 81, the amount of the steam discharged can be appropriately adjusted by the hole 83.

Further, the inner lid 81 in this case is provided with a flange 84 as a configuration that extends to the outer periphery of the container 7 and closes the space between the container 7 and the inner wall of the container storage chamber 6 that is a storage part of the container 7. Yes. In this case, by closing the space between the container storage chamber 6 and the container 7 by the flange 84 of the inner lid 81, it is possible to suppress the escape of heat from the heating means 8 and efficiently cook rice.

  Further, when performing the “bread baking course from rice cooking”, a feeding device 41 is further provided that is driven by a control signal from the control unit 62 and automatically feeds yeast into the container 7. In this case, since yeast is automatically charged into the container 7 from the charging device 41 at a predetermined timing, a user-friendly cooker can be provided.

  In the present embodiment, as an inner lid detecting device for detecting the presence or absence of the inner lid 81, the inner lid detecting sensor 63 is provided, and when the “bread baking course from rice cooking” is performed, the presence of the inner lid 81 is detected. For example, an alarm notification is made on the display body 4. Thereby, the user can understand that the inner lid 81 is attached to the container 7 by the alarm display when selecting and executing “bread baking course from rice cooking”, and the usability as a cooking device is improved.

  Furthermore, when performing the “rice cooking course”, it may be configured such that, for example, the display body 4 gives an alarm notification when it is detected that the inner lid 81 is not present. Thereby, when the user selects and executes the “rice cooking course”, the user can understand from the alarm display that the inner lid 81 is not attached, and the usability as a cooking device is improved.

  Moreover, the control part 62 of this embodiment is comprised so that at least the 1st bread baking control means 71 and the rice cooking control means 75 can be selected, and when performing a rice cooking course, the kneading tool 18 is attached to the mounting part 19. It is set as the structure which can cook rice without mounting | wearing, and the container 7 is made to share by "the bread baking course from rice cooking rice" and the "rice cooking course".

  In this way, when performing the “cooking course”, there is no need to bother to attach the kneading tool 18 to the mounting part 19, and the use of the cooking and baking container 7 in common improves usability and reduces costs. Can be planned.

  Further, the control unit 62 of this embodiment includes at least a first baking control unit 71, and the heating unit 8 includes a first heater 8 </ b> A as a first heating unit that heats the side portion of the container 7, and a container. 7 and a second heating means for heating the lower part of 7. In this case, by providing the first heater 8A for heating the side portion of the container 7 and the second heater 8B for heating the lower portion of the container, the bottom of the container 7 where the heat from the heating means 8 is difficult to travel is also heated. It is possible to bake bread in the container 7 more uniformly by appropriately using the first heater 8A and the second heater 8B.

  Moreover, at the time of the baking process which bakes the kneaded material in the container 7 in the bread shape, the container 7 is mainly heated with the first heater 8A, and the rice in the container 7 is finished without kneading after the rice cooking is heated. In this case, the control unit 62 is configured to control the heating means 8 so that the container 7 is mainly heated by the second heater 8B.

  In this case, it is possible to optimally bake bread or cook rice by switching the heating of the container 7 by the first heater 8A or the second heater 8B as necessary.

  Further, when the kneaded material in the container 7 is baked into a pan shape, the control unit 62 controls the heating means 8 so that the second heater 8B is selectively controlled by using the first heater 8A in combination with the second heater 8B. It is good also as a structure which controls. In this case, when it is desired to increase the baking color of the bottom of the bread, the second heater 8B is used in addition to the first heater 8A so that not only the side of the container 7 but also the bottom can be selectively heated. It can be controlled and the baking color of the bottom of the bread can be easily increased according to the user's preference.

  In addition, this invention is not limited to the said embodiment, A various change is possible in the range which does not deviate from the meaning of this invention. For example, the time and temperature in the above embodiment are merely examples, and do not limit the contents of the present invention. As a form of alarm notification, for example, alarm notification by a sound output device such as a buzzer or a speaker may be used instead of the alarm display by the display body 4.

6 Container storage room (storage section)
7 container 8 heating means 8A first heater (first heating means)
8B Second heater (second heating means)
18 Kneading tool 19 Mounting part 41 Input device 61 Temperature sensor (temperature detection means)
62 Control part (control means)
63 Inner lid detection sensor (Inner lid detection device)
81 Inner lid 83 holes

Claims (7)

A bottomed container, a rotatable mounting part provided in the container, a kneading tool provided in the mounting part, a heating means for heating the container, and a temperature detection means for detecting the temperature of the container And control means for adjusting the amount of heating of the heating means according to the temperature detected by the temperature detecting means,
The control means controls the heating means to perform rice cooking and heating for rice and liquid put into the container, and controls the mounting portion to allow the kneading tool to add the rice kneading tool to the inside of the container. When the yeast is put into the rice in the container, the mounting portion is controlled, and the kneaded material in the container is further kneaded by the kneading tool, and the heating means is controlled. to, after fermented the kneaded product at a predetermined temperature state, and are not bake bread shape by heating the container,
The heating means comprises a first heating means for heating the side portion of the container and a second heating means for heating the lower part of the container,
When the kneaded product is baked into a pan shape, the container is heated mainly by the first heating means, and when the rice in the container is finished without kneading after the rice cooking heating, the second heating is performed. A cooking device characterized in that the container is mainly heated by means . Wherein, prior SL performs cooking heating against the US such a liquid is introduced into the container, and kneading the rice in the vessel by the kneading tool after 炊 rice, yeast is poured into the container When you are to further kneaded kneaded product in the container by the previous SL kneading tool, after fermenting the kneaded product in Jo Tokoro temperature, baked bread shape by heating the container, cooking and baking course from,
Performs cooking heating against the US such a liquid is introduced before Symbol vessel, finish waxy and kneaded rice in the vessel by the kneading tool after 炊 rice, and waxy kneading course from rice ,
The rice is introduced before Symbol vessel was kneaded by the kneading tool, baked bread shape by heating the pre-SL container, a baking course from rice kneading,
The inserted wheat before Symbol vessel was kneaded by the kneading tool, baked bread shape by heating the pre-SL container, a baking course from wheat,
The cooking device according to claim 1 , wherein a rice cooking course in which rice is heated with respect to rice and liquid put into the container and finished as rice can be selected. When performing a baking course from the cooked rice, while opening the upper portion of the container, when performing the cooked rice course, an inner lid that covers the upper portion of the container is provided, and steam generated from within the container The cooking device according to claim 2 , wherein the cooking device is configured to be discharged from a hole provided in the lid . The cooker according to claim 3 , wherein the inner lid extends to the outer periphery of the container and closes a space between the container and the storage portion of the container . An inner lid detecting device for detecting the presence or absence of the inner lid;
When performing the baking course from the cooked rice, when the presence of the inner lid is detected, or when the cooking course is performed, the absence of the inner lid is detected, and an alarm notification is made. The cooker according to claim 3 or 4 , characterized by the above.   The cooker according to any one of claims 2 to 5, further comprising a feeding device that is driven when performing a baking course from the cooked rice and automatically feeds the yeast into the container. When performing the rice cooking course, it is configured so that rice can be cooked without attaching the kneading tool to the mounting part,
The cooker according to any one of claims 2 to 6 , wherein the container is also used in a baking course from the cooked rice and the cooked rice course .

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