JP2018082828A - Beverage manufacturing apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a beverage manufacturing apparatus having a milk foamer with high maintainability.SOLUTION: A large diameter gear 742 and a small diameter gear are housed in a case 741 while meshing with each other. The large diameter gear 742 incorporates a pump side magnet 745 magnetically coupled with a motor side magnet 252 that rotates by a motor 25 for a gear pump. The small diameter gear rotates following the rotation of the large diameter gear 742. The large diameter gear 742 and the small diameter gear have no axles in the rotary shafts. A recess is formed at least either on two lateral faces of the large diameter gear 742 perpendicular to the rotary shafts of the large diameter gear 742 or on two inner faces of the case 741 contacting the two lateral faces.SELECTED DRAWING: Figure 12

Description

  The present disclosure relates to a beverage manufacturing apparatus that uses milk.

  2. Description of the Related Art Conventionally, beverage production apparatuses that produce and / or supply coffee beverages and soft drinks have become widespread. Such a beverage production apparatus includes a device for producing a coffee beverage by mixing foamed milk or steamed milk with coffee, for example. Note that the foamed milk is a whipped milk. Steamed milk is milk warmed with steam.

  As a beverage production apparatus provided with an apparatus (milk former) capable of producing foamed milk or steamed milk, there is a technique disclosed in Patent Document 1, for example. Patent Document 1 discloses the following milk former. That is, the milk sent out from the milk container is mixed with air in the first mixing chamber, and a mixture of foamed milk and air (ie, foamed milk) is generated. The foamed milk produced in the first mixing chamber is compressed by a milk pump and then heated by high-temperature steam in the second mixing chamber as necessary. The foamed milk that has flowed out of the second mixing chamber flows into the tempering device. The conditioner homogenizes the foamed milk, whereby the bubbles in the foamed milk are refined and more uniformly distributed in the milk.

JP 2014-213209 A

  However, the milk former disclosed in Patent Document 1 has a problem of low maintainability. For this reason, the drink manufacturing apparatus which has a milk former with high maintainability is desired.

  The objective of this indication is providing the drink manufacturing apparatus which has a milk former with high maintainability.

  The beverage production device of the present disclosure is a beverage production device including a gear pump having a first gear and a second gear, and a case accommodated inside the first gear and the second gear engaged with each other, The first gear includes a motor-side magnet that is rotated by a motor that generates a driving torque for rotating the first gear and a pump-side magnet that is magnet-coupled, and the second gear is a rotation of the first gear. The first gear and the second gear do not have a mandrel that is the center of the rotation, and the two side surfaces of the first gear are perpendicular to the rotation axis of the first gear. Alternatively, a recess is provided on at least one of the two inner surfaces of the case that contacts the two side surfaces.

  According to this indication, it has a milk former with high maintenance nature.

The perspective view of the beverage manufacturing apparatus which concerns on embodiment of this indication Diagram showing the configuration of the coffee extraction unit The figure which shows the structure of a steam supply part, a milk supply part, and an air supply part Enlarged perspective view of the nozzle unit Exploded perspective view of nozzle unit This is a left side view of the milk former, with the inside partially partially seen through FIG. 4 is a partial cross-sectional view of the branch portion and the valve as viewed from the left side, and shows switching between the first outlet and the second outlet The figure which shows the state which the valve and the valve side gear separated The figure which shows the state which the valve and the valve side gear separated Bottom view of nozzle unit and valve motor The figure which looked at the longitudinal cross-section of the milk former along line A-A 'of FIG. 4 from the back side of the beverage manufacturing apparatus. Exploded perspective view of gear pump and peripheral configuration The figure for demonstrating the magnet coupling of a pump side magnet and a motor side magnet As an example of a gear pump, a diagram illustrating a configuration in which a large diameter gear and a small diameter gear each have a mandrel Diagram showing the dimensions of the large and small diameter gears and the internal space of the case

  Hereinafter, each embodiment of the present disclosure will be described in detail with reference to the drawings. However, a more detailed description than necessary, for example, a detailed description of already well-known matters or a duplicate description of substantially the same configuration may be omitted.

  The following description and the drawings referred to are provided for those skilled in the art to understand the present disclosure, and are not intended to limit the scope of the claims of the present disclosure.

<Definition of direction>
First, directions in the following embodiments will be defined. The direction along the axis from left to right or right to left when the front surface of the beverage production apparatus 1 faces the user is defined as the left-right direction. In addition, a direction from the front to the back of the beverage production apparatus 1 or from the back to the front when the front of the beverage production apparatus 1 faces the user is defined as the front-rear direction. In addition, a direction from the bottom surface to the top surface or the top surface to the bottom surface of the beverage production device 1 when the front surface of the beverage production device 1 and the user face each other is defined as a vertical direction. Hereinafter, the axes along the left-right direction, the front-rear direction, and the up-down direction may be referred to as an x-axis, a y-axis, and a z-axis, respectively.

<1. First Embodiment>
<1-1. Schematic configuration of beverage production apparatus 1>
FIG. 1 is a perspective view of the beverage manufacturing apparatus 1. The beverage manufacturing apparatus 1 is for business use, for example, and is installed in a store or the like. The beverage production apparatus 1 includes a main body 2, a door 3, a button group 4 (see a portion surrounded by a dotted line), a canister 5, a milk cool box 6, a nozzle unit 7, and a drip tray 8. I have.

  The door 3 is attached to the front surface of the main body 2 so as to be freely opened and closed. The button group 4 is disposed on the front surface of the door 3. The plurality of buttons included in the button group 4 include beverage types (espresso coffee, drip coffee (hot ice), latte (hot ice), cappuccino (hot ice), etc.) that the beverage production apparatus 1 can provide. Are assigned to each. When a button to which a desired beverage is assigned is operated by the user, the beverage manufacturing apparatus 1 manufactures and provides the beverage assigned to the operated button. In addition, the drink manufacturing apparatus 1 in this Embodiment shall manufacture the drink using coffee.

  The canister 5 is attached to the upper surface of the main body 2 and stores coffee beans. The milk cooler 6 stores at least one milk pack 9 (see FIG. 3 described later) and stores it at a low temperature.

  The nozzle unit 7 is provided on the front surface of the main body 2 and discharges the beverage produced inside the main body 2 downward. Further, the nozzle unit 7 generates foamed milk (hot and cold), steam milk (hot), cold milk and the like using the milk supplied from the milk pack 9 and discharges it downward. These milk and beverages produced inside the main body 2 are separately discharged from the nozzle unit 7 and mixed in the container 10 to produce various beverages.

The drip tray 8 projects forward from the lower end of the main body 2. The beverage discharged from the nozzle unit 7 is provided to the beverage container 10 placed on the drip tray 8. Also,
The drip tray 8 collects and stores beverages dripping from the nozzle unit 7 or spilling from the container 10.

  As shown in FIG. 2, which will be described later, inside the main body 2, a coffee extraction unit 21 that generates coffee using coffee beans stored in the canister 5 is provided. Further, as shown in FIG. 3 described later, a steam supply unit 22 and an air supply unit 24 are further provided inside the main body 2. A milk supply unit 23 is provided outside the main body 2. The applicant of the present application discloses a coffee extraction unit, a steam supply unit, a milk supply unit, and an air supply unit in JP2013-165814A. Therefore, in this embodiment, the part corresponding to the disclosed content of JP2013-165814A will be briefly described.

  FIG. 2 is a diagram illustrating the configuration of the coffee extraction unit 21. As shown in FIG. 2, the coffee extraction unit 21 includes a hot water tank 211, a hot water pump 212, a filter 213, a hot water supply valve 214, a coffee side hot water supply pipe 215, an elevating device 216, a cylinder unit 217, a cap 218, a coffee liquid pipe 2212, and a mill 2213.

  The hot water tank 211 is a tank open to the atmosphere, and stores a predetermined amount of drinking water in a state heated to a predetermined temperature by a built-in heater (not shown).

  The hot water pump 212 is a pump that pressurizes and discharges hot water in the hot water tank 211. The upstream end of the coffee side hot water supply pipe 215 is connected to the discharge port of the hot water pump 212. The coffee side hot water supply pipe 215 is provided with a filter 213 and a hot water supply valve 214 made of an electromagnetic valve or the like in this order from the upstream side. The downstream end of the coffee-side hot water supply pipe 215 is detachably connected to a hot water supply port of a cylinder 219 described later.

  The cylinder unit 217 is configured to be movable in the vertical direction, and includes a cylinder 219 and a piston 2210. The upper surface of the cylinder 219 is open, and a hot water inlet is formed on the side surface near the lower end of the cylinder 219. The piston 2210 has water permeability and can move in the internal space of the cylinder 219.

  The cap 218 is provided above the cylinder unit 217 and is fitted into the rising cylinder 219 to close the opening. A space surrounded by the lower surface of the cap 218 blocking the cylinder 219, the inner peripheral surface of the cylinder 219, and the upper surface of the piston 2210 forms a coffee liquid extraction chamber.

  The cap 218 is formed with an extraction hole 2211 that penetrates from the lower surface to the upper surface of the cap 218. The coffee liquid obtained in the extraction chamber passes through the extraction hole 2211. The upper end of the extraction hole 2211 is connected so as to be in fluid communication with the coffee nozzle 72 via the coffee liquid pipe 2212.

  A mill 2213 is provided above the inside of the main body 2. The mill 2213 pulverizes the coffee beans stored in the canister 5 to generate ground beans.

  Next, the operation of the coffee extraction unit 21 will be described. When a specific button in the button group 4 (see FIG. 1) is operated, the mill 2213 generates ground beans. The produced ground beans are put into the above-described extraction chamber.

  Next, the cylinder unit 217 is raised by the lifting device 216, and the cap 218 is pushed into the opening of the cylinder 219. Thereby, the ground beans in the extraction chamber are compressed between the piston 2210 and the cap 218.

  Next, the hot water pump 212 is operated, the hot water supply valve 214 is opened, and a predetermined amount of hot water is pressurized and supplied from the hot water tank 211 into the cylinder 219. As a result, a high concentration coffee liquid is obtained. Here, a flow meter (not shown) is provided between the filter 213 and the hot water supply valve 214, and this flow meter measures the amount of hot water supplied to the cylinder 219. The obtained coffee liquid is sent out from the cap 218 and discharged from the coffee nozzle 72 via the coffee liquid pipe 2212. Then, it is poured into the container 10 placed on the drip tray 8 (see FIG. 1).

  Next, the configuration of the steam supply unit 22, the milk supply unit 23, and the air supply unit 24 provided inside and outside the main body 2 will be described. FIG. 3 is a diagram illustrating the configuration of the steam supply unit 22, the milk supply unit 23, and the air supply unit 24.

  As shown in FIG. 3, the steam supply unit 22 includes an electromagnetic pump 221, a milk-side hot water supply pipe 222, a boiler 223, a steam pipe 224, and a three-way valve 225. The hot water tank 211 may be shared with the coffee extraction unit 21.

  Hot water in the hot water tank 211 is supplied to the boiler 223 via the milk-side hot water supply pipe 222 by the operation of the electromagnetic pump 221. The boiler 223 is controlled so as to always have a constant temperature by a built-in electric heater (not shown), and generates steam using hot water supplied by the operation of the electromagnetic pump 221. The generated steam is supplied to the hot milk nozzle 710 via the steam pipe 224 and the three-way valve 225.

  Moreover, as shown in FIG. 3, the milk supply part 23 has the milk supply piping 231 in addition to the above-mentioned milk cold storage box 6. As shown in FIG.

  The upstream end of the milk supply pipe 231 is inserted into the milk pack 9 stored in the milk cool box 6. Further, the downstream end of the milk supply pipe 231 is connected so as to be in fluid communication with a milk inlet 746 of a gear pump 74 (see FIG. 5 or the like) described later.

  As shown in FIG. 3, the air supply unit 24 includes an air pump 241, an air supply pipe 242, and an air valve 243.

  The air pump 241 is driven by a motor (not shown), sucks external air, and sends it out to the air supply pipe 242. The downstream end of the air supply pipe 242 is connected so as to be in fluid communication with the air inlet 747 of the gear pump 74. Further, an air valve 243 composed of an electromagnetic valve or the like is provided in the middle of the air supply pipe 242. When the air valve 243 is opened, the air sent from the air pump 241 is supplied to the air inlet 747 via the air supply pipe 242.

<1-2. Nozzle unit and related configuration>
Next, the detailed configuration of the nozzle unit 7 will be described. The nozzle unit 7 is provided on the front side of the main body 2 as shown in FIG. As shown in FIG. 4, the nozzle unit 7 is fixed to the base unit 11 fixed inside the main body 2, and includes a cover 71, a coffee nozzle 72, and a milk former 73. FIG. 4 is an enlarged perspective view of the nozzle unit 7. In FIG. 4, the cover 71 is not shown.

  As shown in FIGS. 4 to 6, the milk former 73 includes a gear pump 74, a branch portion 75, a valve 76, a cold milk nozzle 77, a tempering device 78, and a milk flow path 79 in the milk former. And a hot milk nozzle 710. FIG. 5 is an exploded perspective view of the nozzle unit 7.

  The gear pump 74 is a transfer pump that transfers milk. The gear pump 74 is provided with a milk inlet 746 and an air inlet 747. Milk supplied from the milk pack 9 is introduced into the gear pump 74 via the milk inlet 746. Air supplied from the air pump 241 is introduced into the gear pump 74 through the air inlet 747. The configuration and operation of the gear pump 74 will be described in detail in the section 1-3 below.

  As shown in FIG. 6, the branch portion 75 is a cylindrical or tubular member extending in the front-rear direction. FIG. 6 is a left side view of the milk former 73 and is a view partially seeing through the inside thereof. As shown in FIG. 6, a cylindrical internal space IS <b> 1 is formed in the branch portion 75. An inlet 751 that is in fluid communication with a milk outlet (milk outlet 748 to be described later) provided in the case of the gear pump 74 is formed near the upper front of the branch portion 75. A first outlet 752 that is in fluid communication with the cold milk nozzle 77 is formed on the lower rear end side of the branch portion 75. A second outlet 753 is formed at the front end of the branch portion 75 so as to be in fluid communication with a milk flow path 79 described later. An opening 754 into which a later-described valve 76 is inserted is formed at the rear end of the branch portion 75.

  As shown in FIGS. 6 and 7, the valve 76 is inserted into the opening 754 of the internal space IS <b> 1 of the branch portion 75 and has a substantially cylindrical rotating body 761. FIG. 7 is a partial cross-sectional view of the branch portion 75 and the valve 76 as viewed from the left side. A first ring groove 762 and a second ring groove 763 are formed on the outer peripheral surface (in other words, the side surface) of the rotating body 761. The axis of the first ring groove 762 is parallel to the y axis, but the axis of the ring groove 763 is not parallel to the y axis and is oblique to the y axis in plan view from the x axis direction. As shown in FIG. 7, the first O-ring 764 and the second O-ring 765 are attached to the first ring groove 762 and the second ring groove 763 described above. 6 does not show the O-rings 764 and 765 for the sake of illustration, and FIG. 7 does not show the ring grooves 762 and 763 for the sake of illustration.

  Here, as shown in FIG. 7, the spatial distance in the y-axis direction between the O-rings 764 and 765 (hereinafter referred to as the inter-ring distance) d is a position on the circumferential surface of the valve 76 (in other words, the valve 76. Depending on the orientation from the central axis of Accordingly, when the shortest part of the distance d between the rings faces upward due to the rotation of the rotating body 761, the inlet 751 and the second outlet 753 are in fluid communication (as indicated by the dashed line arrow). As shown in the lower part of FIG. 7, when the shortest portion is directed downward, the inlet 751 and the first outlet 752 are in fluid communication (see the dashed line arrow).

  In order to rotate the valve 76, as shown in FIGS. 7, 8A and 8B, a valve side gear 766 is attached to the rear end of the valve 76 (rotating body 761). More specifically, the valve-side gear 766 is attached in a state where its own rotation axis and the central axis of the valve 76 are aligned. Here, it is preferable that the valve-side gear 766 can be inserted into and removed from the valve 76 so that the milk former 73 can be attached to and detached from the base unit 11.

  8A and 8B are views showing a state where the valve 76 and the valve side gear 766 are separated. As shown in FIGS. 8A and 8B, an insertion / extraction portion 767 formed in a T shape, for example, is provided at the rear end of the valve 76 (on the side close to the valve side gear 766). 8B, the valve side gear 766 is provided with an insertion / extraction hole 7661 for inserting the insertion / extraction portion 767. The shape of the insertion / extraction hole 7661 is the same as that of the insertion / extraction portion 767 so that the insertion / extraction portion 767 can be inserted and the valve 76 and the valve-side gear 766 can rotate together in the inserted state. They are formed together.

  8A and 8B exemplify the insertion / extraction portion 767 as a T-shape, but the present disclosure is not limited to this. The shape of the insertion / extraction portion 767 and the insertion / extraction hole 7661 may be any shape as long as the valve 76 and the valve side gear 766 can rotate integrally with the insertion / extraction portion 767 inserted into the insertion / extraction hole 7661. However, a shape that is not rotationally symmetric is desirable so that the orientation can be recognized.

  In order to rotate the valve 76, the valve motor 26 is fixed to the base unit 11 as shown in FIGS. 4 and 5. FIG. 9 is a bottom view of the nozzle unit 7 and the valve motor 26. As shown in FIG. 9, the valve motor 26 includes an output shaft 261 and a motor side gear 262. As shown in FIG. 9, the motor side gear 262 is fixed to the tip of the output shaft 261 and meshes with the valve side gear 766.

  As shown in FIG. 8A, the valve side gear 766 is provided with a fixing claw 7762 for fixing to the base unit 11. A fixing claw 7762 of the valve side gear 766 is inserted into a fixing hole (not shown) provided in the base unit 11, and the valve side gear 766 engages with the motor side gear 262 and is fixed to the base unit 11 in a rotatable state. Is done.

  As described above, the milk former 73 is fixed to the base unit 11 by inserting the insertion / extraction portion 767 of the valve 76 into the valve side gear 766 fixed to the base unit 11. Therefore, the milk former 73 can be easily detached from the base unit 11 by pulling out the insertion / extraction portion 767 of the valve 76 from the valve side gear 766. Further, the milk former 73 can be easily attached to the base unit 11 by inserting the insertion / extraction portion 767 into the insertion / extraction hole 7661 of the valve side gear 766. With such a configuration, it becomes easy to remove the milk former 73 from the base unit 11 and perform maintenance such as cleaning.

  In the above description, the milk former 73 is fixed to the base unit 11 by inserting the insertion / extraction portion 767 of the valve 76 into the insertion / extraction hole 7661 of the valve side gear 766 fixed to the base unit 11. However, the milk former 73 may be fixed to the base unit 11 not only by the valve 76 and the valve side gear 766 but also by an attachment member (not shown).

  The cold milk nozzle 77 is integrally attached to the case 741 via the branch portion 75. As shown in FIG. 6, the cold milk nozzle 77 is a cylindrical or tubular member extending in the vertical direction. The cold milk nozzle 77 is formed with a cylindrical internal space IS2. At the upper end of the cold milk nozzle 77, an inlet for fluidly communicating the first outlet 752 and the internal space IS2 is formed. Further, the lower end of the cold milk nozzle 77 opens so as to be in fluid communication with the internal space IS2, and the tempering device 78 is inserted into the internal space IS2 from this opening.

  The upstream end of the milk flow path 79 is connected to the second outlet 753 so as to be in fluid communication, and the downstream end thereof is connected to the hot milk nozzle 710 so as to be in fluid communication. As shown in FIG. 5, the hot milk nozzle 710 is connected to the downstream end of the steam pipe 224 so as to be in fluid communication.

<1-3. Detailed description of gear pump>
Hereinafter, the gear pump 74 included in the beverage production apparatus 1 of the present invention will be described in detail. The gear pump 74 is a transfer pump that transfers milk, and includes a case 741, a large-diameter gear 742, a small-diameter gear 743, and a lid 744, as shown in FIGS. 10 and 11. The large diameter gear 742 is an example of a first gear, and the small diameter gear 743 is an example of a second gear. FIG. 10 is a view of a longitudinal section of the milk former 73 taken along the line AA ′ of FIG. 4 as viewed from the back side of the beverage production apparatus 1. FIG. 11 is an exploded perspective view of the gear pump 74 and its peripheral configuration.

  The large-diameter gear 742 and the small-diameter gear 743 are accommodated in the case 741 in a state where they mesh with each other. The large-diameter gear 742 incorporates a pump-side magnet 745 (see FIG. 12 described later).

  The large diameter gear 742 is rotated by the gear pump motor 25 (see FIG. 5 and the like) fixed to the base unit 11. The gear pump motor 25 includes a mandrel 251 and a motor-side magnet 252. The motor-side magnet 252 is attached to the mandrel 251 and is coupled to the pump-side magnet 745 built in the large-diameter gear 742 to transmit the drive torque generated by the gear pump motor 25 to the pump-side magnet 745. To do. As a result, the large-diameter gear 742 in which the pump-side magnet 745 is built rotates as the gear pump motor 25 rotates. Then, the small-diameter gear 743 housed in the case 741 while being engaged with the large-diameter gear 742 rotates following the large-diameter gear 742.

  FIG. 12 is a diagram for explaining the magnet coupling between the pump-side magnet 745 and the motor-side magnet 252. 12, a cross section of the gear pump 74 and the gear pump motor 25 along the line B-B ′ in FIG. 4 is viewed from the left side of the beverage production apparatus 1. As shown in FIG. 12, the large-diameter gear 742 incorporating the pump-side magnet 745 and the motor-side magnet 252 are installed close to each other with a lid 744 interposed therebetween and are magnet-coupled. As shown in FIG. 12, the lid 744 is provided with an O-ring 7441 for preventing milk leakage.

  Here, in the beverage manufacturing apparatus 1 of the present disclosure, as illustrated in FIGS. 10 and 11, the large-diameter gear 742 and the small-diameter gear 743 do not have a mandrel on the rotation shaft. Therefore, the side surface perpendicular to the rotation axis of the large-diameter gear 742 or the small-diameter gear 743 is formed as a flat surface without a hole or a recess into which the mandrel is inserted.

<1-3-1. Description of gear pump with large diameter gear and small diameter gear having mandrel>
FIG. 13 is a diagram illustrating a configuration in which a large-diameter gear and a small-diameter gear each have a mandrel on a rotating shaft as an example of a gear pump. The gear pump 84 shown in FIG. 13 has a case 841, a large diameter gear 842, a small diameter gear 843, and a lid 844. The large diameter gear 842 has a mandrel 8421, the small diameter gear 843 has a mandrel 8431, Each is provided. Accordingly, the lid 844 is provided with depressions 8441 and 8442 for preventing the lid 844 from interfering with the mandrel 8421 and the mandrel 8431. Further, the front end portions of the mandrel 8421 and the mandrel 8431 are not shown, but are fixed to a part of the inner wall surface of the case 841, for example, so as to be rotatable. Thereby, the large-diameter gear 842 and the small-diameter gear 843 can be suitably rotated within the case 841.

  As described above, the gear pump 84 in which the large-diameter gear 842 and the small-diameter gear 843 have the mandrels 8421 and 8431 has the following points that require improvement.

  The first point that needs improvement is as follows. A beverage such as milk is introduced into the gear pump 84 and transported out of the gear pump 84 by the rotation of the large diameter gear 842 and the small diameter gear 843. In order to handle beverages and the like, the gear pump 84 is required to be hygienic. In order to keep the sanitary condition in the gear pump 84 in good condition, it is desirable that the gear pump 84 is configured to be easily disassembled and disassembled and cleaned every time it is used.

  However, when the large-diameter gear 842 and the small-diameter gear 843 have the mandrel 8421 and the mandrel 8431 as shown in FIG. 13, for example, the mandrel 8421 and the mandrel 8431 connected to the inner wall surface of the case 841 are removed at the time of disassembly, Since operations such as connecting the 8421 and the mandrel 8431 to the inner wall surface of the case 841 are required, disassembly and assembly may not be performed smoothly. For this reason, there is a demand for a gear pump that can be smoothly disassembled and assembled.

  The second point that needs improvement is as follows. For example, when the gear pump 84 is operated, a beverage such as milk is collected or stuck around the mandrel 8421 and the mandrel 8431 or the recesses 8441 and 8442 provided in the lid 844, so that the transport efficiency of the beverage by the gear pump 84 is reduced. And hygienic effects may occur. For this reason, there is a demand for a gear pump that minimizes the number of places where beverages accumulate or stick.

<1-3-2. Description of Gear Pump According to Embodiment of Present Disclosure in Which Large Diameter Gear and Small Diameter Gear Do Not Have Mandrel>
In order to improve such a point, in the gear pump 74 of the present disclosure, the large-diameter gear 742 and the small-diameter gear 743 do not have a mandrel on the rotation shaft, as shown in FIGS. Hereinafter, details of the gear pump 74 of the present disclosure and how the gear pump 74 of the present disclosure is improved in the above points will be described.

  FIG. 14 is a diagram showing the dimensions of the large-diameter gear 742 and the small-diameter gear 743 and the dimensions of the internal space of the case. FIG. 14 shows a cross section when the gear pump 74 is viewed from the front of the beverage production apparatus 1. In the present embodiment, as shown in FIG. 14, the diameters of the addendum circles of the large diameter gear 742 and the small diameter gear 743 are OD1 and OD2, and the root diameters of both gears 742 and 743 are RD1 and RD2. Further, the tooth widths (y-axis direction widths) of both the gears 742 and 743 are substantially the same, and are W (not shown). Further, the distance between the center of the large-diameter gear 742 and the center of the small-diameter gear 743 is C (not shown).

  The case 741 is made of a nonmagnetic material such as a resin. The case 741 forms an internal space IS3 that accommodates the large-diameter gear 742 and the small-diameter gear 743. As shown in FIG. 14, the internal space IS3 is defined by a large-diameter side arc surface S1, a small-diameter side arc surface S2, a bottom surface S3, an upper surface S4, and a front surface S5.

  The arcuate surfaces S1 and S2 are arcuate surfaces including sides forming an arc having radii of approximately OD1 / 2 and OD2 / 2 when viewed from the front in the y-axis direction.

  The bottom surface S3 is a surface including two lower tangent lines (two line segments perpendicular to the paper surface in FIG. 14) in contact with the addendum circles of the circular arc surfaces S1 and S2 in the front view of the beverage production apparatus 1. On the other hand, the upper surface S4 is a surface including two upper tangent lines (two line segments perpendicular to the paper surface in FIG. 14). The front surface S5 is a surface that closes the internal space IS3 surrounded by the surfaces S1 to S4 on the front surface side (front side in FIG. 14) of the beverage production apparatus 1.

  In the case 741, the maximum length L of the straight line connecting the opposing inner surfaces of the case 741 is such that the radius OD1 / 2 of the tip circle of the large diameter gear 742 and the radius OD2 / 2 of the tip circle of the small diameter gear 743 are large. Designed to be a value obtained by adding a predetermined clearance to the sum of the distance C between the center of the large diameter gear 742 and the center of the small diameter gear 743 when the diameter gear 742 and the small diameter gear 743 are engaged with each other. The

  With such a configuration, the large-diameter gear 742 and the small-diameter gear 743 mesh with each other with the outer periphery (a part of the tooth tip) of the large-diameter gear 742 and the small-diameter gear 743 having a clearance from the inner surface of the case 741. Be contained. For this reason, the large-diameter gear 742 is held by the circular arc surface S1 and the small-diameter gear 743 in a meshed state in a plane perpendicular to the rotation axis of the large-diameter gear 742. Similarly, the small-diameter gear 743 is held by the circular arc surface S2 and the large-diameter gear 742 in a meshed state in a plane perpendicular to the rotation shaft of the large-diameter gear 742 or the small-diameter gear 743. By closing the lid 744 in this state, the large-diameter gear 742 and the small-diameter gear 743 are supported so as not to move further in the rotation axis direction (the front-rear direction of the gear pump 74).

  When the gear pump motor 25 rotates and the driving torque generated by the gear pump motor 25 is transmitted to the pump side magnet 745 in the large diameter gear 742 that is magnet-coupled to the motor side magnet 252, the large diameter gear is transmitted. 742 rotates, and accordingly, the small diameter gear 743 also rotates following the large diameter gear 742.

  The case 741 has a milk inlet 746, an air inlet 747, and a milk outlet 748, as shown in FIGS. The milk inlet 746 is a cylindrical or tubular member capable of fluid communication with the internal space IS4 of the gear pump 74 through a through hole formed in the upper surface S4 of the case 741. The internal space IS4 is a space (shaded portion in FIG. 14) surrounded by the upper surface S4, the large diameter gear 742, and the small diameter gear 743 in the internal space IS3 of the gear pump 74. The downstream end of the milk supply pipe 231 is connected to the milk inlet 746 so that fluid communication is possible.

  The air inlet 747 is a cylindrical or tubular member capable of fluid communication with the internal space IS4 of the gear pump 74 through a through-hole formed in the case 741. The air inlet 747 is connected to the downstream end of the air supply pipe 242 so as to be in fluid communication. The milk inlet 746 and the air inlet 747 are preferably formed at the center of the upper surface S4 or in the vicinity thereof.

  The milk outlet 748 is a through hole formed in the bottom surface S <b> 3 of the case 741. The milk outlet 748 can be in fluid communication with the branch 75. The milk outlet 748 is preferably formed at the center of the bottom surface S3 or in the vicinity thereof.

  The above case 741 is fixed to the front side of the base unit 11 so that the bottom surface S3 of the internal space IS3 is parallel to the xy plane. The lid 744 closes the opening of the case 741 in which both gears 742 and 743 are accommodated. An O ring (not shown) is attached to the lid 744, and the gap between the lid 744 and the case 741 is sealed by this O ring.

  During the rotation of the gear pump 74, the milk in the internal space IS4 passes through the outside (the non-meshing side) of the large diameter gear 742 and the small diameter gear 743 by the rotating large diameter gear 742 and small diameter gear 743, and the milk outlet 748. It is transferred to the vicinity. Thereby, the milk that has flowed into the case 741 from the milk inlet 746 can be discharged from the milk outlet 748. The outer side of the large diameter gear 742 and the small diameter gear 743 means the side close to the inner surface of the case 741 in the outer peripheral portions of the large diameter gear 742 and the small diameter gear 743.

  In addition, when milk flows into the internal space IS4 of the gear pump 74 from the milk inlet 746 and air flows into the internal space IS4 from the air inlet 747, the rotation of the gear pump 74 causes the milk and air to be agitated to form. Milk is produced.

  As described above, in the gear pump 74 included in the beverage production apparatus 1 according to the embodiment of the present disclosure, the large-diameter gear 742 and the small-diameter gear 743 are accommodated in the case 741 in a state where they mesh with each other. A motor-side magnet 252 rotated by the gear pump motor 25 and a magnet-coupled pump-side magnet 745 are incorporated, and the small-diameter gear 743 rotates following the rotation of the large-diameter gear 742, and the large-diameter gear 742 and the small-diameter gear 743 are , Does not have a mandrel on the rotating shaft

  And in the gear pump 74 which the drink manufacturing apparatus 1 which concerns on embodiment of this indication has, the maximum length L of the straight line which connects the inner surface which the case 741 opposes is radius OD1 / 2 of the tooth circle of the large diameter gear 742, and The radius OD2 / 2 of the tip circle of the small diameter gear 743 and the distance C between the center of the large diameter gear 742 and the center of the small diameter gear 743 when the large diameter gear 742 and the small diameter gear 743 are engaged with each other. A value obtained by adding a predetermined clearance to the sum.

  With such a configuration, the large-diameter gear 742 and the small-diameter gear 743 do not move in a plane perpendicular to the rotation axes of the large-diameter gear 742 and the small-diameter gear 743 and are rotatably accommodated in the case 741. .

  In the gear pump 74 included in the beverage production apparatus 1 according to the embodiment of the present disclosure, the large-diameter gear 742 and the small-diameter gear 743 each have no mandrel as described above. The side surfaces perpendicular to the rotation shafts of the diameter gear 742 and the small diameter gear 743 can be flattened, and a situation in which milk or the like is accumulated or stuck on the surfaces of the large diameter gear 742 and the small diameter gear 743 can be prevented. Similarly, the inner surface of the lid 744 does not need to be provided with a depression or the like for receiving the mandrel of the large diameter gear 742 and the small diameter gear 743 and avoiding interference with the mandrel, and faces the large diameter gear 742 and the small diameter gear 743. The surface of the lid 744 to be formed can be formed flat, and it is possible to prevent a situation where milk or the like is accumulated or stuck to a part of the lid 744.

  The pump-side magnet 745 in the large-diameter gear 742 and the motor-side magnet 252 attached to the mandrel 251 of the gear pump motor 25 are magnet-coupled, and the drive torque of the gear pump motor 25 is applied to the pump-side magnet 745. By being transmitted, the large-diameter gear 742 rotates. Along with this, the small diameter gear 743 also rotates following the large diameter gear 742. Thus, since the motor side magnet 252 and the pump side magnet 745 are magnet-coupled, it is not necessary to strictly match the output shaft and the shaft of the large-diameter gear 742, and transmission of drive torque to the large-diameter gear 742 is not required. This can be done without using a mandrel.

  Further, in the gear pump 74 included in the beverage production apparatus 1 according to the embodiment of the present disclosure, as described above, the large diameter gear 742 (small diameter gear 743) includes the inner surface of the case 741, the small diameter gear 743 (large diameter gear 742), and Supported by a lid 744. Therefore, when the lid 744 is removed from the case 741, the large diameter gear 742 and the small diameter gear 743 can be easily taken out from the case 741. For this reason, the gear pump 74 can be easily disassembled and cleaned. Moreover, the assembly of the gear pump 74 after disassembly and cleaning is easy.

  As described above, in the gear pump 74 included in the beverage manufacturing apparatus 1 according to the embodiment of the present disclosure, the large-diameter gear 742 and the small-diameter gear 743 do not move in the rotation axis direction (the front-rear direction of the gear pump 74). In addition, the front surface S5 of the case 741 and the lid 744 are brought into contact with each other. In such a state, when the large-diameter gear 742 and the small-diameter gear 743 rotate, there may occur a situation where the rotation cannot be smoothly performed due to friction with the front surface S5 of the case 741 or the lid 744. This is because the frictional force between the large-diameter gear 742 and the lid 744 is increased particularly by the magnet coupling.

  In order to prevent such a situation, a recess D as shown in FIG. 12 is provided on the side surface perpendicular to the rotation axis of the large-diameter gear 742. The recess D has a contact area with the lid 744 at, for example, a position away from the peripheral edge 7421 of the trapezoidal gear 742 on the side surface (side surface perpendicular to the rotation axis direction) facing the lid 744 of the large-diameter gear 742. Provided to be smaller. The depth of the recess D is not particularly limited in the present disclosure, but may be a depth that does not allow the side surface of the large-diameter gear 742 and the lid 744 to contact each other. The predetermined distance is a distance at which the peripheral edge portion 7421 can sufficiently prevent milk leakage. The peripheral edge portion 7421 may be provided with a relief hole (not shown) when milk flows into the recess.

  Further, a recess may be provided on the lid 744 side instead of the side surface of the large diameter gear 742 (not shown). Furthermore, a dent may be provided on both the side surface of the large-diameter gear 742 and the lid 744. In this case, as in the case of being provided on the side surface of the large-diameter gear 742, the dent is not provided at a position facing the peripheral edge portion 7421 of the lid 744, but at a position facing a region that is more than a predetermined distance from the peripheral edge portion 7421. It is desirable to be provided.

  Further, the dent may be provided not only on the side surface in contact with the lid 744 of the large-diameter gear 742 but also on the side surface on the front surface S5 side of the case 741, which is the opposite side surface (not shown). Further, a recess may be provided on the front surface S5 side of the case 741. Furthermore, a dent may be provided on both the side surface of the case 741 on the front surface S5 side of the large diameter gear 742 and the front surface S5 of the case 741. In this case, as in the case of being provided on the side surface in contact with the lid 744, the front surface S5 of the case 741 is not provided at a position facing the peripheral edge portion 7421, but is opposed to a region more than a predetermined distance from the peripheral edge portion 7421. It is desirable to be provided at a position. Further, the escape hole may be provided in the peripheral edge portion 7421 on the side surface of the large-diameter gear 742 or may be provided in the peripheral edge portion of the lid 744 in contact with the peripheral edge portion 7421. Moreover, you may provide in both.

  With such a configuration, when the large-diameter gear 742 rotates, it is possible to prevent the large-diameter gear 742 from rotating smoothly due to friction between the side surface of the large-diameter gear 742 and the front surface S5 and / or the lid 744 of the case 741. it can.

  Although a recess may be provided also on the small diameter gear 743 side, since the small diameter gear 743 side is not magnet-coupled, the recess on the small diameter gear 743 side may not be provided.

<1-4. Milk Former Operation (when creating Steam Milk)>
Next, an operation example of the milk former 73 having the above configuration will be described. When it is determined that a specific button in the button group 4 is operated and the operated button is a beverage using steam milk, a microcomputer (not shown) provided inside the main body 2 has the above-described configuration. Control each part.

  The microcomputer drives the valve motor 26. As a result, the output shaft 261 shown in FIG. 9 rotates. The force generated in the output shaft 261 is transmitted to the valve 76 via the front motor side gear 262 and the valve side gear 766. When generating steam milk, the microcomputer controls the valve motor 26 to rotate and stop the valve 76 so that the shortest part of the distance d between the rings faces upward as shown in the upper part of FIG. As a result, a flow path (see an arrow of an alternate long and short dash line in FIG. 7) from the inlet 751 to the second outlet 753 is formed in the internal space IS1 of the branch portion 75.

  The microcomputer further operates the electromagnetic pump 221 to energize the three-way valve 225. Thereby, the hot water in the hot water tank 211 starts to flow into the boiler 223 via the milk side hot water supply pipe 222. The flowing hot water becomes steam by the boiler 223 and is supplied to the hot milk nozzle 710 through the steam pipe 224.

  The microcomputer further drives the gear pump motor 25. As a result, the rotational force generated in the mandrel 251 is transmitted to the large-diameter gear 742 by a magnet coupling between the motor-side magnet 252 and the pump-side magnet 745. As a result, the large diameter gear 742 begins to rotate, and the small diameter gear 743 rotates following the large diameter gear 742. At this time, both gears 742 and 743 rotate in the directions of arrows a and b shown in FIG. With this rotation, the gear pump 74 starts to suck the milk in the milk pack 9 through the milk supply pipe 231. The milk sucked into the gear pump 74 is discharged from the milk outlet 748 by rotating both the gears 742 and 743 around these outer sides.

  In addition, when producing steam milk, the air pump 241 is stopped and the air valve 243 is closed. That is, the gear pump 74 is not supplied with air from the air supply unit 24.

  The milk discharged from the milk outlet 748 is supplied to the inlet 751 of the branch portion 75. The milk that has flowed into the internal space IS1 from the inlet 751 is discharged from the second outlet 753 through the internal space IS1, and then flows into the hot milk nozzle 710 through the milk flow path 79. As described above, steam is supplied from the steam pipe 224 to the hot milk nozzle 710. Inside the hot milk nozzle 710, the milk is heated with steam, thereby producing steam milk. The generated steam milk is discharged from the hot milk nozzle 710 toward the container 10.

<1-5. Milk Former Operation (when creating cold milk)>
When a specific button in the button group 4 is operated and the operated button is a beverage using cold milk, the microcomputer controls each part of the above configuration as follows.

  First, the microcomputer controls the valve motor 26 to rotate and stop the valve 76 so that the shortest part of the inter-ring distance d faces downward as shown in the lower part of FIG. As a result, a flow path from the inlet 751 to the first outlet 752 (see the arrow of the alternate long and short dash line in FIG. 7) is formed in the internal space IS1 of the branching portion 75.

  The microcomputer further drives the gear pump motor 25. As a result, the gear pump 74 starts to suck the milk in the milk pack 9 as described in the section 1-4. Cold milk in the gear pump 74 is discharged from the milk outlet 748 by the rotation of both gears 742 and 743.

  During the cold milk production, the gear pump 74 does not receive air supply from the air supply unit 24.

  Milk from the milk outlet 748 is supplied to the inlet 751 of the branch 75. The milk flowing into the internal space IS1 from the inlet 751 is discharged from the first outlet 752 through the internal space IS1 and flows into the internal space IS2 from the upper end of the cold milk nozzle 77. The milk that has flowed in is discharged toward the container 10 from the lower end of the cold milk nozzle 77 while maintaining the cold state.

<1-6. Milk foamer operation (when creating cold foamed milk)>
When a specific button in the button group 4 is operated and the operated button is a beverage using cold foamed milk, the microcomputer controls each part of the above configuration as follows.

  First, the microcomputer controls the valve motor 26 to rotate and stop the valve 76 so that the shortest part of the inter-ring distance d faces downward as shown in the lower part of FIG. As a result, a flow path from the inlet 751 to the first outlet 752 (see the arrow of the alternate long and short dash line in FIG. 7) is formed in the internal space IS1 of the branching portion 75.

  Next, the microcomputer opens the air valve 243 and drives the air pump 241 when producing cold foamed milk. As a result, external air is taken into the air pump 241 and supplied to the internal space IS3 of the gear pump 74 through the air supply pipe 242 and the air inlet 747 of the gear pump 74.

  The microcomputer further drives the gear pump motor 25. Thereby, the gear pump 74 starts sucking the milk in the milk pack 9 in the same manner as described in the section 1-4.

  Milk and air in the gear pump 74 are mixed by the rotation of both gears 742, 743, thereby producing cold, foamed milk. The produced cold foamed milk goes outside the rotating gears 742 and 743 and is discharged from the milk outlet 748.

  The cold foamed milk discharged from the milk outlet 748 is supplied to the inlet 751 of the branch portion 75, and then discharged from the first outlet 752 through the internal space IS 1, from the upper end of the cold milk nozzle 77. It flows into the internal space IS2. As described above, the tempering device 78 is provided in the internal space IS2. The conditioner 78 homogenizes the foamed milk foam that has flowed in, and is discharged toward the container 10 from the lower end of the cold milk nozzle 77.

<1-7. Milk Former Operation (when creating hot foamed milk)>
When a specific button in the button group 4 is operated and the operated button is a beverage using hot foamed milk, the microcomputer controls each part of the above configuration as follows.

  First, the microcomputer controls the valve motor 26 to rotate and stop the valve 76 so that the shortest portion of the inter-ring distance d faces upward as shown in the upper part of FIG. As a result, a flow path (see an arrow of an alternate long and short dash line in FIG. 7) from the inlet 751 to the second outlet 753 is formed in the internal space IS1 of the branch portion 75.

  Further, as described in the column 1-4, when the microcomputer operates the electromagnetic pump 221 and energizes the three-way valve 225, the steam is supplied to the hot milk nozzle 710 via the steam pipe 224.

  Further, as described in the column 1-6, when the microcomputer drives the gear pump motor 25, the gear pump 74 generates cold foamed milk and discharges it from the milk outlet 748.

  The cold foamed milk discharged from the milk outlet 748 flows into the inlet 751 of the branch 75 and is discharged from the second outlet 753, and then to the hot milk nozzle 710 via the milk flow path 79. Inflow. As described above, steam is supplied from the steam pipe 224 to the hot milk nozzle 710. Inside the hot milk nozzle 710, the foamed milk is heated with steam, thereby producing hot foamed milk. The generated hot foamed milk is discharged from the hot milk nozzle 710 toward the container 10.

<1-8. Action / Effect>
As described above, in the gear pump 74 of the beverage manufacturing apparatus 1 according to the embodiment of the present disclosure, the large-diameter gear 742 and the small-diameter gear 743 are accommodated in the case 741 in a state where they mesh with each other. The motor-side magnet 252 rotated by the motor 25 and the magnet-coupled pump-side magnet 745 are incorporated. The small-diameter gear 743 is rotated by the rotation of the large-diameter gear 742, and the large-diameter gear 742 and the small-diameter gear 743 are At least one of the two side surfaces of the large-diameter gear 742 that does not have a mandrel on the rotation shaft and is perpendicular to the rotation shaft of the large-diameter gear 742 or the two inner surfaces of the case 741 that contacts the two side surfaces A recess is provided on the surface of the.

  With such a configuration, when the large-diameter gear 742 and the small-diameter gear 743 rotate, it is possible to prevent a situation where the casing 741 cannot rotate smoothly due to friction with the front surface S5 of the case 741 or the lid 744. In the above-described embodiment, the case 741 and the lid 744 are described as different configurations. However, the lid 744 accommodates the large-diameter gear 742 and the small-diameter gear 743 together with the case 741, and is included in the case 741. It is good.

  While various embodiments have been described with reference to the drawings, the present disclosure is not limited to such examples. It will be apparent to those skilled in the art that various changes and modifications can be made within the scope of the claims, and these are naturally within the scope of the disclosure. Understood. In addition, the constituent elements in the above embodiments may be arbitrarily combined without departing from the spirit of the disclosure.

  The present disclosure is useful for a beverage production apparatus having a milk former.

DESCRIPTION OF SYMBOLS 1 Beverage production apparatus 2 Main body 3 Door 4 Button group 5 Canister 6 Milk cold storage 7 Nozzle unit 8 Drip tray 9 Milk pack 10 Container 11 Base unit 21 Coffee extraction part 211 Hot water tank 212 Hot water pump 213 Filter 214 Hot water supply valve 215 Coffee side hot water supply Piping 216 Lifting device 217 Cylinder unit 218 Cap 219 Cylinder 2210 Piston 2211 Extraction hole 2212 Coffee liquid piping 2213 Mill 22 Steam supply unit 221 Electromagnetic pump 222 Milk side hot water supply piping 223 Boiler 224 Steam piping 225 Three-way valve 23 Milk supply unit 231 Milk supply Piping 24 Air supply section 241 Air pump 242 Air supply piping 243 Air valve 25 Gear pump motor 251 Mandrel 252 Motor side magnet 26 Valve motor 261 Output shaft 262 Motor side gear 71 Cover 72 Coffee nozzle 73 Milk former 74 Gear pump 741 Case 742 Large diameter gear 7421 Perimeter 743 Small diameter gear 744 Lid 7441 O-ring 745 Pump side magnet 746 Milk inlet 747 Air inlet 748 Milk Outlet 75 Branch 751 Inlet 752 First outlet 753 Second outlet 754 Open 76 Valve 761 Rotating body 762 First ring groove 763 Second ring groove 764 First O-ring 765 Second O-ring 766 Valve side gear 7661 Insertion / extraction hole 7762 Fixing claw 767 Insertion / extraction section 77 Cold milk nozzle 78 Conditioner 79 Milk flow path 710 Hot milk nozzle 84 Gear pump 841 Case 842 Large diameter gear 8421 Mandrel 843 Small diameter gear 8431 Mandrel 84 4 Lid 8441, 8442 Dimple

Claims (4)

A beverage production apparatus including a gear pump having a first gear and a second gear, and a case accommodated inside the first gear and the second gear engaged with each other,
The first gear includes a motor-side magnet that is rotated by a motor that generates a driving torque for rotating the first gear, and a pump-side magnet that is magnet-coupled.
The second gear rotates following the rotation of the first gear;
The first gear and the second gear do not have a mandrel that is the center of the rotation,
A recess is provided on at least one of the two side surfaces of the first gear perpendicular to the rotation axis of the first gear or the two inner surfaces of the case that are in contact with the two side surfaces.
Beverage production equipment. When the recess is provided on the side surface, the recess is provided at a position away from the peripheral edge of the first gear on the side surface by a predetermined distance or more.
The beverage production apparatus according to claim 1. When the recess is provided on the inner surface, the recess is not provided at a position facing the peripheral edge of the first gear on the inner surface, but at a position facing an inner region of a predetermined distance or more from the peripheral edge of the first gear. Provided,
The beverage production apparatus according to claim 1 or 2. A clearance hole is provided in at least one peripheral edge of the first gear and the case,
The beverage production apparatus according to any one of claims 1 to 3.

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