JP2014042856A - Automatic bread making machine - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an automatic bread making machine provided with a mechanism convenient for making bread from cereal grains without performing a milling step.SOLUTION: A bread container 50 is placed in a baking chamber 40 provided in a body 10 of an automatic bread making machine 1. A kneading blade 52 and a grinding blade 70 are mounted coaxially on a bottom part of the bread container 50. The grinding blade 70 is formed by dispersively disposing a plurality of cutting blades 72 on a top face of a circular plate 71. The kneading blade 52 is attached to an inner shaft 53a of a double shaft penetrating the bottom part of the bread container 50, and the grinding blade 70 is attached to an outer shaft 53b. The inner shaft 53a is driven by a motor 60a, and the outer shaft 53b is driven by a motor 60b. The motor 60a and the motor 60b are controlled by a common control device 80.

Description

  The present invention relates to an automatic bread maker mainly used in general households.

  A commercial household automatic bread maker puts a bread container containing bread-making ingredients into a baking chamber in the main body, kneads and kneads the bread-making ingredients in the bread container with a kneading blade, and after undergoing a fermentation process, In general, the bread container is used as a baking mold to bake bread. An example of an automatic bread maker can be seen in Patent Document 1.

  Ingredients such as raisins and nuts may be mixed with bread ingredients to bake bread with ingredients. Patent Document 2 describes an automatic bread maker provided with means for automatically charging bread-making auxiliary materials such as raisins, nuts and cheese.

JP 2000-116526 A Japanese Patent No. 3191645

  In the past, when making bread, it was necessary to start by obtaining flour obtained by milling grains such as wheat and rice, and mixing flour mixed with various auxiliary ingredients. Even with grain at hand (typically rice), it was difficult to make bread directly from it.

  The present invention has been made in view of the above points, and provides an automatic bread maker equipped with a convenient mechanism for manufacturing bread from cereal grains without going through a milling process. The purpose is to.

  In order to achieve the above object, the present invention automatically receives a bread container containing a bread-making raw material in a baking chamber in the main body, and sequentially performs the crushing process, kneading process, fermentation process and baking process of the bread-making raw material. In the bread maker, a kneading blade and a grinding blade are coaxially attached to the bottom of the bread container.

  According to this structure, the bread-making raw material can be manufactured in the bread container by putting the grain into the bread container and pulverizing it with the grinding blade. Thereafter, the bread-making raw material is kneaded with a kneading blade, and the fermentation and baking steps can be further advanced. Grain grains crushed in a bread container can be baked into bread in the bread container as they are, so that the grains remain in other containers, unlike crushed grains in other containers and then transferred to the bread container. There is no loss associated with the transfer, that is, not entering the bread container. In addition, by attaching them coaxially, the kneading blade and the pulverizing blade can coexist in a compact place at the bottom of the bread container, which is not so wide.

  Further, the present invention is characterized in that, in the automatic bread maker configured as described above, a kneading blade attached coaxially is attached above the grinding blade.

According to this configuration, since the kneading blade is attached above the crushing blade, it becomes easy for the kneading blade to swing the dough and knock it against the inner wall of the bread container, and an element of “kneading” can be added to the kneading. it can.

  Further, the present invention provides an automatic bread maker having the above-described configuration, wherein a double shaft that penetrates the bottom of the bread container is provided, the kneading blade is attached to the inner shaft of the double shaft, and the outer shaft of the double shaft Is characterized in that the grinding blade is attached.

  According to this configuration, since the kneading blade is attached to the inner shaft of the double shaft and the grinding blade is attached to the outer shaft of the double shaft, the kneading blade and the grinding blade can be rotated separately.

  According to the present invention, bread can be baked using hand-held grains, and there is no need to purchase grain flour. In the case of rice, bread can be baked with rice of the desired degree of milling, from brown rice to white rice. Then, the cereal grains put in the bread container are crushed with a pulverizing blade to produce a bread-making raw material, and then the bread-making raw material is kneaded with a kneading blade, and further the fermentation, baking and the process are advanced. Because there is, it can be baked into the bread without leaving the grain in the bread container. For this reason, unlike the method in which grain grains are crushed in another container and then transferred to a bread container, there is no loss associated with the transfer in which the crushed grain grains remain attached to other containers. In addition, by attaching them coaxially, the kneading blade and the pulverizing blade can coexist in a compact place at the bottom of the bread container, which is not so wide.

1 is a vertical sectional view of an automatic bread maker according to the present invention. It is a top view of a grinding blade. It is a control block diagram of the automatic bread maker according to the present invention. It is a whole flowchart of a 1st aspect bread manufacturing process. It is a flowchart of the impregnation process before grinding | pulverization of a 1st aspect bread manufacturing process. It is a flowchart of the grinding | pulverization process of a 1st aspect bread manufacturing process. It is a flowchart of the kneading | mixing process of a 1st aspect bread manufacturing process. It is a flowchart of the fermentation process of a 1st aspect bread manufacturing process. It is a flowchart of the baking process of a 1st aspect bread manufacturing process. It is a whole flowchart of a 2nd aspect bread manufacturing process. It is a flowchart of the impregnation process after the grinding | pulverization of a 2nd aspect bread manufacturing process. It is a whole flowchart of a 3rd aspect bread manufacturing process.

  Embodiments of the present invention will be described below with reference to the drawings.

  The automatic bread maker 1 has a box-shaped main body 10 constituted by an outer shell made of synthetic resin. An operation unit 20 is provided on the front surface of the main body 10. Although not shown, the operation unit 20 has operation keys such as a selection key for bread types (wheat flour bread, rice flour bread, bread with ingredients, etc.), a selection key for cooking contents, a timer key, a start key, a cancel key, and the like. A display unit is provided for displaying the group and the set cooking contents and timer reservation time.

  The upper surface of the main body behind the operation unit 20 is covered with a lid 30 made of synthetic resin. The lid 30 is attached to an edge on the back side of the main body 10 with a hinge shaft (not shown), and rotates in a vertical plane with the hinge shaft as a fulcrum.

A firing chamber 40 is provided inside the main body 10. The baking chamber 40 is made of sheet metal and has an open top surface, from which a bread container 50 is placed. The baking chamber 40 includes a peripheral side wall 40a and a bottom wall 40b having a rectangular horizontal section.

  A base 12 made of sheet metal is installed inside the main body 10. On the base 12, a bread container support 13 made of an aluminum alloy die-cast product is fixed at a location corresponding to the center of the firing chamber 40. The inside of the bread container support part 13 is exposed inside the baking chamber 40.

  At the center of the bread container support portion 13, a double shaft composed of an inner shaft 14a and an outer shaft 14b is vertically supported. The lower ends of the inner shaft 14a and the outer shaft 14b both protrude from the lower surface of the bread container support portion 13. A pulley 15a is fixed to the inner shaft 14a, and a pulley 15b is fixed to the outer shaft 14b.

  The bread container support unit 13 supports the bread container 50 by receiving a cylindrical pedestal 51 fixed to the bottom surface of the bread container 50. The pedestal 51 is also an aluminum alloy die cast product.

  The bread container 50 is made of sheet metal and has a bucket-like shape, and a handle (not shown) for handbags is attached to the lip. The horizontal cross section of the bread container 50 is a rectangle with rounded four corners, and ridge-like protrusions 50a extending in the vertical direction are formed on the inner surfaces of two opposite sides of the four sides.

  In the center of the bottom of the bread container 50, 52 and a grinding blade 70 are arranged. A double shaft composed of an inner shaft 53a and an outer shaft 53b is vertically supported after a countermeasure against sealing is applied to the center of the bread container 50. A kneading blade 52 is attached to the inner shaft 53a, and a grinding blade 70 is attached to the outer shaft 53b. That is, the arrangement of the kneading blade 52 and the crushing blade 70 is a coaxial arrangement. As a result, the kneading blade 52 and the crushing blade 70 can coexist in a compact manner in a place that is not so wide as the bottom of the bread container 50.

  The kneading blade 52 is attached to the non-circular cross section at the upper end of the inner shaft 53a by simply fitting, and can be attached and detached without using a tool. For this reason, it can be easily replaced with a different kind of kneading blade 52.

  The crushing blade 70 is attached to the outer shaft 53 b so as not to hit the lower surface of the kneading blade 52. The crushing blade 70 may be attached simply by fitting.

  As shown in FIG. 2, the grinding blade 70 has a plurality of cutting blades 72 scattered on the upper surface of a metal disk 71. The cutting blade 72 is formed like a juicer cutter or a grater tooth. By increasing the number of the cutting blades 72, the individual cutting blades 72 can be made low in height, so that the interval between the pulverizing blade 70 and the kneading blade 52 can be reduced, and the cutting blades 72 can be arranged compactly.

  As seen in FIG. 2, the cutting blades 72 constitute a plurality of rows that extend in the radial direction. The distance from the center of the disk 71 of each cutting blade protrusion 72 in each line is slightly shifted from the front and rear lines for each line. Therefore, the entire set of cutting blades 72 is uniformly crushed in the entire arrangement region. Can affect.

The inner shaft 53a is connected to the inner shaft 14a, and the outer shaft 53b is connected to the outer shaft 14b to transmit power. As power transmission means, couplings 54a and 54b enclosed in a pedestal 51 are used. That is, of the two members constituting the coupling 54a, one member is fixed to the lower end of the inner shaft 53a, and the other member is fixed to the upper end of the inner shaft 14a. Similarly, of the two members constituting the coupling 54b, one member is fixed to the lower end of the outer shaft 53b, and the other member is fixed to the upper end of the outer shaft 14b.

  Protrusions (not shown) are formed on the inner peripheral surface of the bread container support 13 and the outer peripheral surface of the base 51, respectively. These protrusions constitute a well-known bayonet connection. That is, when the bread container 50 is attached to the bread container support part 13, the bread container 50 is lowered so that the protrusions of the base 51 do not interfere with the protrusions of the bread container support part 13, and the base 51 fits into the bread container support part 13. Thereafter, when the bread container 50 is twisted horizontally, the protrusion of the pedestal 51 is engaged with the lower surface of the protrusion of the bread container support portion 13 so that the bread container 50 cannot be pulled upward. By this operation, the coupling 54a and the coupling 54b are also simultaneously achieved. The twisting direction when the bread container 50 is attached coincides with the rotation directions of the kneading blade 52 and the crushing blade 70 so that the bread container 50 does not come off even when the kneading blade 52 or the crushing blade 70 rotates.

  A heating device 41 disposed inside the baking chamber 40 surrounds the bread container 50 and heats the bread-making material. The heating device 41 is constituted by a sheathed heater.

  A motor 60 a is attached to the base 12, and a motor 60 b is attached to the beam 16 provided in the main body 10 separately from the base 12. The motor 60a and the motor 60b are both shafts, and the output shaft 61a projects from the lower surface of the motor 60a, and the output shaft 61b projects from the lower surface of the motor 60b. A pulley 62a is fixed to the output shaft 61a, and the pulley 62a is connected to the pulley 15a of the inner shaft 14a by a belt 63a. A pulley 62b is fixed to the output shaft 61b, and this pulley 62b is connected to the pulley 15b of the outer shaft 14b by a belt 63b.

  Since the inner shaft 14a rotates the kneading blade 52, it is required to rotate at low speed and high torque. Since the outer shaft 14b rotates the grinding blade 70, high speed rotation is required. Therefore, the pulley 62a rotates the pulley 15a at a reduced speed, and the pulley 62b sets a diameter ratio between the pulleys so that the pulley 15Rb rotates at a constant speed or an increased speed. Further, a high-speed rotation type is selected as the motor 60b.

  The lid 30 is provided with a ceiling 31 at a portion covering the firing chamber 40. The ceiling 31 is formed by molding a sheet metal into a dome shape, and the top portion thereof is connected to a viewing window 32 provided on the lid 30. A heat-resistant glass is fitted into the viewing window 32.

  Operation control of the automatic bread maker 1 is performed by the control device 80 shown in FIG. The control device 80 is configured by a circuit board disposed at a proper position in the main body 10 (preferably a portion that is not easily affected by the heat of the baking chamber 40). In addition to the operation unit 20 and the heating device 41 described so far, a motor The temperature sensor 81 is connected to the motor driver 64a of 60a and the motor driver 64b of the motor 60b. The temperature sensor 81 is disposed in the baking chamber 40 and detects the temperature of the baking chamber 40. A commercial power supply 82 supplies power to each component.

  Then, the process of manufacturing bread from cereal grains using the automatic bread maker 1 will be described with reference to FIGS. 4 to 12.

  FIG. 4 is an overall flowchart of the first aspect bread manufacturing process. In FIG. 4, the process proceeds in the order of the impregnation process before grinding # 10, the grinding process # 20, the kneading process # 30, the fermentation process # 40, and the firing process # 50. Then, the content of each process is demonstrated.

In the pre-grinding impregnation step # 10 shown in FIG. 5, first, in step # 11, the user measures the grain and puts a predetermined amount into the bread container 50. Rice grains are the easiest to obtain as grain,
Other grains such as wheat, barley, straw, buckwheat, buckwheat, corn and the like can also be used.

  In step # 12, the user weighs the liquid and puts a predetermined amount into the bread container 50. A common liquid is water, but it may be a liquid having a taste component such as broth or fruit juice. Alcohol may be contained. Note that the order of step # 11 and step # 12 may be switched.

  The operation of putting the grain and liquid into the bread container 50 may be performed by removing the bread container 50 from the baking chamber 40 or may be performed while the bread container 50 is placed in the baking chamber 40.

  When the grain and liquid are put in the bread container 50 in the baking chamber 40, or when the bread container 50 containing the grain and liquid is attached to the bread container support 13R, the lid 30 is closed. Here, the user presses a predetermined operation key in the operation unit 20 to start the liquid impregnation time count. Step # 13 starts from this point.

  In Step # 13, the mixture of the grain and the liquid is allowed to stand in the bread container 50, and the grain is impregnated with the liquid. In general, since the impregnation is promoted as the liquid temperature increases, the heating means 41 may be energized to increase the temperature of the baking chamber 40.

  In step # 14, the control device 80 checks how much time has elapsed since the start of the resting of the grain and liquid. When the predetermined time has elapsed, the pre-grinding impregnation step # 10 ends. This is notified to the user by display on the operation unit 20 or by voice.

  Following the pre-grinding impregnation step # 10, the pulverization step # 20 shown in FIG. 6 is performed. When the user inputs grinding operation data (type and amount of grain, type of bread to be baked, etc.) through the operation unit 20 and presses the start key, the grinding is started.

  In step # 21, the control device 80 drives the motor 60b. Then, the outer shaft 14b and the outer shaft 53b rotate at a high speed rotation set for the grinding blade 70. The crushing blade 70 crushes the cereal grains in the mixture of the cereal grains and the liquid by the cutting blade 72. The pulverization by the pulverization blade 70 is performed in a state in which the liquid is immersed in the cereal grains, so that the cereal grains can be easily pulverized to the core. The protrusion 50a formed on the inner surface of the bread container 50 suppresses the flow of the mixture of the cereal grains and the liquid, and assists the pulverization. If the kneading blade 52 is stopped, the kneading blade 52 also suppresses the flow of the mixture of the grain and the liquid and assists the pulverization.

  In Step # 22, in order to obtain a desired pulverized grain, a pulverization pattern as set (however, if the pulverizing blade is continuously rotated, intermittently interlaced with a stop period, or intermittently rotated, the interval is taken. The control device 80 checks whether or not the rotation time length has been completed. When the set pulverization pattern is completed, the process proceeds to step # 23 to finish the rotation of the pulverization blade 70, and the pulverization step # 20 is completed. This is notified to the user by display on the operation unit 20 or by voice.

  In the above description, the pulverization step # 20 is started by the user's operation after the pre-grinding impregnation step # 10. If the pulverization operation data is input in the middle of No. 10, the pulverization step # 20 may be automatically started after the pre-pulverization impregnation step # 10 is completed.

Subsequent to the pulverization step # 20, the kneading step # 30 shown in FIG. 7 is performed. At the time of entering the kneading step # 30, the cereal grains and liquid in the bread container 50 are pasty or slurry dough raw materials. In the present specification, the material at the start of the kneading step # 30 is referred to as “dough raw material”, and the material that has come close to the intended state of the dough as the kneading progresses, ".

  In step # 31, the user opens the lid 30 and puts a predetermined amount of gluten into the dough material. Add seasoning ingredients such as salt, sugar and shortening as needed.

  The user inputs the type of bread and cooking details from the operation unit 20 before and after Step # 31. When the user presses the start key when the preparation is complete, the bread making operation that automatically continues from the kneading step # 30 to the fermentation step # 40 and further to the baking step # 50 is started.

  In step # 32, the control device 80 drives the motor 60a. Then, the inner shaft 14a and the inner shaft 53a rotate, and the kneading blade 52 starts rotating in the dough material. As described above, since the rotation of the motor 60a is transmitted to the inner shaft 14a after being decelerated, the rotation of the kneading blade 52 is of low speed and high torque.

  The controller 80 energizes the heating device 41 while driving the motor 60 to raise the temperature of the baking chamber 40. As the kneading blade 52 rotates, the dough raw material is kneaded and kneaded into a single dough having a predetermined elasticity. When the kneading blade 52 swings the dough and knocks it against the inner wall of the bread container 50, an element of “kneading” is added to the kneading. The protrusion 50a formed on the inner wall of the bread container 50 helps "kneading".

  In step # 33, the control device 80 checks how much time has elapsed since the start of the rotation of the kneading blade 52. When the predetermined time has elapsed, the process proceeds to step # 34.

  In step # 34, the user opens the lid 30 and puts yeast into the dough.

  In step # 35, the control device 80 checks how much time has passed since the yeast was added to the dough. When the time necessary to obtain the desired dough has elapsed, the process proceeds to step # 36, where the rotation of the kneading blade 52 is completed. At this point, the dough that is connected and has the required elasticity has been completed.

  In addition, the dry yeast may be sufficient as the yeast used in the dough in step # 34. Baking powder may be used instead of yeast.

  Subsequent to the kneading step # 30, the fermentation step # 40 shown in FIG. 8 is performed. In step # 41, the dough that has undergone the kneading step 30 is placed in a fermentation environment. That is, the control device 80 energizes the heating chamber 40 to the heating device 41 if necessary, and sets the temperature in a temperature zone where fermentation proceeds. The user arranges the dough, if necessary, and leaves the dough.

  In step # 42, the control device 80 checks how much time has passed since the dough was placed in the fermentation environment. If predetermined time passes, fermentation process # 40 will be complete | finished.

  Subsequent to the fermentation step # 40, the firing step # 50 shown in FIG. 9 is performed. In step # 51, the fermented dough is placed in a baking environment. That is, the control device 80 sends electric power necessary for baking to the heating device 41 and raises the temperature of the baking chamber 40 to the baking temperature zone.

In step # 52, the control device 80 checks how much time has passed since the dough was placed in the baking environment. When the predetermined time has elapsed, the firing step # 50 ends. Here, since the completion of bread making is notified by display or sound on the operation unit 20, the user opens the lid 30 and takes out the bread container 50.

  During the baking step # 50, the user can look into the inside of the bread container 50 through the viewing window 32 and check the degree of bread swell and the color of the baked color.

  Then, the 2nd aspect bread-making process is demonstrated based on FIG. 10 and FIG. FIG. 10 is an overall flowchart of the second aspect bread manufacturing process. In FIG. 10, the process proceeds in the order of pulverization step # 20, post-pulverization impregnation step # 60, kneading step # 30, fermentation step # 40, and firing step # 50. Next, the content of the post-grinding impregnation step # 60 will be described based on FIG.

  In step # 61, the dough raw material formed in the pulverization step # 20 is left in the bread container 50. This dough raw material has not been subjected to the impregnation step before pulverization. While standing still, liquid soaks into the ground grain. The control device 80 energizes the heating device 41 as necessary to heat the dough material and promote the impregnation.

  In step # 62, the control device 80 checks how much time has elapsed since the start of standing. When the predetermined time has elapsed, the post-grinding impregnation step # 60 is finished. When the post-grinding impregnation step # 60 is completed, the process proceeds to the kneading step # 30. The steps after the kneading step # 30 are the same as the first aspect bread making step.

  Then, the 3rd aspect bread-making process is demonstrated based on FIG. FIG. 12 is an overall flowchart of the third aspect bread manufacturing process. Here, the pre-pulverization impregnation step # 10 of the first aspect is placed before the pulverization step # 20, and the post-pulverization impregnation step 60 of the second aspect is placed after the pulverization step # 20. The steps after the kneading step 30 are the same as the first aspect bread making step.

  The pulverizing blade 70 can be used not only for pulverizing grains, but also for fragmenting ingredients such as nuts and leafy vegetables. For this reason, bread containing fine ingredients can be baked. The crushing blade 70 can also be used for crushing ingredients other than ingredients mixed in bread and crude drug ingredients.

  Since the kneading blade 52 and the pulverizing blade 70 are rotated by separate motors, the kneading blade 52 and the pulverizing blade 70 can be driven independently of each other's operation, and the kneading blade 52 and the pulverizing blade 70 respectively rotate optimally. It will be easier to give numbers. The motor 61a for rotating the kneading blade 52 and the motor 60b for rotating the grinding blade 70 are controlled by a single control device 80, so that the rotation of the grinding blade 70 and the rotation of the kneading blade 52 can be controlled in association with each other. It becomes possible. Therefore, in the stage of pulverizing the grain and the stage of kneading the pulverized grain powder, the rotation suitable for the type and amount of the grain is given to the grinding blade 70 and the kneading blade 52 to improve the quality of the bread. Can do.

  Although the embodiments of the present invention have been described above, the scope of the present invention is not limited to these embodiments, and various modifications can be made without departing from the spirit of the invention.

  The present invention is widely applicable to automatic bread machines used mainly in general households.

DESCRIPTION OF SYMBOLS 1 Automatic bread machine 10 Main body 12 Base 13 Bread container support part 14a Inner shaft 14b Outer shaft 20 Operation part 30 Lid 40 Baking chamber 50 Bread container 52 Kneading blade 53a Inner shaft 53b Outer shaft 60a Motor 60b Motor 70 Grinding blade 80 Control apparatus

Claims (3)

In an automatic bread maker that accepts a bread container containing bread-making ingredients in a baking chamber in the main body and sequentially performs the crushing process, kneading process, fermentation process, and baking process of the bread-making ingredients,
An automatic bread maker, wherein a kneading blade and a grinding blade are coaxially attached to the bottom of the bread container.   2. The automatic bread maker according to claim 1, wherein a kneading blade attached coaxially is attached above the grinding blade.   A double shaft penetrating the bottom of the bread container is provided, the kneading blade is attached to the inner shaft of the double shaft, and the grinding blade is attached to the outer shaft of the double shaft. The automatic bread maker according to 1 or 2.