Coffee machine

ES3073307T3Undetermined Publication Date: 2026-07-10DAITO ENTERTAINMENT INC (100 00)

Patent Information

Authority / Receiving Office
ES · ES
Patent Type
Patents
Current Assignee / Owner
DAITO ENTERTAINMENT INC (100 00)
Filing Date
2022-02-18
Publication Date
2026-07-10

AI Technical Summary

Technical Problem

The state of grinding coffee beans in a grinder can affect the taste of the extracted coffee beverage.

Method used

A coffee machine with two grinders, each driven by different motors, allows for adjustable rotation speeds and controlled input amounts of coffee beans based on type and degree of roasting, preventing beans from staying too long and being affected by heat.

Benefits of technology

This configuration ensures optimal grinding conditions for different types of coffee beans, maintaining flavor quality by minimizing heat exposure and adjusting particle size for better extraction.

✦ Generated by Eureka AI based on patent content.

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Patent Text Reader

Abstract

The present invention relates to a coffee maker comprising a second grinder for grinding coffee beans. The present invention provides a coffee maker controlled according to the grind level of the coffee beans. The coffee maker (with the GM grinder shown in Figure 18 and the beverage preparation device 1 shown in Figure 1) comprises a second grinder 5B that grinds coffee beans and is characterized in that the quantity of coffee beans fed into the second grinder 5B is controlled (step S24 shown in Figure 37).
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Description

Technical Field

[0001] The present invention relates to a coffee machine including a grinder for grinding coffee beans.Background Art

[0002] A coffee machine that performs preparation using coffee beans has been proposed (for example, Patent Literature 1). The coffee machine proposed in Patent Literature 1 is equipped with a coffee bean grinding device (grinder) and a coffee beverage extraction device. There are also coffee machines equipped with only a grinder.Citation ListPatent Literature

[0003] Patent Literature 1: Japanese Patent Laid-Open No. 2019-30433 EP3536157 A1 discloses a separation apparatus for separating an unwanted substance from an extraction target includes a forming unit configured to form a separation chamber through which the extraction target passes, and a suction unit communicating with the separation chamber in a direction crossing a passage direction of the extraction target and configured to suck air in the separation chamber. The forming unit includes an inlet for the extraction target, which communicates with the separation chamber, and an outlet for the extraction target, which communicates with the separation chamber, and the air is sucked from the outlet into the separation chamber by suction of the suction unit.Summary of InventionTechnical Problem

[0004] It has been found that a state for grinding coffee beans in this grinder may affect a taste of a coffee beverage extracted from ground beans.

[0005] In view of the above circumstances, an object of the present invention is to provide a coffee machine that is controlled in consideration of a state for grinding coffee beans in the grinder.Solution to Problem

[0006] The coffee machine according to the present invention for achieving the above object is a coffee machine according to claim 1. The coffee machine including: a first grinder configured to grind coffee beans by rotation of a first motor; and a second grinder disposed downstream of the first grinder and configured to grind coffee beans by rotation of a second motor, wherein the first motor and the second motor are different motors, the first grinder is capable of changing a rotation speed of the first motor according to a type of coffee beans, and an input amount of coffee beans to be put into the second grinder is controlled by controlling the rotation speed of the first motor.

[0007] In addition, The first grinder may be a grinder for coarse grinding, and the second grinder may be a grinder for fine grinding.

[0008] Further, the first motor may stop rotation before the second motor.

[0009] In addition, the coffee machine may be a coffee machine including a second grinder configured to grind coffee beans, in which an input amount of coffee beans to be put into the second grinder is controlled.

[0010] The coffee beans referred to herein may be cracked beans, ground beans, or beans that are not cracked or ground.

[0011] The input amount is controlled to prevent ground beans from staying in the second grinder for an unnecessarily long time. In the second grinder, when the input amount of coffee beans is larger than an output amount of ground beans, the ground beans stay in the second grinder for a longer time, and the ground beans are easily adversely affected by heat. Therefore, in the coffee machine, the input amount is controlled to prevent this from happening. Therefore, the machine is controlled in consideration of a state for grinding coffee beans in the grinder.

[0012] In the coffee machine, the input amount may be controlled in accordance with a type of coffee beans.

[0013] The type of coffee beans may be a variety of coffee beans, a degree of roasting of coffee beans, or a combination of the type and the degree of roasting.

[0014] The coffee machine may further include a first grinder provided upstream of the second grinder and configured to grind coffee beans, and the input amount of coffee beans to be put into the second grinder may be controlled by controlling a speed at which the first grinder grinds coffee beans.

[0015] The coffee machine may further include a supply device provided upstream of the second grinder and configured to supply coffee beans downstream, and the input amount of coffee beans to be put into the second grinder may be controlled by controlling a supply speed of coffee beans by the supply device.

[0016] The coffee machine may further include: a first grinder disposed upstream of the second grinder and configured to grind coffee beans; and a supply device disposed upstream of the first grinder and configured to supply coffee beans downstream, and at least one of the first grinder or the supply device may be controlled to reduce the input amount of coffee beans to be put into the second grinder.

[0017] For example, both the first grinder and the supply device may be controlled to reduce the input amount of coffee beans to be put into the second grinder.Brief Description of Drawings

[0018] [Figure 1] Figure 1 is an external view of a beverage production device 1. [Figure 2] Figure 2 is a partial front view of the beverage production device 1. [Figure 3] Figure 3 is a block diagram of a control device 11. [Figure 4] Figure 4 is a perspective view of a pulverizing device 5. [Figure 5] Figure 5 is a longitudinal cross-sectional view of the pulverizing device 5 shown in Figure 4. [Figure 6] Figure 6 is an external perspective view of a coffee bean grinding machine. [Figure 7] Figure 7 is a block diagram of a control device of the coffee bean grinding machine. [Figure 8] (a) of Figure 8 is a diagram showing a coffee bean grinding machine GM to which a hopper unit 402 is attached instead of a canister accommodation unit 401 shown in Figure 6, and (b) of Figure 8 is a diagram showing the coffee bean grinding machine GM to which a funnel unit 403 is attached. [Figure 9] (a) of Figure 9 is a diagram schematically showing a state in which a weighing unit 404 is attached to an option attachment portion GM11, and (b) of Figure 9 is a perspective view showing an electric screw conveyor ESC. [Figure 10] (a) of Figure 10 is a diagram showing a state in which a lid unit GM21 for opening and closing a bean outlet GM20 provided in a center casing GM10 of the coffee bean grinding machine GM is closed, and (b) of Figure 10 is a diagram showing a state in which the lid unit GM21 is opened. [Figure 11] Figure 11 is a diagram showing a main configuration of the pulverizing device 5 built in the coffee bean grinding machine GM in a posture in which a guide passage forming member GM22 faces the front. [Figure 12] Figure 12 is a perspective view of a first grinder 5A. [Figure 13] Figure 13 is a diagram schematically showing a configuration of a second grinder 5B. [Figure 14] Figure 14 is a flowchart showing a control process of the processing unit 11a in a grinding process. [Figure 15] Figure 15 is a diagram showing an example of data stored in a server 16. Description of Embodiments

[0019] An embodiment of the present invention will be described with reference to the drawings.<1. Overview of Beverage Production Device>

[0020] Figure 1 is an external view of a beverage production device 1. The beverage production device 1 shown in Figure 1 is a device for automatically producing a coffee beverage from roasted coffee beans and a liquid (here, water), and can produce a coffee beverage for one cup per one production operation. Roasted coffee beans as a raw material can be accommodated in canisters 40. A cup placing portion 110 is provided in a lower portion of the beverage production device 1, and a produced coffee beverage is poured into a cup from a pouring portion 10c.

[0021] The beverage production device 1 includes a housing 100 that forms an exterior of the beverage production device 1 and encloses an internal mechanism. The housing 100 is roughly divided into a main body portion 101 and a cover portion 102 that covers a part of a front surface and a part of a side surface of the beverage production device 1. The cover portion 102 is provided with an information display device 12. The information display device 12 shown in Figure 1 is a touch panel type display, and is capable of receiving an input from an administrator of the device or a beverage consumer in addition to displaying various types of information. The information display device 12 is attached to the cover portion 102 via a moving mechanism 12a, and can be moved in a predetermined range in an upper-lower direction by the moving mechanism 12a.

[0022] The cover portion 102 is provided with a bean inlet 103 and an opening and closing door 103a that opens and closes the bean inlet 103. Roasted coffee beans different from the roasted coffee beans accommodated in the canister 40 can be input to the bean inlet 103 by opening the opening and closing door 103a. As a result, it is possible to provide a cup of special beverage to a beverage consumer.

[0023] The cover portion 102 shown in Figure 1 is made of a translucent material such as acrylic or glass, and constitutes a transparent cover whose entire body is a transmissive portion. Therefore, an inner mechanism covered by the cover portion 102 can be visually recognized from the outside. In the beverage production device 1 shown in Figure 1, a part of a production portion for producing a coffee beverage can be visually recognized through the cover portion 102. The main body portion 101 shown in Figure 1 is entirely a non-transmissive portion, and it is difficult to visually recognize the inside of the main body portion 101 from the outside.

[0024] Figure 2 is a partial front view of the beverage production device 1, and is a diagram showing a part of the production portion that can be visually recognized by a user in a front view of the beverage production device 1. The cover portion 102 and the information display device 12 are shown by imaginary lines.

[0025] The housing 100 in a front portion of the beverage production device 1 has a double structure of the main body portion 101 and the cover portion 102 on an outer side (front side) of the main body portion 101. A part of mechanisms of the production portion are disposed between the main body portion 101 and the cover portion 102 in a front-rear direction, and can be visually recognized by a user through the cover portion 102.

[0026] A part of the mechanisms of the production portion that can be visually recognized by a user through the cover portion 102 include a collective conveying portion 42, a first grinder 5A, a second grinder 5B, a separation device 6, an extraction container 9, and the like. A rectangular concave portion 101a recessed in a rear side is formed in a front portion of the main body portion 101, and the extraction container 9 and the like are positioned in a rear side of the concave portion 101a.

[0027] Since these mechanisms can be visually recognized from the outside through the cover portion 102, an administrator may easily inspect or check the operation. In addition, a beverage consumer may enjoy a process of producing a coffee beverage.

[0028] A right end portion of the cover portion 102 is supported by the main body portion 101 via a hinge 102a so as to be freely opened and closed horizontally. An engaging portion 102b is provided at a left end portion of the cover portion 102 to maintain the main body portion 101 and the cover portion 102 in a closed state. The engaging portion 102b is, for example, a combination of a magnet and iron. By opening the cover portion 102, an administrator can inspect a part of the production portion described above on an inner side of the cover portion 102.

[0029] The cover portion 102 shown in Figure 1 is of a horizontal opening type, but may be of a vertical opening type or a slide type. In addition, the cover portion 102 may be configured such that the cover portion 102 cannot be opened or closed.< Bean Processing Device>

[0030] The bean processing device 2 will be described with reference to Figures 1 and 2. The bean processing device 2 includes a reservoir device 4 and a pulverizing device 5.< Reservoir Device>

[0031] The reservoir device 4 includes the plurality of canisters 40 in which roasted coffee beans are accommodated. Three canisters 40 shown in Figure 1 are provided. Each of the canisters 40 includes a cylindrical main body 40a for accommodating roasted coffee beans, and a handle 40b provided on the main body 40a, and is configured to be detachably attached to the beverage production device 1.

[0032] Each of the canisters 40 may accommodate different types of roasted coffee beans, and may be configured such that a type of roasted coffee beans used for producing a coffee beverage can be selected according to an operation input to the information display device 12. The roasted coffee beans of different types are, for example, roasted coffee beans of different coffee bean varieties. The roasted coffee beans of different types are coffee beans of the same type, but may be roasted coffee beans of different degrees of roasting. The roasted coffee beans of different types may be roasted coffee beans of different varieties and degrees of roasting. In addition, roasted coffee beans in which roasted coffee beans of a plurality of types and varieties are mixed may be accommodated in at least one of the three canisters 40. In this case, roasted coffee beans of each variety may have the same degree of roasting.

[0033] Although a plurality of canisters 40 are provided in the beverage production device 1 shown in Figure 1, only one canister 40 may be provided. When a plurality of canisters 40 are provided, roasted coffee beans of the same type may be accommodated in all or a plurality of canisters 40.

[0034] Each of the canisters 40 is detachably attached to a conveyor 41, which is a weighing conveying device. The conveyor 41 is, for example, an electric screw conveyor, and automatically measures a predetermined amount of roasted coffee beans accommodated in the canister 40 and feeds out the roasted coffee beans to a downstream side.

[0035] Each of the conveyors 41 discharges the roasted coffee beans to the collective conveying portion 42 on the downstream side. The collective conveying portion 42 is formed of a hollow member, and forms a conveying passage for roasted coffee beans from each of the conveyors 41 to the pulverizing device 5 (in particular, the first grinder 5A). The roasted coffee beans discharged from each of the conveyors 41 move inside the collective conveying portion 42 by an own weight thereof, and flow down to the pulverizing device 5.

[0036] A guide portion 42a is formed in the collective conveying portion 42 at a position corresponding to the bean inlet 103. The guide portion 42a forms a passage for guiding roasted coffee beans put from the bean inlet 103 to the pulverizing device 5 (in particular, the first grinder 5A). As a result, in addition to the roasted coffee beans accommodated in the canister 40, a coffee beverage made from roasted coffee beans put from the bean inlet 103 can be produced.<Pulverizing Device>

[0037] The pulverizing device 5 will be described with reference to Figures 2 The pulverizing device 5 includes the first grinder 5A, the second grinder 5B, and the separation device 6. The first grinder 5A and the second grinder 5B are mechanisms for grinding roasted coffee beans supplied from the reservoir device 4. The roasted coffee beans supplied from the reservoir device 4 are ground by the first grinder 5A, then further ground by the second grinder 5B into powder, and are put into the extraction container 9 from a discharge pipe 5C.

[0038] The first grinder 5A and the second grinder 5B have different particle sizes for grinding beans. The first grinder 5A is a grinder for coarse grinding, and the second grinder 5B is a grinder for fine grinding. The first grinder 5A and the second grinder 5B are electric grinders, and include a motor as a drive source, a rotary blade driven by the motor, and the like. A size (particle size) of roasted coffee beans to be ground can be changed by changing the number of rotations of the rotary blade.

[0039] The separation device 6 is a mechanism for separating wastes from ground beans. The separation device 6 includes a passage portion 63a disposed between the first grinder 5A and the second grinder 5B. The passage portion 63a is a hollow body that forms a separation chamber through which ground beans falling freely from the first grinder 5A pass. A passage portion 63b extending in a direction (for example, a left-right direction) intersecting a passing direction (for example, the upper-lower direction) of the ground beans is connected to the passage portion 63a, and a suction unit 60 is connected to the passage portion 63b. By the suction unit 60 suctioning the air in the passage portion 63a, lightweight objects such as chaff and fine powder are suctioned. As a result, the wastes can be separated from the ground beans.<Control Device>

[0040] A control device 11 of the beverage production device 1 will be described with reference to Figure 3. Figure 3 is a block diagram of the control device 11.

[0041] The control device 11 controls the entire beverage production device 1. The control device 11 includes a processing unit 11a, a storage unit 11b, and an interface (I / F) unit 11c. The processing unit 11a is, for example, a processor such as a CPU. The storage unit 11b is, for example, a RAM or a ROM. The I / F unit 11c includes an input and output interface that inputs and outputs a signal between an external device and the processing unit 11a. The I / F unit 11c also includes a communication interface capable of performing data communication with a server 16 via a communication network 15 such as the Internet. The server 16 can communicate with a mobile terminal 17 such as a smartphone via the communication network 15, and can receive, for example, information such as a reservation for beverage production or an impression from the mobile terminal 17 of a beverage consumer.

[0042] The processing unit 11a executes a program stored in the storage unit 11b, and controls an actuator group 14 based on an instruction from the information display device 12, a detection result of a sensor group 13, or an instruction from the server 16. The sensor group 13 includes various sensors (for example, a hot water temperature sensor, an operation position detection sensor of a mechanism, a pressure sensor) provided in the beverage production device 1. The actuator group 14 includes various actuators (for example, a motor, an electromagnetic valve, a heater, and the like) provided in the beverage production device 1.

[0043] Next, a modification of the pulverizing device 5 will be described. In the following description, components having the same names as those described above are denoted by the same reference numerals as those used above. The pulverizing device 5 described here has a different appearance from that of the pulverizing device shown in Figure 2, but has the same function.

[0044] Figure 4 is a perspective view of the pulverizing device 5, and Figure 5 is a longitudinal cross-sectional view of the pulverizing device 5 shown in Figure 4.

[0045] Similarly to the pulverizing device shown in Figure 2, the pulverizing device 5 shown in Figure 4 also includes the first grinder 5A, the second grinder 5B, and the separation device 6. The first grinder 5A and the second grinder 5B are mechanisms for grinding roasted coffee beans supplied from the reservoir device 4 shown in Figure 2. The first grinder 5A is a grinder for crushing coffee beans into a predetermined size (for example, about 1 / 4) to facilitate separation of wastes adhering to the coffee beans. The second grinder 5B is a grinder for grinding the coffee beans crushed by the first grinder 5A into ground coffee beans having a desired particle size. Therefore, the first grinder 5A and the second grinder 5B have different particle sizes for grinding beans, and the second grinder 5B is a grinder having a finer particle size than the first grinder 5A. The particle size of the ground beans in the second grinder 5B may have an error (about ± 5 µm), but can be adjusted by adjusting an interval between a rotary blade 58b and a fixed blade 57b.

[0046] The first grinder 5A includes a motor 52a (see Figure 4) and a main body portion 53a. The motor 52a is a drive source of the first grinder 5A. The main body portion 53a is a unit for accommodating a cutter, and includes a built-in rotation shaft 54a as shown in Figure 5. A gear 55a is provided on the rotation shaft 54a, and a driving force of the motor 52a is transmitted to the rotation shaft 54a via the gear 55a.

[0047] As shown in Figure 5, a rotary blade 58a, which is a cutter, is provided on the rotation shaft 54a. A fixed blade 57a, which is a cutter, is provided around the rotary blade 58a. The inside of the main body portion 53a communicates with an inlet 50a (see Figure 4) and a discharge port 51a (see Figure 5). Roasted coffee beans supplied from the reservoir device 4 shown in Figure 2 enter the main body portion 53a from the inlet 50a formed in an upper portion of the main body portion 53a, and are pulverized while being sandwiched between the rotary blade 58a and the fixed blade 57a shown in Figure 5. As shown in Figure 5, a preventing plate 56a is provided on an upper side of the rotary blade 58a of the rotation shaft 54a, and the preventing plate 56a prevents the roasted coffee beans from escaping to the upper side. In the first grinder 5A, the roasted coffee beans are ground to, for example, about 1 / 4. The pulverized ground beans are discharged from the discharge port 51a to the separation device 6.

[0048] Roasted coffee beans supplied to the inlet 50a may be supplied not from above the rotary blade 58a but at a height at which the roasted coffee beans come into contact with a side surface of the rotary blade 58a. In this case, since the roasted coffee beans are prevented from escaping to the upper side by the rotary blade 58a, the preventing plate 56a may not be provided.

[0049] The first grinder 5A may change a size of roasted coffee beans to be discharged after being pulverized by changing the number of rotations of the rotary blade 58a. The distance between the rotary blade 58a and the fixed blade 57a may be manually adjusted.

[0050] The separation device 6 shown in Figure 4 is a mechanism that is disposed between the first grinder 5A and the second grinder 5B and separates wastes such as chaff and fine powder from ground beans by an air suction force. Roasted coffee beans supplied from the reservoir device 4 are first coarsely ground by the first grinder 5A, and wastes are separated from the coarsely ground beans by the separation device 6. The coarsely ground beans from which the wastes are separated are finely ground by the second grinder 5B.

[0051] The second grinder 5B includes a motor 52b (see Figure 4) and a main body portion 53b. The motor 52b is a drive source of the second grinder 5B. The main body portion 53b is a unit for accommodating a cutter, and includes a built-in rotation shaft 54b as shown in Figure 5. A pulley 55b is provided on the rotation shaft 54b, and a driving force of the motor 52b is transmitted to the rotation shaft 54b via a belt 59b and the pulley 55b.

[0052] As shown in Figure 5, the rotary blade 58b is provided on the rotation shaft 54b, and the fixed blade 57b is provided on an upper side of the rotary blade 58b. The inside of the main body portion 53b communicates with the inlet 50b shown in Figure 4 and the discharge port 51b shown in Figure 4. Ground beans falling from the separation device 6 enter the main body portion 53b from the inlet 50b, and are further pulverized while being sandwiched between the rotary blade 58b and the fixed blade 57b. The ground beans pulverized into powder are discharged from the discharge port 51b. A particle size of the ground beans in the second grinder 5B can be adjusted by adjusting the interval between the rotary blade 58b and the fixed blade 57b.

[0053] Figure 6 is an external perspective view of a coffee bean grinding machine, and Figure 7 is a block diagram of a control device of the coffee bean grinding machine.

[0054] A coffee bean grinding machine GM shown in Figure 6 includes the reservoir device 4, the pulverizing device 5, and the control device 11 shown in Figure 7 that controls the reservoir device 4 and the pulverizing device 5. The coffee bean grinding machine GM also includes the information display device 12 (see Figure 7) wirelessly connected to the control device 11. The information display device 12 is a touch panel type display for inputting various control instructions, set values, and the like of the coffee bean grinding machine GM, and can receive inputs from an administrator or a user in addition to displaying various types of information. The information display device 12 is provided with a speaker and a camera.

[0055] The control device 11 controls the entire coffee bean grinding machine GM. The control device 11 includes the processing unit 11a, the storage unit 11b, and the interface (I / F) unit 11c. The processing unit 11a is, for example, a processor such as a CPU. The storage unit 11b is, for example, a RAM or a ROM. A recipe is stored in the storage unit 11b. The recipe includes information on various conditions for grinding coffee beans, beans information, recipe creator information, comments of a recipe creator, and the like. The I / F unit 11c includes an input and output interface that inputs and outputs a signal between an external device and the processing unit 11a. The I / F unit 11c also includes a communication interface capable of performing data communication with an external terminal such as the server 16 or the mobile terminal 17 via the communication network 15 such as the Internet. The server 16 can communicate with the mobile terminal 17 such as a smartphone via the communication network 15, and can receive, for example, information such as a reservation for production of ground beans of coffee and an impression from the mobile terminal 17 of a consumer. A coffee bean grinding system GS for grinding coffee beans includes the coffee bean grinding machine 1, the server 16, and the mobile terminal 17.

[0056] The processing unit 11a executes a program stored in the storage unit 11b, and controls the reservoir device 4 and the pulverizing device 5 according to the recipe. More specifically, the processing unit 11a controls the actuator group 14 according to the recipe, and controls the actuator group 14 based on an instruction from the information display device 12, a detection result of the sensor group 13, or an instruction from the server 16. The sensor group 13 includes various sensors (for example, an operation position detection sensor of a mechanism) provided in the reservoir device 4 and the pulverizing device 5. The actuator group 14 includes various actuators (for example, a motor) provided in the reservoir device 4 and the pulverizing device 5.

[0057] The reservoir device 4 shown in Figure 6 includes a cylindrical canister accommodation unit 401 and a detachable cap 401c that is screwed to an upper end portion of the canister accommodation unit 401 and covers an upper surface of the canister accommodation unit 401. A plurality of canister accommodation chambers (not shown) are provided inside the canister accommodation unit 401. The plurality of canister accommodation chambers are provided in a circumferential direction, and a plurality of canisters can be accommodated inside the canister accommodation unit 401. Here, the canister (not shown) has the same structure as the canister shown in Figures 1 and 2 except that the handle 40b is not provided. The plurality of canisters accommodated in the reservoir device 4 can be selectively used. Therefore, it is possible to perform a grinding process by selecting roasted coffee beans of different varieties or roasted coffee beans having different degrees of roasting, and it is also possible to perform a grinding process by mixing a plurality of types of roasted coffee beans of different varieties or degrees of roasting.

[0058] The canister accommodation unit 401 is detachably attached to an option attachment portion GM11 provided in an upper portion of a center casing GM10 of the coffee bean grinding machine GM. In addition to the canister accommodation unit 401, a plurality of types of units can be attached to the option attachment portion GM11. The upper portion of the center casing GM10 covers a lower portion of a unit attached to the option attachment portion GM11. A type of the unit attached to the option attachment portion GM11 may be displayed on an external terminal such as the mobile terminal 17 capable of communicating with the coffee bean grinding machine GM.

[0059] (a) of Figure 8 is a diagram showing the coffee bean grinding machine GM to which a hopper unit 402 is attached instead of the canister accommodation unit 401 shown in Figure 6, and (b) of Figure 8 is a diagram showing the coffee bean grinding machine GM to which a funnel unit 403 is attached.

[0060] Figure 6 is a perspective view of the coffee bean grinding machine GM as viewed obliquely from a front left side, and Figure 8 is a perspective view of the coffee bean grinding machine GM as viewed obliquely from a front right side.

[0061] The option attachment portion GM11 shown in Figure 6 is provided on an inner circumferential surface of the center casing GM10. A method of attaching each of the units to the option attachment portion GM11 may be a screwing method, a method in which a locking claw provided in each of the units is locked to the option attachment portion GM11, or a method in which a locking claw provided in the option attachment portion GM11 is locked to each of the units.

[0062] The hopper unit 402 shown in (a) of Figure 8 is a transparent container in which roasted coffee beans are accommodated, and an upper surface of the hopper unit 402 is covered with a detachable cap 402c. The hopper unit 402 corresponds to a large single canister.

[0063] On the other hand, the funnel unit 403 shown in (b) of Figure 8 is in a shape of a funnel whose inner side is tapered toward the option attachment portion GM11, and an upper end thereof is open. The funnel unit 403 also accommodates roasted coffee beans. In the funnel unit 403, the supply of roasted coffee beans to a downstream side is smooth as compared with the canister and the hopper unit 402. The canister accommodation unit 401, the hopper unit 402, and the funnel unit 403 are reservoir units capable of storing roasted coffee beans. These reservoir units (401 to 403) are provided with supply ports for supplying roasted coffee beans to the downstream side.

[0064] A weighing unit can also be attached to the option attachment portion GM11.

[0065] (a) of Figure 9 is a diagram schematically showing a state in which a weighing unit 404 is attached to the option attachment portion GM11.

[0066] In the coffee bean grinding machine GM shown in (a) of Figure 9, the canister accommodation unit 401 shown in Figure 8 is further attached to the weighing unit 404 attached to the option attachment portion GM11. The reservoir units (401 to 403) capable of storing roasted coffee beans can be detachably attached to the weighing unit 404. Similarly to the method of attaching each of the units to the option attachment portion GM11, a method of attaching the reservoir unit to the weighing unit 404 may be a screwing method, a method in which a locking claw provided in each of the units is locked to the weighing unit 404, or a method in which a locking claw provided in the weighing unit 404 is locked to the reservoir unit. In the example shown in (a) of Figure 9, locking claws 404k provided in the weighing unit 404 are locked to protruding portions GM11t of the option attachment portion GM11. Locking claws 401k provided in the canister accommodation unit 401 are locked to protruding portions 404t provided on an upper portion of an inner circumferential wall of the weighing unit 404.

[0067] The weighing unit 404 includes a receiving port 4040, a guiding passage 4041, a conveying passage 4042, and a feed-out port 4043. When the reservoir units (401 to 403) are attached to the weighing unit 404, a supply port USP of the reservoir unit is connected to the receiving port 4040 of the weighing unit 404, and roasted coffee beans stored in the reservoir unit are supplied to the receiving port 4040. The receiving port 4040 and an upstream side of the conveying passage 4042 are connected by the guiding passage 4041. In the conveying passage 4042 shown in (a) of Figure 9, a right side is the upstream side and a left side is a downstream side. An electric screw conveyor ESC is disposed in the conveying passage 4042, and roasted coffee beans are conveyed through the conveying passage 4042 and fed out from the feed-out port 4043 toward the pulverizing device 5. That is, the roasted coffee beans supplied to the receiving port 4040 are guided to the conveying passage 4042 through the guiding passage 4041, and are conveyed from the right side to the left side of the conveying passage 4042 shown in (a) of Figure 9. The conveying path 4042 shown in (a) of Figure 9 is horizontally provided, but a downstream end opening 4042o of the conveying path 4042 is formed to open obliquely upward. The conveying path 4042 may be inclined such that the downstream side is higher than the upstream side.

[0068] (b) of Figure 9 ia a perspective view showing the electric screw conveyor ESC.

[0069] In the electric screw conveyor ESC shown in (b) of Figure9, a right near side is an upstream side, and a left front side is a downstream side. The electric screw conveyor ESC includes a screw shaft ESC1 and a screw blade ESC2 spirally provided on an outer circumferential surface of the screw shaft ESC1. A motor ESC3 that rotationally drives the screw shaft ESC1 is built in an upstream end portion of the electric screw conveyor ESC. Roasted coffee beans guided to the conveying passage 4042 are conveyed through the conveying passage 4042 by the rotating screw blade ESC2. The control device 11 controls the rotation of the motor ESC3, and roasted coffee beans is automatically weighed by a rotation amount of the screw shaft ESC1. The electric screw conveyor ESC automatically weighs roasted coffee beans accommodated in the reservoir units (401 to 403) and conveys the roasted coffee beans toward the downstream side.

[0070] As shown in (a) of Figure 9, a cover member 460 is provided on the downstream end opening 4042o of the conveying passage 4042. As described above, the downstream end opening 4042o is formed obliquely upward, and the cover member 460 is also obliquely disposed. The cover member 460 includes a cover plate 461 and belt-shaped members 451.

[0071] Next, a bean outlet will be described.

[0072] (a) of Figure 10 is a diagram showing a state in which a lid unit GM21 for opening and closing a bean outlet GM20 provided in the center casing GM10 of the coffee bean grinding machine GM is closed, and (b) of Figure 10 is a diagram showing a state in which the lid unit GM21 is opened.

[0073] As described above, the option attachment portion GM11 is provided in the upper portion of the center casing GM10 of the coffee bean grinding machine GM. A start button GM15 for instructing the start of a grinding process by being pressed is provided in a middle portion in a height direction of the center casing GM10. Further, a lower portion of the center casing GM10 covers the first grinder 5A. The bean outlet GM20 shown in (b) of Figure 10 is provided downstream of the option attachment portion GM11 and upstream of the first grinder 5A. That is, when the weighing unit 404 is attached to the option attachment portion GM11, a position of the bean outlet GM20 is a position on a downstream side of the feed-out port 4043 (see (a) of Figure 9) of the weighing unit 404, and when the reservoir units (401 to 403) are attached to the option attachment portion GM11, the position is a position on a downstream side of the supply port USP (see (a) of Figure 9) of the reservoir units. Roasted coffee beans stored in the reservoir units (401 to 403) are fed out from the bean outlet GM20. In addition, when the weighing unit 404 is attached to the option attachment portion GM11, a surplus of the beans may be discharged from the bean outlet GM20 as a result of the weighing. A guide passage forming member GM22 is attached to the center casing GM10 so as to prevent the roasted coffee beans discharged from the bean outlet GM20 from being scattered. As shown in (b) of Figure10, the roasted coffee beans B discharged from the bean outlet GM20 are guided by the guide passage forming member GM22 and slide obliquely downward. When a collection container is attached to the vicinity of a tip end of the guide passage forming member GM22, the discharged roasted coffee beans can be easily collected in the collection container.

[0074] As shown in (b) of Figure10, the lid unit GM21 includes an inner lid GM211 and an outer lid 212. In a closed state shown in (a) of Figure 10, the inner lid GM211 is a part of a circumferential wall of a bean conveying passage (not shown) provided inside the center casing GM10. On the other hand, the outer lid GM212 is a member constituting a part of the center casing GM10 in the closed state shown in (a) of Figure 10. The bean outlet GM20 provided in the center casing GM10 is closed by the outer lid GM212.

[0075] For example, after the weighing by the weighing unit 404 is completed and the weighed roasted coffee beans are put into the first grinder 5A, the lid unit GM21 is automatically switched from a closed state to an open state under the control of the control device 11. When the lid unit GM21 is in the open state, the screw blade ESC2 resumes rotation, and remaining coffee beans are conveyed, and are discharged from the bean outlet GM20 before arriving the first grinder 5A. When roasted coffee beans remain in the electric screw conveyor ESC, roasted coffee beans of a different type are mixed when the roasted coffee beans of a different type are subjected to a grinding process in the next. Therefore, it is necessary to take out the remaining roasted coffee beans from the inside of the electric screw conveyor ESC to the outside. Even when the weighing unit 404 is not mounted and roasted coffee beans of the same type are used, the bean outlet GM20 effectively functions. Normally, until a rotation speed of a first motor of the first grinder 5A reaches a constant speed, roasted coffee beans are not supplied to the first grinder 5A, but beans remaining in front of the first grinder 5A are only discarded because they are ground by the first grinder 5A. However, if the bean outlet GM20 is provided, the remaining beans in front of the first grinder 5A can be collected from the bean outlet GM20, and the beans are not wasted. When the driving of the first grinder 5A is stopped, the lid unit GM21 automatically changes from the closed state to the open state under the control of the control device 11. When the lid unit GM21 is automatically changed to the open state, it is notified in advance that the lid unit GM21 will be opened. Not only in the case of remaining roasted coffee beans, but also in the case of stopping the grinding process in the middle, the lid unit GM21 is opened, and the roasted coffee beans can be taken out to the outside from the inside of the coffee bean grinding machine GM. Further, the lid unit GM21 may be manually opened. For example, when the first grinder 5A is being driven, the lid unit GM21 is automatically locked and cannot be opened, but when the first grinder 5A is stopped, the automatic lock may be released and the lid unit GM21 may be manually opened at any time. Alternatively, the lid unit GM21 may be opened according to an instruction from an external terminal such as the mobile terminal 17.

[0076] In a grinding method in the coffee bean grinding machine GM described above, first, the reservoir units (401 to 403) capable of storing coffee beans are attached to the option attachment portion GM11 provided upstream of the first grinder 5A (attachment step). Next, the coffee beans stored in the reservoir units attached to the option attachment portion GM11 are supplied to the first grinder 5A (supply step). Then, the supplied coffee beans are ground by the first grinder 5A (grinding step). Finally, the coffee beans remaining between the reservoir units (401 to 403) and the first grinder 5A are taken out to the outside from the bean outlet GM20 (take-out step).

[0077] The bean outlet GM20 and the outer lid 212 that opens and closes the bean outlet GM20 is also applicable to the beverage production device 1 shown in Figure 1. The bean outlet GM20 may be provided at a position below the bean inlet 103, which is upstream of the pulverizing device 5, by changing a mounting position of the information display device 12.

[0078] Next, the pulverizing device 5 of the coffee bean grinding machine GM will be described. The pulverizing device 5 includes the first grinder 5A, the second grinder 5B, and the separation device 6.

[0079] Figure 11 is a diagram showing a main configuration of the pulverizing device 5 built in the coffee bean grinding machine GM in a posture in which the guide passage forming member GM22 shown in Figure 10 faces the front.

[0080] In Figure 11, the first grinder 5A, the forming unit 6B, and the second grinder 5B are disposed from an upstream side. That is, the forming unit 6B is provided downstream of the first grinder 5A and upstream of the second grinder 5B. The first grinder 5A and the second grinder 5B are mechanisms that grind roasted coffee beans supplied from a reservoir unit such as the canister accommodation unit 401, the hopper unit 402, or the funnel unit 403. When the weighing unit 404 shown in (a) of Figure 9 is attached, the first grinder 5A and the second grinder 5B serve as mechanisms that grind roasted coffee beans conveyed by the electric screw conveyor ESC. A connecting structure of the first grinder 5A and the forming unit 6B is the same as the connecting structure described with reference to Figure 5, that is, the forming unit 6B is provided with the cylindrical portion 65 (see Figure 5), which is not shown in this example, and the discharge port 51a (see Figure 5 or Figure 12) of the first grinder 5A is connected to the opening portion 65a (see Figure 5) at an upper end of the cylindrical portion 65.

[0081] An upper end of a coupling duct 661 is connected to the discharge port 66 of the forming unit 6B. In Figure11, a lower side portion of the coupling duct 661 is obscured by the manual setting disc dial 695.

[0082] Figure 11 shows the fixed blade 57b disposed on an upper side and the rotary blade 58b disposed on a lower side, which constitute the second grinder 5B.

[0083] The fixed blade 57b can be moved up and down with respect to the rotary blade 58b, and a particle size of ground beans can be adjusted by adjusting an interval between the rotary blade 58b and the fixed blade 57b. Figure 11 also shows a worm wheel 691 and a worm gear 692 that meshes with the worm wheel 691 as a part of a lifting mechanism of the fixed blade 57b.

[0084] First, the first grinder 5A will be described.

[0085] Figure 12 is a perspective view of the first grinder 5A.

[0086] The first grinder 5A shown in Figure 12 is a grinder for crushing coffee beans into a predetermined size (for example, about 1 / 4) to facilitate separation of wastes adhering to the coffee beans. A rotation shaft (not shown in Figure 12) extends from above, and the rotary blade 58a serving as a cutter is provided on the rotation shaft. The fixed blade 57a, which is a cutter, is provided around the rotary blade 58a. The fixed blade 57a shown in Figure 12 is provided on an inner circumferential surface of the main body portion 53a. The rotation shaft is rotated by a first motor (not shown) (see the motor 52a shown in Figure 4), and the rotary blade 58a is rotated.

[0087] Roasted coffee beans introduced into a bean conveying passage provided inside the center casing GM10 pass through a portion blocked by the inner lid GM211 shown in (b) of Figure 10, and arrive the first grinder 5A.

[0088] Figure 13 is a diagram schematically showing a configuration of the second grinder 5B.

[0089] The second grinder 5B includes the second motor 52b, a motor base 502, a base portion 505a, and a particle size adjusting mechanism 503.

[0090] The second motor 52b is a drive source of the second grinder 5B, and is supported above the motor base 502. A pinion gear 52b' fixed to an output shaft of the second motor 52b and a gear 502a that meshes with the pinion gear are disposed above the motor base 502.

[0091] A gear 55b' that meshes with the gear 502a is disposed above the base portion 505a. The rotation shaft 54b is fixed to the gear 55b', and the rotation shaft 54b is rotatably supported by the base portion 505a. The rotation shaft 54b is rotated by a driving force of the second motor 52b transmitted to the gear 55b' via the gear 502a. The rotary blade 58b is provided at an end portion of the rotation shaft 54b, and the fixed blade 57b is provided above the rotary blade 58b. That is, the fixed blade 57b is disposed to face the rotary blade 58b.

[0092] The particle size adjusting mechanism 503 includes a motor 503a as a drive source thereof and the worm gear 692 rotated by a driving force of the motor 503a. The gear portion 691g of the worm wheel 691 meshes with the worm gear 692.

[0093] Figure 13 shows a frame member 694. The frame member 694 is fixedly disposed in a casing (not shown), and a screw groove is provided on an inner circumferential surface of the frame member 694. The screw groove 693s provided on the outer circumferential surface of the holder portion 693 meshes with the screw groove of the frame member 694. As described above, the fixed blade 57b is screwed to the connecting portion of the worm wheel 691 via the holder portion 693. Therefore, when the gear portion 691g of the worm wheel 691 rotates, the fixed blade 57b moves up and down in an axial direction of the gear portion 691g. The coupling port 691j of the worm wheel 691 is connected so as to overlap the lower end of the coupling duct 661, and the connection with the lower end of the coupling duct 661 is maintained even when the worm wheel 691 moves downward. The fixed blade 57b shown in Figure 13 is positioned at an initial position and is in a state of being most distant from the rotary blade 58b.

[0094] The processing unit 11a shown in Figure 7 controls a rotation amount of the motor 503a to adjust a gap between the rotary blade 58b and the fixed blade 57b. By adjusting this gap, a particle size of ground beans in the second grinder 5B can be adjusted.

[0095] The fixed blade 57b that moves up and down has a detection position that is a predetermined distance (for example, 0.7 mm) separated from the rotary blade 58b. The detection position is a position closer to the rotary blade 58b than the initial position of the fixed blade 57b. The second grinder 5B is provided with a sensor 57c that detects the fixed blade 57b is at the detection position.

[0096] The second grinder 5B described above performs an initial operation when the coffee bean grinding machine GM is turned on. In the initial operation of the second grinder 5B, calibration is executed.

[0097] Figure 14 is a flowchart showing a control process of the processing unit 11a in the grinding process.

[0098] The control process shown in Figure 14 is started in response to pressing of the start button GM15 shown in Figure 10. When the weighing unit 404 shown in Figure 9 is attached to the option attachment portion GM11, the control process may be started in response to the start of the rotation of the screw blade ESC2 shown in (b) of Figure 9.

[0099] First, the processing unit 11a starts the rotation of the first motor for the first grinder 5A and the second motor 52b for the second grinder 5B (step S21). In step S21, both the first motor and the second motor 52b start rotating at preset rotation speeds. As a result, the rotary blade 58a starts rotating in the first grinder 5A, and the rotary blade 58b starts rotating in the second grinder 5B. The rotation of the first motor and the rotation of the second motor 52b may not be started at the same time, and the rotation of the second motor 52b may be started after the rotation of the first motor is started. For example, when the grinding process is started by the first grinder 5A, the rotational torque or the current value of the first motor increases. The processing unit 11a may start the rotation of the second motor 52b when detecting an increase in the rotational torque or an increase in the current value of the first motor. When the first motor for the first grinder 5A starts to rotate, the cracked beans are fed to the second grinder 5B.

[0100] In the subsequent step S22, it is determined whether to continue the rotation of the first motor. For example, if a predetermined time elapses after the electric screw conveyor ESC finishes conveying, if a predetermined time elapses after the rotational torque of the first motor decreases, or if a predetermined time elapses after the current value of the first motor decreases, the determination result is No, and the rotation of the first motor is stopped (step S27). On the other hand, if the determination result is Yes, the process proceeds to step S23.

[0101] A sensor for detecting passage of the cracked beans is provided in the vicinity of an inlet of the second grinder 5B, and the processing unit 11a shown in Figure 7 monitors an input amount of the cracked beans to be put into the second grinder 5B per unit time. In step S23, it is determined whether the input amount per unit time exceeds a reference value. The reference value is a variable that varies depending on the type of coffee beans, the particle size of ground beans, the rotation speed set in the second motor 52b, and the like, and a plurality of types of reference values are stored in the storage unit 11b shown in Figure 7. For example, the harder the coffee beans, the smaller the reference value. The recipe specifies the type of coffee beans, the particle size of ground beans, and the like, and the processing unit 11a selects a reference value according to the recipe and executes the determination process of step S23, or selects a reference value according to various set values and executes the determination process of step S23. When the input amount per unit time exceeds the reference value, the rotation speed of the first motor is reduced (step S24), and the process returns to step S22. A rate of reducing the rotation speed of the first motor may be a predetermined rate, or may be a rate corresponding to a degree at which the input amount exceeds the reference value. When the rotation speed of the first motor is decreased, the amount of cracked beans fed out from the first grinder 5A per unit time is reduced. As a result, the input amount can also be reduced, the ground beans can be prevented from staying between the fixed blade 57b and the rotary blade 58b, and the ground beans are hardly affected by heat. A coffee beverage extracted from the ground beans ground in this way tends to have a refreshing taste without being adversely affected by oil content.

[0102] If it is determined in step S23 that the input amount is equal to or less than the reference value, it is determined whether the rotation speed of the first motor is in a state of being reduced. If the rotation speed is not in a state of being reduced, the process returns to step S22, and if the rotation speed is in a state of being reduced, the rotation speed is restored to the set rotation speed (step S26), and then the process returns to step S22.

[0103] In step S28 following step S27 of stopping the rotation of the first motor, it is determined whether to stop the rotation of the second motor 52b this time. For example, if a predetermined time elapses after the rotational torque of the second motor 52b decreases or if a predetermined time elapses after the current value of the second motor 52b decreases, the determination result is Yes, the rotation of the second motor 52b is stopped (step S29), and the control process ends.

[0104] In the control process described above, although the input amount of ground beans to be put into the second grinder 5B is controlled by controlling the rotation speed of the first motor for the first grinder 5A, the input amount of ground beans to be put into the second grinder 5B can also be controlled by controlling a rotation speed of the motor ESC3 that rotates the screw blade ESC2 of the weighing unit 404 shown in Figure 9. By controlling both the rotation speed of the first motor and the rotation speed of the motor ESC3, it is also possible to control the input amount of ground beans to be put into the second grinder 5B.

[0105] The control process shown in Figure 14 can also be executed by the processing unit 11a shown in Figure 3, and by controlling the rotation speed of the motor 52a for the first grinder 5A shown in Figure 4 or by controlling a conveying speed of the conveyor 41 shown in Figure 2, the input amount of ground beans to be put into the second grinder 5B shown in Figure 2 can be controlled.

[0106] A rotation speed of the rotary blade 58a of the first grinder 5A may change depending on the hardness or the like of roasted coffee beans. Originally, although the rotation speed of the first motor of the first grinder 5A is set so as not to exceed the allowable amount of the grinding process by the second grinder 5B, the number of rotations per unit time (rotation speed) of the rotary blade 58a or the first motor of the first grinder 5A may be monitored, and when the number of rotations per unit time exceeds the reference value, the rotation speed of the first motor may be reduced.

[0107] The control process in the grinding process described above with reference to Figure 14 is also applicable to the control process in the grinding process of the pulverizing device of the beverage production device 1 shown in Figure 1. An instruction to reduce or restore the rotation speed of the first motor may be output from an external terminal such as the mobile terminal 17 shown in Figure 7.

[0108] According to the above description, "a coffee machine [for example, the coffee bean grinding machine GM shown in Figure 6 or the beverage production device 1 shown in Figure 1] including: a second grinder configured to grind coffee beans [for example, the second grinder 5B], in which an input amount of coffee beans to be put into the second grinder is controlled [for example, step S24 shown in Figure 14]" has been described.

[0109] According to this coffee machine, the input amount is controlled in consideration of a state for grinding coffee beans in the grinder.

[0110] The coffee beans referred to herein may be cracked beans, ground beans, or beans that are not cracked or ground.

[0111] The input amount is controlled to prevent ground beans from staying in the second grinder for an unnecessarily long time. In the second grinder, when the input amount of coffee beans is larger than an output amount of ground beans, the ground beans stay in the second grinder for a longer time, and the ground beans are easily adversely affected by heat. Therefore, in the coffee machine, the input amount is controlled to prevent this from happening. Therefore, the machine is controlled in consideration of a state for grinding coffee beans in the grinder.

[0112] "The coffee machine in which the input amount is controlled according to a type of coffee beans" has also been described.

[0113] The type of coffee beans may be a variety of coffee beans, a degree of roasting of coffee beans, or a combination of the type and the degree of roasting.

[0114] "The coffee machine further including: a first grinder [for example, the first grinder 5A] provided upstream of the second grinder and configured to grind coffee beans, in which the input amount of coffee beans to be put into the second grinder is controlled by controlling a speed [for example, the rotation speed of the first motor] at which the first grinder grinds coffee beans" has also been described.

[0115] "The coffee machine further including: a supply device [for example, the weighing unit 404 shown in Figure 9 and the conveyor 41 shown in Figure 2] provided upstream of the second grinder and configured to supply coffee beans downstream, in which the input amount of coffee beans to be put into the second grinder is controlled by controlling a supply speed of coffee beans by the supply device" has also been described.

[0116] "The coffee machine further including: a first grinder [for example, the first grinder 5A] disposed upstream of the second grinder and configured to grind coffee beans; and a supply device [for example, the weighing unit 404 shown in Figure 9 and the conveyor 41 shown in Figure 2] disposed upstream of the first grinder and configured to supply coffee beans downstream, in which at least one of the first grinder or the supply device is controlled to reduce the input amount of coffee beans to be put into the second grinder" has also been described.

[0117] For example, both the first grinder and the supply device may be controlled to reduce the input amount of coffee beans to be put into the second grinder.

[0118] Further, "a coffee machine system (for example, Figure 3 or Figure 7) including an external device (for example, the server 16 or the mobile terminal 17) capable of communicating with the coffee machine" has also been described.

[0119] In addition, "a grinding method of coffee beans including: a step of starting to put coffee beans into a second grinder (step S21 shown in Figure 14); and a step of controlling an input amount of coffee beans to be put into the second grinder (step S24 shown in Figure 14)" has also been described.

[0120] Ground beans ground by the second grinder 5B are discharged from a chute GM31 shown in Figure 6.

[0121] The chute GM31 shown in Figure 6 guides the ground beans fed out in a substantially horizontal direction downward. The coffee bean grinding machine GM shown in Figure 6 is provided with a hammer member GM32 that strikes the chute GM31. The hammer member GM32 pivots about a pivot shaft GM321 extending in the upper-lower direction. The ground beans fed out in a substantially horizontal direction may collide with and adhere to an inner wall of the chute GM31. A user pivots the hammer member GM32 to strike the chute GM31, and applies an impact to the adhered ground beans to cause the ground beans to fall.

[0122] Here, a recipe will be described in detail. The recipe includes a grinding recipe including only grind information for grinding coffee beans, and a beverage production recipe including information on various production conditions for preparing a coffee beverage, such as extraction conditions for a coffee beverage, in addition to the grind information. In the coffee bean grinding machine GM, a grinding process can be executed as long as there is a grinding recipe, but if a beverage production recipe is displayed on the information display device 12, grinding conditions may be corrected in view of conditions of a coffee beverage extraction process executed after the grinding process, and a better quality coffee beverage may be obtained.

[0123] The storage unit 11b shown in Figure 7 may keep storing a recipe, or may acquire a recipe from the server 16 before starting the grinding process, store the recipe only while the grinding process is being executed, and delete the recipe from the storage unit 11b when the grinding process ends. Alternatively, only a part of the information of a recipe (for example, beans information or recipe creator information) may be stored in the storage unit 11b, the remaining information of the recipe (for example, information of various conditions for grinding coffee beans) may be acquired from the server 16 before the grinding process is started, and the remaining information may be deleted from the storage unit 11b when the grinding process ends. Recipes stored in the storage unit 11b are encrypted.

[0124] The recipes are managed as a database in the server 16.

[0125] (A) to (C) of Figure 15 are diagrams showing an example of data stored in the server 16. (A) of Figure 15 shows data 1500 stored in a beverage information database. The data 1500 includes a recipe ID 1501, creator information 1502 indicating a creator of a recipe, number-of-times-of-production information 1503 indicating the number of times of production in which beverage information has been selected by a user in the past, raw material information, a production method, and types 1512 and 1513. The raw material information includes beans information 1504 indicating a type of beans, production area information 1505 indicating a production area of beans, and information of a degree of roasting 1506 indicating a degree of roasting of beans. The production method includes the amount of beans used in one extraction 1507, a grinding particle size of beans 1508, a steaming hot water amount 1509, a steaming time 1510, and an extracted hot water amount 1511. Among these pieces of information, the most necessary information in a grinding process is the grinding particle size of beans 1508, but other pieces of information may also be necessary in considering the grinding particle size of beans 1508. A type 1 (1512) is type information indicating whether a beverage is a hot beverage or an iced beverage, and a type 2 (1513) is type information indicating the flavor of the beverage. In the present embodiment, although the number-of-times-of-production information 1503 is described as the number of times a beverage corresponding to the number-of-times-of-production information 1503 has been produced by a plurality of beverage production devices, the number-of-times-of-production information 1503 may be stored for each of the beverage production devices.

[0126] (B) of Figure 15 shows exemplary data 1520 of a user information database. A user may be a store, or a clerk or a customer of the store. The data 1520 includes ID information 1521 indicating a user identifier, name information 1522 indicating a name of a user, age information 1523 indicating the age of a user, and gender information 1524 indicating the gender of a user. For example, the data 1520 may further include information corresponding to an address of a user, nickname information of a user, and photograph data of a user.

[0127] (C) of Figure 15 shows exemplary data 1530 of a grinding history database. The data 1530 includes user information 1531 on a user who instructed grinding, date and time information 1532 on a grinding date and time, a recipe ID 1533 used in a grinding process, a machine ID 1534 corresponding to the coffee bean grinding machine GM that performed a grinding process, and a store ID 1535 corresponding to a store where the coffee bean grinding machine GM is installed. For example, the data 1530 may further include price information corresponding to the price of ground beans of ground coffee. In addition, a coffee beverage production history database may also be stored, similar to the grinding history database.

[0128] The data 1500, 1510, and 1530 described above may also be stored in the storage unit 11b of the control device 11 in the coffee bean grinding machine GM.

[0129] The present invention is not limited to the embodiments and examples described above, and the contents thereof can be combined with each other without departing from the spirit of the present invention, and may be partially changed according to an object or the like. The individual terms described in the present specification are merely used for describing the present invention, and it is needless to say that the present invention is not limited to the strict meaning of the terms, and can include equivalents thereof. For example, expressions such as "device" and "portion" may be rephrased as "unit", "module", or the like.Reference Signs List

[0130] 1 beverage production device 4 reservoir device 5 pulverizing device 5A first grinder 57a fixed blade 58a rotary blade 5B second grinder 57b fixed blade 58b rotary blade 11 control device 11a processing unit 12 information display device 17 mobile terminal GM coffee bean grinding machine

Claims

1. A coffee machine (1, GM), comprising: a first grinder (5A) configured to grind coffee beans by rotation of a first motor (52a); a second grinder (5B) disposed downstream of the first grinder (5A) and configured to grind coffee beans by rotation of a second motor (52b, 503a); a storage unit (11b) storing a recipe including information on various conditions for grinding coffee beans; a processing unit (11a); a sensor for detecting passage of cracked beans provided in a vicinity of an inlet of the second grinder (5B), wherein: the first motor (52a) and the second motor (52b, 503a) are different motors, the storage unit (11b) stores a plurality of types of reference value; the processing unit (11a) monitors an input amount of the coffee beans to be put into the second grinder (5B) by the sensor, the processing unit (11a) selects a reference value among the plurality types of reference value depending to the information specified by the recipe and reduces the rotation speed of the first motor (52a) based on the selected reference value and the input amount of the coffee beans monitored by the sensor to be put into the second grinder (5B), and the processing unit (11a) reduces the rotation speed of the first motor (52a) when the input amount to the second grinder (5B) exceeds the reference value.

2. The coffee machine (1, GM) according to claim 1, wherein: the processing unit (11a) restores the rotation speed of the first motor (52a) to a set rotation speed when the input amount of the coffee beans to the second grinder (5B) is equal to or less than the selected reference value where the rotation speed of the first motor is in a state of being reduced.