JP2020132223A - Beverage dispenser - Google Patents

Abstract

To provide a beverage dispenser making it easy to satisfactorily mix a beverage from a tank and a beverage from a BIB unit.SOLUTION: A beverage dispenser 1 includes: a body 2; a nozzle 42 supported by the body 2, extending in a vertical direction and discharging a first beverage from below; a tube 53 which is connected to a beverage storage part 52A storing a second beverage to be mixed with the first beverage, and through which the second beverage flows; a tube pump 54 feeding the beverage in the tube 53; and a holding member 84 disposed on a downstream side in a supplying direction of the second beverage with respect to the tube pump 54, compressing and holding the tip end part 53B of the tube 53 from the diameter direction of the tube 53, and increasing the flow rate of the second beverage flowing in the tube 53.SELECTED DRAWING: Figure 4

Description

The present invention relates to a beverage dispenser that uses BIB.

Conventionally, in this type of beverage dispenser, BIB units using BIB (Bag In Box) are provided on both sides of the tank unit, and a centralized nozzle in which two nozzles of the BIB unit and a nozzle of the tank unit are integrated is provided. The configuration is known (see, for example, Patent Document 1).

Japanese Unexamined Patent Publication No. 09-267897

However, when the nozzles of the BIB unit are concentrated on the nozzles of the tank unit from the side of the nozzles of the tank unit, and the beverage discharged from the BIB unit has a high viscosity, the highly viscous beverage drips. It may fall directly under the nozzle without hitting the beverage in the tank unit. Even if the highly viscous beverage that drips drops into the cup, it does not mix well with the beverage from the tank unit, and it may accumulate in the cup as a lump, resulting in a shade of taste.

The present invention solves the above-mentioned conventional problems, and an object of the present invention is to provide a beverage dispenser that can easily sufficiently mix a beverage from a tank and a beverage from a BIB unit.

In order to achieve the above object, the beverage dispenser of the present invention has a nozzle extending in the vertical direction to discharge the first beverage from below, and a beverage storage unit for accommodating the second beverage mixed with the first beverage. A tube for flowing the second beverage and a tube pump for delivering the beverage in the tube, which are arranged downstream of the tube pump in the supply direction of the second beverage. The tip of the tube is compressed and held from the radial direction of the tube, and the holding portion is provided to increase the flow velocity of the second beverage flowing in the tube.

According to this, the inside of the tip portion of the tube can be narrowed to increase the flow velocity of the second beverage.

The beverage dispenser of the present invention can narrow the inside of the tip of the tube to increase the flow velocity of the second beverage. Therefore, it is possible to suppress the dripping of the second beverage discharged from the tip portion and easily hit the first beverage, and it is possible to sufficiently mix the beverage from the tank and the beverage from the BIB unit.

Perspective view of the beverage dispenser according to the embodiment of the present invention Front view of beverage dispenser with open door Right side view of the beverage dispenser with the right panel removed Enlarged view of the main part of FIG. FIG. 5 is a perspective view of the tube pump and the pinch mechanism. VI-VI line sectional view of FIG. Perspective view of the main part of the pinch mechanism seen from below Front view showing the holding member in the neutral position Front view showing the holding member in the upward position Front view showing the holding member in the downward position Perspective view showing the state where the pump unit is removed Perspective view showing the state where the pinch unit is removed

According to the first invention, in a beverage dispenser, a main body, a nozzle supported by the main body and extending in the vertical direction to discharge the first beverage from below, and a second beverage mixed with the first beverage are provided. A tube connected to a beverage accommodating portion for accommodating and flowing the second beverage and a tube pump for delivering the beverage in the tube are provided, and the second beverage is supplied downstream to the tube pump. It is provided with a holding portion that is arranged and compresses and holds the tip of the tube from the radial direction of the tube to increase the flow velocity of the second beverage flowing through the tube.
According to this, the inside of the tip portion of the tube can be narrowed to increase the flow velocity of the second beverage. Therefore, it is possible to suppress the dripping of the second beverage discharged from the tip portion and easily hit the first beverage, and it is possible to sufficiently mix the beverage from the tank and the beverage from the BIB unit.

In the second invention, the holding portion includes a base portion and a pair of holding portions supported by the base portion, and the tube is press-fitted into the pair of holding portions.
According to this, the tip end portion of the tube can be compressed with a simple structure.

In the third aspect of the invention, the pair of sandwiching portions are arranged on a side in which the base portion is supported by the main body and the tip thereof is separated from the main body.
According to this, the open tip side of the holding portion can be visually recognized, and the work of holding the tube between the holding portions becomes easy.

In the fourth invention, the sandwiching portion includes a contact portion that abuts in the radial direction of the tube, the abutting portion is formed in a straight line, and a pair of the abutting portions are arranged in parallel. ..
According to this, the width of the cross section of the flow path of the tube can be made constant, and the flow of the beverage can be easily stabilized.

Hereinafter, embodiments of the present invention will be described with reference to the drawings. The present invention is not limited to the present embodiment.
FIG. 1 is an external perspective view of the beverage dispenser 1 according to the embodiment of the present invention.
The beverage dispenser 1 includes an external box-shaped main body 2. A door 3 is provided at the front portion of the main body 2. The door 3 is supported so as to be openable and closable around a hinge shaft (not shown) on the front left side of the main body 2. On the front surface of the door 3, a display unit 3A for displaying a drink that can be supplied and a selection button 3B for selecting a drink are provided. A cup 4 for supplying a beverage is set below the front portion of the main body 2, and a cup set portion 5 is provided. A drip tray 6 is supported below the cup set portion 5.

FIG. 2 is a front view of the beverage dispenser 1 with the door 3 opened. FIG. 3 is a right side view of the beverage dispenser 1 from which the right panel 2A is removed.
The main body 2 includes a cooling unit 11 (see FIG. 3), a tank unit 12 arranged in the center of the main body 2 in the left-right direction (width direction), and a pair of left and right BIBs arranged on the left and right sides of the tank unit 12 in a front view. It has units 13 and 13.

As shown in FIG. 3, the cooling unit 11 includes a compressor 21, a condenser 22, a capillary tube (not shown), and an evaporator (not shown) that constitute a refrigeration cycle. Further, the cooling unit 11 includes a fan 23 arranged behind the condenser 22, a refrigerant pipe (not shown) for circulating the refrigerant, and the like. The upper water tank 34 and the cold storage 51 can be cooled by evaporating the refrigerant in the evaporator (not shown) of the cooling unit 11.

The tank unit 12 includes a water supply system 31, a syrup supply system 32, and a nozzle unit 33 (see FIG. 2) to which the water supply system 31 and the syrup supply system 32 are connected.
The water supply system 31 has a water tank 34. The water tank 34 is arranged above the rear part of the main body 2. Tap water is supplied to the water tank 34 through a pipe (not shown). A pipe 35 extending forward and downward is connected to the water tank 34. The pipe 35 is connected to the pressurizing tank 36. A tube (not shown) extending from the pressurizing tank 36 is connected to the nozzle unit 33 via a solenoid valve 38. The water pressurized by the opening / closing control of the solenoid valve 38 can be supplied to the nozzle unit 33.

The syrup supply system 32 has a pipe 39 extending from a syrup tank (not shown) containing the syrup. The tube 39 is connected to the nozzle unit 33 via a solenoid valve 40. The syrup can be supplied to the nozzle unit 33 by controlling the opening and closing of the solenoid valve 40. The beverage dispenser 1 is provided with a plurality of syrup tanks (not shown) and syrup supply systems 32 so that different types of syrup can be supplied to the nozzle unit 33.

As shown in FIG. 2, the nozzle unit 33 is supported at the center of the front surface of the main body 2. The nozzle unit 33 is a composite nozzle that discharges different types of syrup beverages supplied from a plurality of syrup tanks according to the user's choice. The nozzle unit 33 has an appearance box-shaped mixer portion 41 and a shaft-shaped nozzle 42 extending downward from the lower portion of the mixer portion 41. A discharge port 42A is formed at the lower end of the nozzle 42. Each tube (not shown) extending from the solenoid valves 38 and 40 (see FIG. 3) is connected to the mixer portion 41. In the mixer unit 41, the supplied syrup and water are mixed to generate a syrup beverage, and the produced syrup beverage is discharged downward through the discharge port 42A of the nozzle 42. When only water is supplied to the mixer unit 41, only water is discharged from the discharge port 42A through the nozzle 42. The beverage discharged from the discharge port 42A is discharged downward along the axis L0 of the nozzle 42. In this embodiment, the water corresponds to the first beverage.

BIB units 13 and 13 are arranged on the left and right sides of the nozzle unit 33. The left and right BIB units 13 and 13 have different shapes and the like depending on the arrangement position, but the basic configuration is the same.
The BIB unit 13 includes a cold storage 51 in front of the upper part of the main body 2. The cold storage 51 is configured to be coolable by the cooling unit 11. A BIB (Bag In Box) 52 is replaceably mounted on the cold storage 51. BIB 52 contains concentrated beverages such as oolong tea and juice. The concentrated beverage of BIB52 is provided after being mixed with water and diluted. In this embodiment, the concentrated beverage corresponds to the second beverage.

BIB 52 is made of a flexible material. The BIB 52 has a box-shaped beverage accommodating portion 52A for accommodating the concentrated beverage, and a tube 53 connected to the beverage accommodating portion 52A to lead out and flow the concentrated beverage. At the time of distribution, BIB 52 is distributed in a state in which the tip of the tube 53 is sealed and sealed. Then, when the BIB 52 is set in the beverage dispenser 1, the sealing portion of the tube 53 is removed and the discharge port 53A is formed at the tip of the tube 53.

The tube 53 of the BIB 52 extends downward from the front of the cold storage 51, is introduced into the tube pump 54, and is attached to the tube pump 54. Further, in the tube 53, the tip portion 53B led out from the tube pump 54 is held by the pinch mechanism 55. The pinch mechanism 55 is arranged on the lower side of the rotor 63 and on the nozzle 42 side with respect to the rotation shaft 62 of the rotor 63. The pinch mechanism 55 supports the tube 53 in a state of being tilted downward as it approaches the nozzle 42. The pinch mechanism 55 holds the discharge port 53A of the tube 53 toward the lower side of the discharge port 42A of the nozzle 42.

FIG. 4 is an enlarged view of a main part of FIG. FIG. 5 is a perspective view of the tube pump 54 and the pinch mechanism 55.
The tube pump 54 includes a base portion 61. The base portion 61 is fixed to the panel 2B on the front surface of the main body 2 with a fixture 54A. A rotor 63 is supported on the base portion 61. The rotor 63 is rotatably supported by a rotating shaft 62 extending in the front-rear direction. A driving force is transmitted to the rotating shaft 62 from a DC motor (not shown) supported behind the base portion 61.

The rotor 63 includes a pair of front and rear disc-shaped main body portions 63A, and a columnar roller 63B rotatably supported between the front and rear main body portions 63A. A plurality of rollers 63B are arranged at equal intervals along the outer peripheral portion 63C of the main body portion 63A. The roller 63B forms an uneven shape on the outer peripheral portion 63C of the rotor 63 by pressing the tube 53 to deliver the concentrated beverage.

The rotor 63 on the right side is configured to transmit a clockwise driving force in front view. Further, the rotor 63 on the left side is configured to transmit a counterclockwise driving force when viewed from the front.

An arm-shaped guide 64 that presses the tube 53 against the rotor 63 is supported on the outer side in the left-right direction with respect to the rotor 63. The guide 64 has an inner peripheral portion 64A that curves along the outer peripheral portion 63C of the rotor 63. The tube 53 is mounted in a state of being sandwiched and pressed between the outer peripheral portion 63C of the rotor 63 and the inner peripheral portion 64A of the guide 64. The tube 53 is held by the roller 63B along the outer peripheral portion 63C in a state where the tube 53 is inserted between the main bodies 63A and 63A in the portion without the roller 63B with respect to the rotor 63.

In the present embodiment in which the tip end portion 53B of the tube 53 is arranged so as to extend from the outside in the left-right direction toward the lower side of the nozzle 42, the tube 53 extends along a virtual straight line L1 extending from the outer peripheral portion 63C of the rotor 63. Since the guide 64 is arranged on the lateral side of the rotor 63 in the left-right direction, the bending of the tube 53 can be suppressed and the flow of the beverage in the tube 53 can be prevented from being blocked.

The guide 64 includes a downstream end portion 64B on the downstream side and an upstream end portion 64C on the upstream side with respect to the rotation direction of the rotor 63.
A rotation pin (rotation shaft) 65 extending in the front-rear direction is supported on the downstream end portion 64B. In this embodiment, the rotation pin 65 is arranged below the rotation shaft 62.
The guide 64 is rotatably supported around the rotation pin 65. The guide 64 (see the solid line in FIG. 4) can be rotated to a closed position for pressing the tube 53 between the rotor 63 and the outer peripheral portion 63C. Further, the guide 64 (see the broken line in FIG. 4) can be rotated to a release position in which the rotor 63 is opened from the outer peripheral portion 63C and the pressing of the tube 53 is released.

A stopper 66 is formed on the outer side of the rotating pin 65 in the left-right direction. The stopper 66 is formed in a shaft shape that protrudes forward from the base portion 61. The stopper 66 contacts the guide 64 to prevent the guide 64 from moving too much outward in the left-right direction, and holds the guide 64 in the release position.

FIG. 6 is a sectional view taken along line VI-VI of FIG.
A pin sliding portion 68 for supporting a fixing pin (locking portion) 67 extending in the front-rear direction is formed at the upstream end portion 64C. The pin sliding portion 68 is formed with a columnar sliding hole 68A extending in the front-rear direction. A through hole 68B having a diameter smaller than that of the sliding hole 68A is formed at the front end of the sliding hole 68A. A fixing pin 67 is inserted into the through hole 68B, and the fixing pin 67 is slidably supported in the front-rear direction along the sliding hole 68A and the through hole 68B.

A disk-shaped receiving portion 67A is supported on the fixing pin 67. The receiving portion 67A is housed in the sliding hole 68A. Inside the sliding hole 68A, a compression spring (biasing member) 69 is arranged in front of the receiving portion 67A. The compression spring 69 urges the fixing pin 67 toward the base portion 61. A knob portion 67B having a diameter larger than that of the through hole 68B is supported at the front end of the fixing pin 67. The knob portion 67B is hooked on the upstream end portion 64C of the guide 64. The urged fixing pin 67 is prevented from coming off by the knob 67B, and the fixing pin 67 is held at a protruding position protruding from the guide 64. By pulling the knob portion 67B forward, the compression spring 69 is compressed and the fixing pin 67 can be retracted from the protruding position.

The base portion 61 is formed with a fixing hole (locked portion) 71 into which the fixing pin 67 is inserted. By inserting the fixing pin 67 into the fixing hole 71, the guide 64 is fixed at the closed position. Since the fixing pin 67 slides in a pin shape, it is easy to secure the amount of sliding in the front-rear direction, and it is easy to increase the difference between the protruding position and the position retracted from the protruding position.

A pin guide portion (guide portion) 72 is formed in the base portion 61 adjacent to the fixing hole 71. The pin guide portion 72 is formed in a passing region of the fixing pin 67 that rotates together with the guide 64. The pin guide portion 72 projects forward so as to come into contact with the fixing pin 67 at the protruding position. The pin guide portion 72 is formed continuously on the fixed guide surface (first inclined surface) 72B and the fixed guide surface 72B whose protrusion amount increases as the distance from the fixing hole 71 increases in the moving direction of the guide 64. It is provided with a release guide surface (second inclined surface) 72A in which the amount of protrusion decreases as the distance from 72B increases. A ridge-shaped top 72C is formed between the fixed guide surface 72B and the release guide surface 72A. A fixing hole 71 is formed in the fixing guide surface 72B. The amount of protrusion of the pin guide portion 72 is an amount that protrudes in a direction opposite to the protruding direction of the fixing pin 67, and is an amount that protrudes in a direction that retracts the fixing pin 67 from the protruding position.

When the guide 64 moves from the release position to the fixed position, the fixed pin 67 at the protruding position comes into contact with the pin guide portion 72. Since the fixing pin 67 is subjected to an urging force by the compression spring 69, the state in which the fixing pin 67 is in contact with the pin guide portion 72 is maintained, and when the fixing pin 67 crosses the top 72C of the pin guide portion 72, it moves back and forth. Slide in the direction. Therefore, when the guide 64 is moved to the closed position, the operator can obtain a feeling of wearing such as a click feeling, and can notify the operator that the guide 64 has been moved to the closed position.

Further, when the fixing pin 67 comes into contact with the release guide surface 72A, the urging force of the compression spring 69 acts on the fixing pin 67, so that the release guide surface 72A receives a force to move to the release position side due to the inclination of the release guide surface 72A. Therefore, when an external force does not act such as an operator's operation, the guide 64 moves toward the release position. Similarly, when the fixing pin 67 comes into contact with the fixing guide surface 72B, the fixing pin 67 is guided to the fixing hole 71 and locked. Therefore, the pin guide portion 72 can move the guide 64 to the closed position or a direction deviated from the closed position.

In particular, since the top 72C has a ridge shape, the fixing pin 67 is easily displaced from the top 72C. Therefore, even if the operator releases the guide 64 at the top 72C, the guide 64 moves to the fixed guide surface 72B or the release guide surface 72A. Therefore, in the present embodiment, the guide 64 moves to the closed position with a simple configuration. It is easier for the operator to recognize whether or not this is done. Therefore, incomplete fixation of the tube 53 to the tube pump 54 is suppressed. Further, the movement of the fixing pin 67 to an incompletely closed position where the fixing pin 67 is not fitted in the fixing hole 71 is easily recognized by the operator.

As shown in FIGS. 4 to 6, an introduction portion 73 that bifurcates toward the tube 53 side in the left-right direction is formed at the upstream end portion 64C of the guide 64. An introduction portion 61A is formed in the base portion 61 so as to face the introduction portion 73 of the guide 64. The surrounding shape is formed by the introduction portion 73 and the introduction portion 61A facing each other. A tube 53 extending from above passes through the inside of this enclosure shape, and the tube 53 is introduced between the rotor 63 and the guide 64. Further, the introduction portion 73 and the introduction portion 61A are formed outside the rotation shaft 62 of the rotor 63 in the left-right direction away from the nozzle 42. Therefore, the tube 53 is introduced into the tube pump 54 in a state where bending is suppressed.

In the guide 64, the downstream end portion 64B is arranged on the nozzle unit 33 side of the upstream end portion 64C in the left-right direction, and is arranged in an inclined state. Therefore, the size of the tube pump 54 in the vertical direction is suppressed as compared with the case where the guide 64 is arranged in the vertical direction.
The lower rotation pin 65 is arranged below the rotation shaft 62 of the rotor 63. Therefore, even if the guide 64 is moved to the release position, it is difficult to squeeze out to the left and right outside, and the space between the guide 64 and the rotor 63 can be greatly opened. Further, the size in the vertical direction can be made compact while securing the area where the tube 53 is sandwiched between the tube pump 54.

The pinch mechanism 55 that holds the tip end portion 53B of the tube 53 is located downstream of the guide 64 in the rotation direction of the rotor 63, and is arranged in the tangential direction A that passes below the nozzle 42 from the outer peripheral portion 63C of the rotor 63. .. The tangential direction A is the direction of the tangential line that is in contact with the outer peripheral portion 63C of the rotor 63 and extends downward from the outer peripheral portion 63C to the nozzle 42. Therefore, the virtual straight line L1 along which the tube 53 follows tends to follow the tangential direction A of the rotor 63, and bending of the tube 53 led out from the outside in the left-right direction of the rotor 63 can be suppressed.

The pinch mechanism 55 includes a box-shaped base portion 81. The base portion 81 is fixed to the front panel of the main body 2 with a fixture 55A. Therefore, the tube 53 led out from the tube pump 54 extends on the virtual straight line L1 extending linearly along the tangential direction A. Therefore, the tube 53 is not bent, the length of the tube 53 can be suppressed, and the concentrated beverage can easily flow. That is, the tube 53 can be arranged along the tangential direction A of the rotor 63, and the length of the tube 53 can be suppressed. Further, since the bending of the tube 53 can be suppressed, the beverage passing through the tube 53 can be easily flowed.

FIG. 7 is a perspective view of a main part of the pinch mechanism 55 as viewed from below.
A square tubular pinch wall portion 82 extending forward is formed in the front portion of the base portion 81. A pair of U-shaped grooves 82A, 82A facing each other along the tangential direction A (see FIG. 4) are formed in the pinch wall portion 82. A tube 53 is inserted into the U-shaped grooves 82A and 82A. The pinch wall portion 82 is supported by an opening / closing member 83 that closes the pinch wall portion 82 from the front and covers the tube 53 from the radial direction. One end of the opening / closing member 83 is hingeably supported by the pinch wall portion 82, and the other end is engaged with and supported by the pinch wall portion 82. A pinch mechanism body (not shown) having a solenoid (not shown) or the like is supported behind the base portion 61. The main body of the pinch mechanism is configured to press the tube 53 in the radial direction when the beverage is not supplied to prevent the concentrated beverage from dripping from the tube 53.

On the nozzle 42 side below the pinch wall portion 82, a holding member (holding portion) 84 that holds the tip portion 53B in the vicinity of the discharge port 53A of the tube 53 is arranged. The holding member 84 is arranged on a virtual straight line L1 (see FIG. 4). The holding member 84 includes a base portion 84A and a pair of holding portions 84B and 84B formed on the base portion 84A and projecting forward. Abutting portions 84C and 84C formed in parallel with each other and extending forward are formed in the opposing portions of the sandwiching portions 84B and 84B. In the present embodiment, the contact portions 84C and 84C are formed in parallel at regular intervals, the tips of the contact portions 84C and 84C are located forward, and the front is open.
The tube 53 is press-fitted and mounted between the holding portions 84B and 84B, and the flow path in the tube 53 is compressed flatly and mounted so that the flow velocity of the concentrated beverage in the tube 53 increases. Therefore, with a simple configuration, the flow path of the tip portion 53B of the tube 53 can be narrowed, and the flow velocity of the concentrated beverage can be increased. Further, the diameter of the tube 53 may differ depending on the type of BIB 52. Since the contact portions 84C and 84C are formed in parallel at regular intervals, it is easy to make the width of the cross section of the flow path the same even if the diameters of the tubes 53 are different when the wall thickness of the tubes 53 is the same. ing.

As shown in FIG. 4, the holding member 84 is arranged so as to enter below the nozzle unit 33. The holding member 84 is arranged so as to hold the discharge port 53A of the tube 53 toward the lower side of the discharge port 42A of the nozzle 42. Therefore, the concentrated beverage is discharged near the nozzle 42, and the concentrated beverage is applied to the beverage from the nozzle 42 to facilitate mixing. In particular, in the present embodiment, the tube 53 is compressed in a flat shape, and the cross-sectional width of the flow path of the tube 53 is likely to be constant. Therefore, the flow of the discharged beverage is stable and it is easy to discharge the beverage in a state where dripping is suppressed.

FIG. 8 is a front view showing the holding member 84 in the neutral position. FIG. 9 is a front view showing the holding member 84 in the upward position. FIG. 10 is a front view showing the holding member 84 in the downward position.
A support hole 84D extending in the front-rear direction is formed in the base portion 84A of the holding member 84. A convex shaft 81A provided in the base portion 81 is inserted into the support hole 84D. The base portion 84A is rotatably supported around the convex shaft 81A. An O-ring (not shown) that applies a frictional force is supported between the base portion 84A and the base portion 81, and the rotation angle of the base portion 84A can be maintained by the frictional force. In the present embodiment, the holding member 84 can change its orientation from the upward position shown in FIG. 9 to the downward position shown in FIG. Thereby, the discharge direction of the beverage discharged from the tube 53 can be adjusted according to the viscosity of the concentrated beverage.

A cap mounting portion 84E that protrudes in a cylindrical shape is formed on the lower surface of the holding member 84. The tip of the cap mounting portion 84E is formed in a flange shape, and the cap 85 is detachably supported. The cap 85 is attached to the cap attachment portion 84E when the beverage dispenser 1 is not in use, such as when the store is closed, and protects the discharge port 53A of the tube 53.
Further, on the lateral side of the pinch mechanism 55 in the left-right direction, the base portion 61 is formed with a recess 61B recessed in a circular shape at the rear. The recess 61B is configured so that the cap 85 can be fitted. When the beverage dispenser 1 is used, the cap 85 that protects the discharge port 53A of the tube 53 can be attached to the recess 61B for storage.

FIG. 11 is a perspective view showing a state in which the pump unit 91 is removed. FIG. 12 is a perspective view showing a state in which the pinch unit 92 is removed.
The tube pump 54 and the pinch mechanism 55 are each unitized. The pump unit 91 including the tube pump 54 and the pinch unit 92 including the pinch mechanism 55 are fixed to the main body 2 as separate bodies.

As shown in FIG. 11, the panel 2B on the front surface of the main body 2 is formed with an opening-shaped mounting portion 2C to which the pump unit 91 can be mounted. The pump unit 91 is fixed to the panel 2B of the main body 2 by inserting the rear portion of the pump unit 91 into the mounting portion 2C and fixing the fixing portion 61C of the base portion 61 with the fixture 54A (see FIG. 4).

Further, a unit support portion 93 is formed on the nozzle 42 side in the lower portion of the base portion 61 of the pump unit 91. The unit support portion 93 is inclined so as to move away from the nozzle 42 as it goes downward. The unit support portion 93 is formed with a pair of support portions 93A, 93A that are L-shaped and extend in the front-rear direction.

As shown in FIG. 12, the pinch unit 92 is slidably engaged with the unit support portion 93 in the front-rear direction. A bent plate-shaped engaging portion 94 is supported on the upper portion of the pinch unit 92. A pair of insertion portions 94A, 94A extending in the front-rear direction are formed at both left and right ends of the engaging portion 94. The pinch unit 92 is supported by the pump unit 91 by inserting the insertion portions 94A, 94A into the support portions 93A, 93A from the front or the rear. The pump unit 91 and the pinch unit 92 are movably engaged with each other in the front-rear direction.

As shown in FIG. 12, an opening-shaped mounting portion 2D to which the pinch unit 92 can be mounted is formed on the panel 2B on the front surface of the main body 2. The rear portion of the pinch unit 92 is inserted into the mounting portion 2D so that the engaging portion 94 is fitted into the unit support portion 93 of the pump unit 91. Then, the fixing portion 81B of the base portion 81 is fixed by the fixture 55A (see FIG. 4). As a result, the pinch unit 92 is fixed to the panel 2B of the main body 2. Since the pinch unit 92 can be attached to and detached from the pump unit 91, maintainability is improved.

In the present embodiment, the left and right pump units 91 have different formation positions of the unit support portion 93, but the pinch unit 92 is common to the left and right pump units 91.
Since the pump unit 91 and the pinch unit 92 are separate bodies, the tolerances of the parts may accumulate, but since the orientation of the holding member 84 can be adjusted, the error can be absorbed and the concentrated beverage can be easily discharged to the predetermined position. ing.

Next, the operation of this embodiment will be described.
When the beverage dispenser 1 is used, when the user operates the syrup beverage selection button 3B, the solenoid valves 38 and 40 are opened, and water is supplied to the nozzle unit 33 and syrup is supplied. The supplied water and syrup are mixed by the mixer unit 41 and discharged downward from the discharge port 42A of the nozzle 42. Therefore, the syrup beverage is supplied to the cup 4 on the drip tray 6.

When the user operates the concentrated beverage selection button 3B, the solenoid valve 38 is opened, water is supplied to the nozzle unit 33, water is discharged from the nozzle 42, and the corresponding tube pump 54 and pinch mechanism are used. 55 is activated and the concentrated beverage is discharged from the tube 53. Therefore, the concentrated beverage is supplied to the cup 4 in a state where it hits the water and is easily mixed with the water.

In the tube pump 54 and the pinch mechanism 55 of the present embodiment, the tube 53 is less bent, and the concentrated beverage easily flows through the tube 53 without interruption. Moreover, since the tip portion 53B of the tube 53 is compressed in a flat shape, the concentrated beverage discharged from the tube 53 is easily discharged from the nozzle 42 in a state where the flow velocity is increased and the liquid is less likely to drip. Therefore, the concentrated beverage is supplied to the cup 4 in a state where it hits the water and is easily mixed with the water.

Further, since the angle of the holding member 84 can be adjusted, in the case of a concentrated beverage having a high viscosity, the angle of the holding member 84 can be adjusted and the discharge port 53A of the tube 53 can be set upward. Therefore, even if it is easy to drip, it is easy to appropriately hit the water discharged from the nozzle 42. On the other hand, in the case of a concentrated beverage having a low viscosity, the angle of the holding member 84 can be adjusted to set the discharge port 53A of the tube 53 downward. Since the discharge direction of the concentrated beverage can be directed downward, it is possible to prevent the concentrated beverage from hitting the water vigorously and scattering.

Next, a case where the BIB 52 is replaced will be described.
When the BIB 52 is replaced, such as when the concentrated beverage is emptied, the guide 64 of the tube pump 54 is moved to the release position, and the opening / closing member 83 of the pinch mechanism 55 is opened. Then, the tube 53 is removed from the tube pump 54 and the pinch mechanism 55, and the BIB 52 is removed from the cold storage 51.

When mounting a new BIB 52, the tube 53 of the BIB 52 is moved along the outer peripheral portion 63C of the rotor 63 to move the guide 64 to the closed position. When the fixing pin 67 is inserted into the fixing hole 71 and fixed, the tube 53 is fixed along the guide 64.
At this time, since the fixing pin 67 slides in the axial direction of the fixing pin 67 when guided by the pin guide portion 72, a feeling of wearing can be obtained.

Further, if the operator stops the operation before moving the guide 64 to the closed position, the fixing pin 67 is guided by the pin guide portion 72 and moves. Therefore, when the guide 64 is in an unfixed state near the closed position, it is possible to easily make the operator notice the unfixed state. Therefore, the operator can move the guide 64 to the closed position so as to obtain a feeling of wearing, and can prevent the tube 53 from being mounted on the tube pump 54 in an erroneous state.

Further, in the holding member 84, the tips of the holding portions 84B and 84B are directed forward so that the open tip side of the holding portions 84B and 84B can be visually recognized, and the tube 53 is held between the holding portions 84B and 84B. Easy to work. Therefore, the work efficiency is improved.

Next, a case where the tube pump 54 and the pinch mechanism 55 are maintained will be described.
It may be necessary to replace a part due to deterioration over time. At this time, in the present embodiment, the tube pump 54 and the pinch mechanism 55 are configured as separate units from the pump unit 91 and the pinch unit 92, and can be individually assembled to the main body 2. Therefore, as compared with the case where the tube pump 54 and the pinch mechanism 55 form an integrated unit, the weight of each is reduced and the workability at the time of maintenance is improved.

As described above, the beverage dispenser 1 of the present embodiment accommodates the main body 2, the nozzle 42 supported by the main body 2 and extending in the vertical direction to discharge water from below, and the concentrated beverage mixed with water. A tube 53 connected to the beverage accommodating portion 52A to flow the concentrated beverage and a tube pump 54 for delivering the beverage in the tube 53 are provided, and are arranged downstream of the tube pump 54 in the supply direction of the concentrated beverage. A holding member 84 is provided which holds the tip 53B of the 53 by compressing it from the radial direction of the tube 53 and increases the flow velocity of the concentrated beverage flowing in the tube 53.
Therefore, the flow velocity of the concentrated beverage can be increased by narrowing the flow path of the tip portion 53B of the tube 53. Therefore, the concentrated beverage discharged from the tip portion 53B can be suppressed from dripping and easily exposed to water, and the beverage from the tank unit 12 and the beverage from the BIB units 13 and 13 can be sufficiently mixed.

In the present embodiment, the holding member 84 includes a base portion 84A and a pair of holding portions 84B supported by the base portion 84A, and a tube 53 is press-fitted into the pair of holding portions 84B.
Therefore, the tip portion 53B of the tube 53 can be compressed with a simple configuration.

Further, in the present embodiment, the pair of sandwiching portions 84B are arranged so that the base portion 84A is supported by the main body 2 and the tip thereof is separated from the main body 2.
Therefore, the open tip side of the holding portion 84B can be visually recognized, and the work of holding the tube 53 between the holding portions 84B and 54B becomes easy.

Further, in the present embodiment, the holding portion 84B includes an abutting portion 84C that abuts in the radial direction of the tube 53, the abutting portion 84C is formed in a straight line, and a pair of abutting portions 84C are arranged in parallel. Has been done.
Therefore, the width of the cross section of the flow path of the tube 53 can be made constant, and the flow of the beverage can be easily stabilized.

The present invention is not limited to the one described in the above embodiment, and various modifications and applications can be made without departing from the spirit of the present invention.
For example, a configuration in which a plurality of nozzles 42 are provided may be provided.
The tube pump 54 and the pinch mechanism 55 are formed separately, but may be an integrated unit.
Although the configuration in which the pin guide portion 72 is provided on the base portion 61 of the tube pump 54 has been described, the pin guide portion 72 may be omitted and an electrical detection member may be provided to detect the movement of the guide 64.
Although the guides 64 of the tube pump 54 are arranged on different sides on the left and right, they may be arranged on the same side.

As described above, the beverage dispenser according to the present invention can be suitably used as a beverage dispenser that uses a BIB and holds the tip of the tube by a pinch mechanism.

1 Beverage dispenser 2 Main body 42 Nozzle 52A Beverage storage part 53 Tube 53B Tip part 54 Tube pump 84 Holding member (holding part)
84A base 84B holding part 84C contact part

Claims (4)

With the main body
A nozzle that is supported by the main body and extends in the vertical direction to discharge the first beverage from below.
A tube connected to a beverage storage unit for accommodating a second beverage to be mixed with the first beverage and through which the second beverage flows.
A tube pump for delivering the beverage in the tube,
The second beverage, which is arranged on the downstream side in the supply direction of the second beverage with respect to the tube pump, compresses and holds the tip of the tube from the radial direction of the tube, and flows in the tube. With a retainer to increase the flow velocity,
Beverage dispenser characterized by that. The holding portion includes a base portion and a pair of holding portions supported by the base portion.
The tube is press-fitted into the pair of holding portions.
The beverage dispenser according to claim 1. The pair of holding portions are arranged on a side in which the base portion is supported by the main body and the tip thereof is separated from the main body.
2. The beverage dispenser according to claim 2. The sandwiching portion includes a contact portion that abuts in the radial direction of the tube.
The contact portion is formed in a straight line and is formed.
The pair of the contact portions are arranged in parallel,
The beverage dispenser according to claim 2 or 3.

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