KR102380876B1 - Beverage maker - Google Patents

Abstract

A beverage maker according to an embodiment of the present invention includes a capsule housing having a capsule accommodating space in which a capsule containing beverage material is accommodated, and a lid module covering the capsule housing, any one of the lid module and the capsule housing, It includes an inlet passage for supplying water or air toward the capsule receiving space, and a capsule perforating portion for puncturing the capsule.

Description

Beverage Maker {BEVERAGE MAKER}

The present invention relates to a beverage maker, and more particularly, to a beverage maker capable of preventing leakage of water or air input into the supply when extracting beverage materials accommodated in the supply.

Beverage is a generic term for drinkable liquids such as alcohol or tea. For example, beverages are divided into various categories, such as water (drinks) to quench thirst, juice drinks with a unique flavor and taste, soft drinks that give a refreshing feeling, preference drinks that can be expected to have arousal effect, or alcoholic drinks with alcohol effects can be

A typical example of such a beverage is beer. Beer is an alcoholic beverage made from malt (malt) made from sprouting barley, filtered, added hops, and fermented with yeast.

Consumers can purchase and consume ready-made products manufactured and sold by beer makers, or they can consume house beer (or craft beer) manufactured by directly fermenting beer ingredients at home or in a bar.

House beer can be manufactured in a variety of types than ready-made products, and can be manufactured to better suit consumer tastes.

Materials for beer production may include water, liquid malt, hops, yeast, and flavor additives.

Yeast can be called yeast and can be added to the liquid malt to ferment the liquid malt and help produce alcohol and carbonic acid.

Flavor additives are additives that enhance the taste of beer, such as fruit, syrup, or vanilla beans.

In general, house beer may largely include a total of three steps of a wort production step, a fermentation step, and a maturation step, and it may take 2 to 3 weeks from the wort production step to the maturation step.

For house beer, it is important to maintain the optimum temperature during the fermentation stage, and the easier it is to manufacture, the more convenient the user can be.

Recently, a beverage maker that can easily prepare a beverage such as beer at home or a bar is gradually being used, and it is preferable that such a beverage maker is configured to be convenient for use.

1. Unexamined Patent Publication No. 10-2014-0005379 (published on Jan. 14, 2014)

An object to be solved by the present invention is to provide a beverage maker capable of preventing leakage of the input water or air when water or air is introduced to guide the beverage material accommodated in the feeder to the fermenter.

Another object to be solved by the present invention is to provide a beverage maker capable of further simplifying the structure of an inlet flow path for introducing water or air into the capsule receiving space of the feeder in which the beverage material is accommodated.

According to one aspect for solving the problems of the present invention, a beverage maker includes a capsule housing having a space in which a capsule containing beverage material is accommodated, and a lid module covering the capsule housing, of the lid module and the capsule housing Any one, including an inlet passage for supplying water or air, and a capsule perforating part for puncturing the capsule, may perform puncturing of the capsule and supply of water or air at the same time.

According to an embodiment, any one of the lead module and the capsule housing includes an inlet body having the inlet passage and a capsule perforation formed therein, and the inlet body includes an upper body connected to a feeder inlet passage and a lower body having a capsule perforation formed therein. It may have a space forming an inlet flow path therebetween.

According to an embodiment, the inlet body may further include a sealing body fixed to at least one of the upper body and the lower body and formed to surround side surfaces of the upper body and the lower body.

According to an embodiment, the sealing body further includes a sealing rib formed on a bottom surface and formed with a lower contact portion contacting the upper surface of the capsule and the capsule housing, the space inside the sealing rib and the space between the sealing rib and the capsule housing can be shielded from each other.

According to an embodiment, the distance between the lower end of the capsule housing and the lower end of the capsule perforation part may be implemented to be shorter than the distance between the lower end of the capsule housing and the lower end of the sealing rib.

According to an embodiment, the beverage maker may further include a capsule sealing member mounted on the capsule housing to seal between the capsule housing and the capsule.

According to an embodiment of the present invention, the beverage maker includes an inlet body having the capsule perforation part and the inlet passage as an integral part, so that it has a more simplified structure, so that the product can be easily manufactured and assembled.

In addition, since the inlet body has a minimized configuration of the upper body, the lower body, and the sealing body, it is possible to reduce the manufacturing cost or the assembly time.

In addition, the sealing body is formed to surround the side surfaces of the upper body and the lower body, so that it is possible to prevent water leakage or air leakage through a gap between the upper body and the lower body.

In addition, since the inner space and the outside of the sealing rib are shielded by the sealing rib included in the sealing body, the water supplied to the inside of the capsule is prevented from leaking to the outside or the beverage material from leaking back to the outside, so that the beverage maker is clean can keep

In addition, since water or beverage material is prevented from flowing into the capsule housing by the capsule sealing member mounted on the capsule housing and sealing the space between the capsule housing and the capsule, it is possible to maintain the cleanliness of the capsule housing.

In addition, since the distance between the lower end of the capsule housing and the lower end of the capsule perforation part is implemented to be shorter than the distance between the lower end of the capsule housing and the lower end of the sealing rib, the upper part of the capsule can be perforated more effectively.

1 is a perspective view of a capsule and a beverage maker having the same according to an embodiment of the present invention.
Figure 2 is an overall configuration diagram of a beverage maker according to an embodiment of the present invention.
3 is a perspective view of the feeder shown in FIG. 1 ;
Figure 4 is a plan view showing the inside of the lead module of the feeder shown in Figure 3;
5 is an exploded view of an inlet body included in the lead module shown in FIG. 4 , and FIG. 6 is a cross-sectional view of the inlet body.
7 is a cross-sectional view when the lid module covers the capsule and the capsule container after the capsule is seated in the feeder.
FIG. 8 is an enlarged view of part A of the cross-sectional view shown in FIG. 7 .
9 is a cross-sectional view when the capsule container is opened and the capsule is withdrawn from the capsule container.
FIG. 10 is an enlarged view of part B of the cross-sectional view shown in FIG. 9 .

Hereinafter, specific embodiments of the present invention will be described in detail with drawings.

1 is a perspective view of a capsule and a beverage maker having the same according to an embodiment of the present invention, Figure 2 is an overall configuration diagram of the beverage maker according to an embodiment of the present invention.

The configuration and perspective views of the beverage maker shown in FIGS. 1 to 2 are for convenience of explanation, and the configuration and appearance of the beverage maker having a capsule according to an embodiment of the present invention are not limited thereto.

In addition, in the present specification, it is assumed that the beverage manufactured using the beverage maker is beer, but the types of beverages that can be manufactured using the beverage maker may vary.

1 and 2, the beverage maker includes a fermentation module 1, a feeder 3 connected to the fermentation module 1 and a main flow path 2, and a feeder 3 and an inlet flow path 4 It includes a water supply module (5) connected to, and a beverage extractor (6) from which the beverage fermented in the fermentation module (1) is taken out to the outside.

The fermentation module 1 includes a fermenter assembly 11 having a space S1 therein.

The fermenter assembly 11 may include a fermenter 112 having an opening 111 formed therein and a space S1 formed therein, and a fermenter cover 114 covering the opening 111 .

The fermenter 112 may be composed of a combination of a plurality of members.

The fermenter cover 114 is to seal the inside of the fermenter 112 , and may be disposed on the upper portion of the fermenter 112 to cover the opening 111 . The fermenter cover 114 may be provided with a main flow path connection part 115 connected to the main flow path 2 .

In addition, the fermentation module 1 may further include a beverage preparation pack 12 that is inserted into and accommodated in the fermenter assembly 11 . The beverage preparation pack 12 may be a pack in which the material for beverage preparation is accommodated therein.

The beverage preparation pack 12 may be formed smaller than the space S1 formed inside the fermenter assembly 11 . The beverage preparation pack 12 may be accommodated by being inserted into the fermenter 11 in a state in which the material is accommodated therein. The beverage preparation pack 12 may be inserted into the fermenter 112 and accommodated in the fermenter 112 while the opening 111 of the fermenter 112 is opened. The fermenter cover 114 may cover the opening 111 of the fermenter 112 after the beverage preparation pack 12 is inserted into the fermenter 112 . Beverage preparation pack 12 may help the fermentation of materials in a state accommodated in the space S1 closed by the fermenter 112 and the fermenter cover 114 . The beverage preparation pack 12 may be inflated by the pressure therein while the preparation of the beverage is in progress.

According to an embodiment, the beverage manufactured by the beverage maker may be manufactured without going through a fermentation process. For example, a specific beverage may be manufactured by mixing water and materials into the beverage preparation pack 12 . In this case, the fermenter 112 may function as a storage container to accommodate and store the beverage preparation pack 12 containing the manufactured beverage.

On the other hand, there is beer as an example of a beverage that can be manufactured using a beverage maker. For example, the material for beer production may include water, malt, yeast, hops, flavor additives, and the like.

The beverage maker may include both the supply unit 3 and the beverage preparation pack 12 , and the material for beverage preparation may be dispersedly accommodated in the supply unit 3 and the beverage preparation pack 12 . The beverage preparation pack 12 may contain some of the materials for beverage production, and the feeder 3 may contain the remaining materials. The remaining materials accommodated in the feeder 3 may be supplied to the beverage preparation pack 12 together with the water supplied from the water supply module 5, and may be mixed with some materials accommodated in the beverage preparation pack 12. there is.

The beverage preparation pack 12 may contain a main material essential for beverage production, and the feeder 3 may contain additives added to the main material. In this case, the additive contained in the feeder 3 may be mixed with water supplied from the water supply module 5 and supplied to the beverage preparation pack 12 , and mixed with the main material accommodated in the beverage preparation pack 12 . can be

The main material accommodated in the beverage preparation pack 12 may be a material with more capacity than other materials. For example, in the case of beer production, the main material may be malt, yeast, hops, or malt among flavor additives. In addition, the additive accommodated in the feeder 3 may be a material other than malt among the materials for manufacturing beer, and may be yeast, hops, flavor additives, or the like.

On the other hand, the beverage maker does not include both the beverage preparation pack 12 and the supply unit 3, as described above, and without a separate beverage preparation pack 12, only the supply unit 3 may be provided, and the supply unit 3 ) can accommodate all materials for beverage manufacturing. In this case, all the materials accommodated in the feeder 3 may be supplied into the fermenter assembly 11 together with the water supplied from the water supply module 5 . The feeder 3 may contain the main material and the additive together, and the main material and the additive accommodated in the feeder 3 may be simultaneously supplied into the fermenter assembly 11 or may be sequentially supplied with a time difference.

In addition, the beverage maker does not include a separate beverage production pack 12 , the user directly inputs some materials for beverage production into the fermenter assembly 11 , and the remaining materials for beverage production are in the feeder 3 . Acceptance is also possible. In this case, the user directly inputs the main material into the fermenter assembly 11 , and the additive may be accommodated in the feeder 3 . The additive accommodated in the feeder 3 may be mixed with the water supplied from the water supply module 5 and supplied into the fermenter assembly 11, and may be mixed with the main material previously introduced into the fermenter assembly 11. .

When the beverage maker includes both the feeder 3 and the beverage production pack 12 , it is possible to manufacture a beverage more conveniently, and below, an example including both the feeder 3 and the beverage production pack 12 will be described. However, of course, the present invention is not limited to including both the feeder 3 and the beverage preparation pack 12 .

The material input into the beverage preparation pack 12 may be fermented over time, and the beverage manufactured in the beverage preparation pack 12 may flow into the main flow path 2 through the main flow path connection part 115, and , may flow from the main flow path 2 to the beverage dispenser 6 and be taken out by the beverage dispenser 6 .

The fermentation module 1 may further include a temperature controller for changing the temperature of the fermenter assembly 11 . The temperature controller heats or cools the fermenter assembly 11 , and may adjust the temperature of the fermenter assembly 11 to an optimal temperature for beverage fermentation.

The temperature controller may include a compressor 131, a condenser 132, an expansion mechanism 133, and a refrigeration cycle device 13 having an evaporator 134, any one of the condenser and the evaporator is a fermenter assembly ( 11) can be placed.

When the condenser 132 is placed in contact with the fermenter 112 , the refrigeration cycle device 13 may heat the fermenter 112 to adjust the temperature of the fermenter 112 . In this case, the condenser 132 may be disposed to be in contact with the outer surface of the fermenter 112 . The condenser 132 may include a condensing tube wound around the outer surface of the fermenter 112 .

When the evaporator 134 is disposed to be in contact with the fermenter 112 , the refrigeration cycle device 13 may cool the fermenter 112 to adjust the temperature of the fermenter 112 . In this case, the evaporator 134 may be disposed to be in contact with the outer surface of the fermenter 112 . The evaporator 134 may include an evaporation tube wound around the outer surface of the fermenter 112 .

The thermostat may further include a heater 14 for heating the fermenter assembly 11 . The heater 14 may be installed to be in contact with the outer surface of the fermenter 112, and may be configured as a heating heater that generates heat when power is applied. The heater 14 may be configured as a line heater, and may be wound around the outer surface of the fermenter 112 .

The refrigeration cycle device 13 may be configured as a heat pump. The refrigeration cycle device 13 may include a flow path switching valve (not shown). The flow path switching valve may be configured as a four-way valve. The flow path switching valve may be respectively connected to the suction flow path of the compressor 131 and the discharge flow path of the compressor 131, may be connected to the condenser 132 and the condenser connection flow path, and may be connected to the evaporator 134 and the evaporator connection flow path. .

The flow path switching valve may guide the refrigerant compressed in the compressor 131 to the condenser 132 when the fermenter 112 is cooled, and guide the refrigerant leaked from the evaporator 134 to the compressor 131 .

The flow path switching valve may guide the refrigerant compressed in the compressor 131 to the evaporator 134 when the fermenter 112 is heated, and also guide the refrigerant leaked from the condenser 132 to the compressor 131 .

Hereinafter, the feeder 3 will be described as follows.

The feeder 3 may be connected to the water heater 53 and the inlet passage 4 , and may be connected to the fermenter assembly 11 and the main passage 2 .

The feeder (3) may be accommodated in the material required for beverage production, the water supplied from the water supply module (5) may be configured to pass. For example, when the beverage manufactured in the beverage maker is beer, the material accommodated in the feeder 3 may be yeast, hops, flavor additives, or the like.

The material received in the feeder 3 may be received directly in a material receiver formed in the feeder 3 . At least one material receiver may be formed in the feeder 3 . A plurality of material accommodating portions may be formed in the feeder 3, and in this case, a plurality of material accommodating portions may be formed to be partitioned from each other.

On the other hand, the material accommodated in the feeder 3 may be accommodated in the capsule, the feeder 3 may be formed with at least one capsule receiving portion in which the capsule is accommodated. When the material is contained in the capsule, the feeder 3 may be configured to allow seating and withdrawal of the capsule, and the feeder 3 may be configured as a capsule kit assembly in which the capsule is detachably accommodated. The capsule means a capsule in which the material for beverage production is accommodated.

A main flow path 2 and an inlet flow path 4 may be respectively connected to the feeder 3 , and water supplied to the inlet flow path 4 may be mixed with the material while passing through the material receiving part or capsule, and the material receiving part Alternatively, the material accommodated in the capsule may flow into the main flow path 2 together with water.

The feeder 3 may contain a plurality of additives of different types separated from each other. The plurality of additives accommodated in the feeder 3 may be yeast, hops and flavor additives, which may be accommodated separately from each other.

When a plurality of capsule accommodating parts are formed in the feeder 3 , each of the plurality of capsule accommodating parts may be connected to the inlet flow path 4 and the feeder inlet flow path, and may be connected to the main flow path 2 and the feeder outlet flow path.

The material receiver of the feeder 3 and the capsule receiver of the feeder 3 may be of substantially the same construction. When the capsule is inserted into the feeder 3 in a state in which the material is accommodated in the capsule, it may be referred to as a capsule receiving part, and when the material is directly accommodated in the feeder 3 in a state in which the material is not contained in the capsule, it may be referred to as a material receiving part. Since the material accommodating part and the capsule accommodating part have substantially the same configuration, hereinafter, it will be described that the capsule accommodating part is formed in the feeder 3 for convenience of description.

The feeder 3 is formed with a capsule receiving portion in which the capsule containing the additive is detachably accommodated, may be connected to the inlet flow path 4 and the feeder inlet flow path, and may be connected to the main flow path 2 and the feeder outlet flow path.

An opening/closing valve for opening and closing the feeder inlet flow path may be installed in the feeder inlet flow path.

A check valve for preventing the fluid of the main flow path 2 from flowing back into the capsule container may be installed in the feeder outlet flow path.

The feeder 3 may be provided with a plurality of capsule accommodating portions 31, 32 and 33, and a plurality of capsule containers may be formed separately from each other. The plurality of capsule accommodating portions 31, 32, 33 may be connected to their respective feeder inlet passages and their respective feeder outlet passages.

* Hereinafter, the first additive, the second additive, and the third additive may be accommodated in the feeder 3 . For example, when manufacturing beer using a beverage maker, the first additive may be yeast, the second additive may be hops, and the third additive may be a flavor additive.

The feeder 3 includes a first capsule accommodating part 31 in which the first capsule (C1) containing the first additive is accommodated, and the second capsule accommodating part 32 in which the second capsule (C2) in which the second additive is accommodated is accommodated. ) and a third capsule containing the third additive (C3) may include a third capsule accommodating portion 33 is accommodated.

A first feeder inlet flow path 311 for guiding water or air to the first capsule receiving unit 31 may be connected to the first capsule receiving unit 31, and water leaked from the first capsule receiving unit 31, A first feeder outlet passage 312 through which the mixture of water and the first additive, air is guided may be connected. A first opening/closing valve 313 for opening and closing the first feeder inlet flow path 311 may be installed in the first feeder inlet flow path 311 . In the first feeder outlet flow path 312 , the fluid of the first capsule accommodating part 31 flows into the main flow path 2 while preventing the fluid of the main flow path 2 from flowing back into the first capsule accommodating part 31 . A first check valve 314 may be installed. Here, the fluid may be water leaked from the first capsule receiving part 31, a mixture of water and the first additive, and air.

A second supply inlet passage 321 for guiding water or air to the second capsule accommodating part 32 may be connected to the second capsule accommodating part 32, and water flowing out from the second capsule accommodating part 32, A second feeder outlet passage 322 through which the mixture of water and the second additive, air is guided may be connected. A second on-off valve 323 for opening and closing the second feeder inlet passage 321 may be installed in the second feeder inlet passage 321 . In the second feeder outlet flow path 322 , the fluid of the second capsule accommodating part 32 flows into the main flow path 2 while preventing the fluid of the main flow path 2 from flowing back into the second capsule accommodating part 32 . A second check valve 324 may be installed. Here, the fluid may be water, a mixture of water and the second additive, and air leaked from the second capsule receiving unit 32 .

A third supply inlet flow path 331 for guiding water or air to the third capsule accommodating part 33 may be connected to the third capsule accommodating part 33, and water leaked from the third capsule accommodating part 33, A third feeder outlet passage 332 through which the mixture of water and the third additive, air is guided may be connected. A third on-off valve 333 for opening and closing the third feeder inlet passage 331 may be installed in the third supply inlet passage 331 . In the third feeder outlet flow path 332 , the fluid of the third capsule accommodating part 33 flows into the main flow path 2 while preventing the fluid of the main flow path 2 from flowing back into the third capsule accommodating part 33 . A third check valve 334 may be installed. Here, the fluid may be water, a mixture of water and a third additive, and air leaked from the third capsule accommodating part 33 .

The beverage maker may include a bypass flow path 34 through which water supplied from the inlet flow path 4 can be supplied to the main flow path 2 by bypassing the capsule accommodation units 31 , 32 , 33 . .

The bypass flow path 34 is connected to the inlet flow path 4 and the main flow path 2, and water or air in the inlet flow path 4 bypasses the capsule accommodating parts 31, 32, and 33 to bypass the main flow path ( 2) may be guided to the bypass flow path 34 to flow.

The bypass flow path 34 may be connected in parallel with the flow path of the first capsule accommodating part 31 , the flow path of the second capsule accommodating part 32 , and the flow path of the third capsule accommodating part 33 .

A bypass valve 35 for opening and closing the bypass flow path 34 may be installed in the bypass flow path 34 .

The main flow path 2 may be connected to the first feeder outlet flow path 312 , the second feeder outlet flow path 322 , the third feeder outlet flow path 332 , and the bypass flow path 34 . The main flow path 2 includes a common pipe connected to the fermenter assembly 11, a first feeder outlet flow path 312, a second feeder outlet flow path 322, a third feeder outlet flow path 332, and a bypass flow path ( 34) and may include a laminated pipe connected to a common pipe.

The main flow path 2 may be connected to the fermenter assembly 11 , and may be connected to the fermenter cover 114 of the fermenter assembly 11 . The main flow path 2 may be connected to the main flow path connection part 115 provided in the fermenter cover 114 .

The inlet passage 4 may be connected to the first feeder inlet passage 311 , the second feeder inlet passage 321 , the third feeder inlet passage 331 , and the bypass passage 34 .

The inlet flow path 4 has a common pipe connected to the water supply module 5, a common pipe branching from the common pipe, and a first feeder inlet flow path 311, a second feeder inlet flow path 321, and a third feeder inlet flow path 331. and a plurality of branch pipes connected to the bypass flow path 34 .

The water supply module 5 includes a water tank 51 containing water; a water supply pump 52 for pumping water in the water tank 51; It may include a water heater 53 that heats the water pumped by the water pump 52 .

A water tank outlet water passage 54 may be connected to the water tank 51 , and the water supply pump 52 may be connected to the water tank outlet water passage 54 .

A feed water pump outlet flow path 55 may be connected to the feed water pump 52 , and the feed water heater 53 may be connected to the feed water pump outlet flow channel 55 .

A flow meter 56 for measuring the flow rate of the feed water pump outlet channel 55 may be installed in the feed water pump outlet flow path 55 .

The water supply heater 53 may be a mold heater, and includes a heater case through which water pumped from the water supply pump 52 passes therein, and a heating heater installed inside the heater case to heat the water flowing into the heater case. can The water heater 53 may be provided with a thermistor 57 that measures the temperature of the water heater 53 . In addition, a thermal fuse 58 may be installed in the water supply heater 53 to cut off the circuit when the temperature is high to block the current applied to the water supply heater 53 .

When the feed water pump 52 is driven, the water in the water tank 51 may be guided to the water heater 53 through the water tank outlet flow path 54 , the feed water pump 52 , and the feed water pump outlet flow channel 55 , and the water supply The water guided to the heater 53 may be heated in the water supply heater 53 and then guided to the inlet passage 4 .

The beverage dispenser 6 may be connected to the main flow path 2 . The beverage dispensing machine 6 may include a beverage dispensing flow path 61 connected to the main flow path 2 and guiding the beverage of the main flow path 2 . The beverage dispensing machine 6 may further include a beverage dispensing valve 62 connected to the beverage dispensing passage 61 .

The beverage extraction passage 61 may be provided with a foam blocking part 63, and the foam of the beverage flowing from the main flow passage 2 to the beverage extraction passage 61 is minimized while passing through the foam blocking path. can be The bubble blocking part 63 may be provided with a mesh (Mesh), etc. through which the bubbles are filtered.

* For example, the beverage dispensing valve 62 may include a lever operated by the user and a tap valve having a limit switch (Micro Switch) for sensing the user's operation, but this is not necessarily the case.

The beverage maker may further include an air injector 8 connected to at least one of the main passage 2 and the inlet passage 4 to inject air.

When the air injector 8 is connected to the inlet passage 4 , air can be injected into the feeder 3 through the inlet passage 4 , and the air injected into the inlet passage 4 is connected to the feeder 3 and the main After passing through the flow path (2) sequentially may be injected into the beverage preparation pack (12). When the air injector 8 is connected to the inlet passage 4, air can be injected into the beverage preparation pack 12 through the inlet passage 4, the bypass passage 34, and the main passage 2, Air may be supplied to the material in the beverage preparation pack 12 .

When the air injector 8 is connected to the inlet flow path 4, air can be injected into the capsule accommodating parts 31, 32, 33 through the inlet flow path 4, and the capsules (C1) (C2) ( C3) and the remaining water or residues in the capsule accommodating parts 31, 32 and 33 can flow into the main flow path 2, and the capsules C1 (C1) (C2) (C3) and the capsule accommodating parts 31, 32 )(33) can be kept clean. According to an embodiment, the air injector 8 injects air into the capsule receiving portions 31, 32, and 33 through the inlet passage 4, and the beverage material contained in the capsules C1, C2, and C3. can be extracted into the main flow path (2).

The air injector 8 may include an air injection passage 81 connected to the inlet passage 4 , and an air injection pump 82 for pumping air into the air injection passage 81 .

The air injector 8 may further include a check valve 83 for preventing the water of the inlet passage 4 from flowing into the air injection pump 82 through the air injection passage 81 . The check valve 83 may be installed after the air injection pump 82 in the air injection direction.

The air injector 8 may further include an air filter connected to the air injection passage 81 and installed before the air injection pump 82 in the air injection direction.

When the air injection pump 82 is driven, the air can be filtered from dust by the air filter, and the air that has passed through the air filter 84 is flowed by the air injection pump 82 into the inlet passage 4 . can be moved.

The beverage maker may further include a main valve 9 for opening and closing the main flow path 2 .

The main valve 9 is installed between the connection part 91 of the main flow path 2 and the beverage extraction flow path 61 of the main flow path 2 and the connection part 92 of the main flow path 2 and the fermenter assembly 11 to be installed. can

The main valve 9 may be opened when hot water is injected into the beverage preparation pack 12 to open the main flow path 2 . The main valve 9 may be closed while cooling the fermenter assembly 11 to close the main flow path 2 . The main valve 9 may be opened when air is injected into the beverage preparation pack 12 to open the main flow path 2 . The main valve 9 may be opened when the additive is supplied into the beverage preparation pack 12 to open the main flow path 2 . The main valve 9 may be closed while the fermentation of the material is in progress to seal the inside of the beverage preparation pack 12 . The main valve 9 may be closed during aging and storage of the beverage to seal the inside of the beverage preparation pack 12 . The main valve 9 may be opened when the beverage is taken out by the beverage dispenser 6 to open the main flow path 2 .

The beverage maker may further include a base 100 . The base 100 may constitute the outer appearance of the bottom surface of the beverage maker, and the fermenter assembly 11, the compressor 131, the feed water heater 53, the feed water pump 52, the water tank 51, etc. located on the upper side thereof can support

The beverage maker may include an insulating wall surrounding the fermenter 112 and the evaporator 134 together. The insulating wall may be formed of expanded polystyrene, etc., which has high thermal insulation performance and can absorb vibration.

* The beverage maker may include a peripheral surface of the insulating wall, and an insulating wall cover 104 surrounding the upper surface of the insulating wall.

The insulating wall cover 104 may be configured as a single cover, and may be configured as a combination of a plurality of covers.

The lower portion of the insulating wall cover 104 may be mounted on the base 100 .

The insulating wall cover 104 may protect the insulating wall and may form part of the exterior of the beverage maker.

The insulating wall cover 104 may surround the entire circumferential surface of the insulating wall, and may surround only a portion of the circumferential surface of the insulating wall.

The insulating wall cover 104 may have a side opening formed on the surface facing the water tank 51 . The extension tube of the evaporator 134 may be disposed to pass through the side opening.

Meanwhile, the water tank 51 may be spaced apart from the base 100 on the upper side of the base 100 . The water tank 51 may be spaced apart from the base 100 in a vertical direction. A space in which at least one of the compressor 131 , the water heater 53 and the water pump 52 can be accommodated may be formed between the water tank 51 and the base 100 . In addition, the water tank 51 may be spaced apart from the insulating wall in a horizontal direction.

The beverage maker may include a water tank supporter 106 for supporting the water tank 51 to be spaced apart from the base 100 . The water tank supporter 106 may be disposed on the base 100 , and may support the water tank 51 on the upper side of the base 100 to be spaced apart from the base 100 . The lower end of the water tank supporter 106 may be placed on the base 100 , and the water tank 51 may be placed on the upper portion thereof.

The feeder 3 may be disposed between the fermenter module 1 and the water tank 51 . In this case, the beverage maker can be manufactured more compactly than when the feeder 3 is located other than between the fermenter cover 114 and the water tank 51 , and the feeder 3 includes the fermenter cover 114 and the water tank 51 . ) can be protected by In addition, when each of the fermenter module 1 and the water supply module 5 is formed in a cylindrical shape, the feeder 3 disposed between the fermenter module 1 and the water supply module 5 has at least a portion of the side of the fermenter module ( 1) and by being rounded inward along the water supply module 5, it is possible to make the beverage maker compact.

The feeder 3 may be spaced apart from the base 100 in the vertical direction on the upper side of the base 100 .

The feeder 3 may include a capsule accommodating body 36 (see FIG. 3 ) having a capsule accommodating portion in which the capsule 7 is detachably accommodated, and a lid module 37 covering the capsule accommodating portion.

The lid module 37 may include a lid 38 covering the capsule receiving body 36 . The lid 38 may be slidably disposed or rotatably connected to the capsule receiving body 36 . The lid 38 may be hingedly connected to the capsule receiving body 36 .

The feeder 3 may be installed to be positioned approximately in the upper center of the beverage maker, and the user rotates the lid module 37 of the feeder 3 upward to easily mount the capsules C1, C2, and C3. , can be separated.

The beverage maker may have an accommodation space that can accommodate a plurality of parts. Here, the receiving space may be a space between the heat insulating wall and the water tank 51 in the left and right directions and between the feeder 3 and the base 100 in the vertical direction.

It is preferable that the beverage maker is accommodated in a plurality of parts in such an accommodation space, and in this case, the beverage maker may be compact. A plurality of components accommodated in this accommodation space can be protected by being surrounded by an insulating wall, a water tank 51 , a base 100 and a feeder 3 , and a center cover 66 and a rear cover 107 .

The on/off valves 313, 323, 333 installed in the feeder inlet flow paths 311, 321, 331 shown in FIG. (36) may be located below.

Meanwhile, the beverage dispensing valve 62 may be mounted on the center cover 66 . The beverage dispensing valve 62 may be mounted to protrude in the forward direction to the center cover 66 .

The center cover 66 may be formed as a front cover integral with the heat insulating wall cover 104 and the water tank supporter 106 . In this case, the front cover and the rear cover 107 are fastened to each other to form a front exterior and a rear exterior of the beverage maker.

The capsule 7 illustrated in FIG. 1 may refer to the capsules C1, C2, and C3 illustrated in FIG. 2 .

The capsule 7 may include a capsule body 71 , an upper cover 72 , and a lower cover 73 . The capsule body 71, the upper cover 72, and the lower cover 73 may be sealed from the outside so that the beverage material accommodated in the capsule does not deteriorate, or may protect the beverage material from leaking to the outside.

The capsule body 71 may form an inner space of the capsule 7 and form a side portion of the capsule 7 . The capsule body 71 is implemented as a plastic material such as PP (polypropylene), PET (polyethylene terephthalate), etc., and can effectively protect the inside without being damaged or damaged even by a predetermined impact. According to an embodiment, the capsule body 71 may be implemented with aluminum or the like.

The capsule body 71 includes an upper junction part to which the upper cover 72 is joined, a body part provided under the upper junction part to form a side surface of the capsule 7, and an opening at the lower part of the capsule 7 provided under the body part. and may include a lower joint to which the lower cover 73 is joined.

The upper junction portion and the lower junction portion may be formed to have a predetermined length in a transverse direction in order to effectively bond the upper cover 72 and the lower cover 73 to each other.

As an example, in order for the user to more easily separate the capsule from the capsule container, the outer diameter of the upper joint portion may be formed to be larger than the outer diameter of the upper end of the body portion.

According to the embodiment, in order to minimize the loading space of the capsule 7 and reduce the amount of the lower cover 73 used during manufacturing, the outer diameter of the lower junction is formed to be the same as the lower outer diameter of the body, and the inner diameter (or opening) of the lower junction diameter) may be formed smaller than the lower inner diameter or the minimum inner diameter of the body portion.

The body portion may be formed to become narrower in width from the upper part to the lower part. For example, the body portion may have a cylindrical shape in which the widths of the outer diameter and the inner diameter are narrowed from the upper part to the lower part, but this is not necessarily the case.

Since the capsule 7 according to an embodiment of the present invention is provided with a lower cover 73 so that the lower portion of the capsule 7 is more easily punctured (cut), the beverage material inside the capsule can flow out more easily.

The upper cover 72 and the lower cover 73 may be made of a material that is easily perforated by the upper perforation member and the lower perforation member of the feeder 3 . For example, the upper cover 72 and the lower cover 73 may be implemented with a soft material such as aluminum foil or polyethylene film (PE). The strength of the upper cover 72 and the lower cover 73 may be lower than that of the capsule body 71 . In this case, when the upper cover 72 and the lower cover 73 are perforated by the perforating member, not only the portion in contact with the perforating member but also the adjacent portion may be cut. In addition, when water or air is introduced through the cut-out upper cover 72 , the cut-out area of the upper cover 72 and the lower cover 73 may be wider due to water pressure. As a result, water or air can more easily flow into the inside through the upper part of the capsule 7 , and the beverage material can more easily flow out through the lower part of the capsule 7 .

A beverage material may be accommodated inside the capsule 7 . The beverage material contained in the capsule 7 may be in liquid form or in powder form. When the upper cover 72 and the lower cover 73 are cut, the beverage material may flow out into the feeder extraction passages 312 , 322 , 332 through the lower portion of the capsule 7 .

3 is a perspective view of the feeder shown in FIG. 1 ;

Referring to Figure 3, the feeder (3) is a capsule (C1), (C2), (C3) is a capsule receiving body (36) formed in which the capsule receiving portion (31, 32, 33) is removably accommodated, and the capsule It may include a lid module 37 covering the receiving portions 31, 32 and 33.

The lid module 37 may include a lid 38 covering the capsule accommodating body 36 , and a lock release unit 371 for releasing the lock of the lid 38 . The lid 38 may be slidably disposed or rotatably connected to the capsule receiving body 36 . The lid 38 may be hingedly connected to the capsule receiving body 36 .

The lead 38 may be configured as a combination of a plurality of members. For example, the lid 38 may include a lower lid 39 and an upper lid 40 . At least one of the lower lid 39 and the upper lid 40 may be connected to the capsule receiving body 36 .

When the user presses the unlocking unit 371 , the lock of the lid 38 may be released. As the locking is released, the lid 38 hinged with the capsule accommodating body 36 may rotate upwards of the capsule accommodating body 36 . As the lid rotates upward, the capsule housing provided in the capsule accommodating body 36 may be opened to the outside. The capsule housing may form a capsule accommodation space in which the capsule 7 containing the beverage material is accommodated. According to an embodiment, the capsule housing may include a capsule container 317 (refer to FIG. 7 ) forming the capsule accommodation space and a housing 362A accommodating the capsule container 317 .

On the other hand, the lead module 37 may include at least a portion of the feeder inlet passages 311, 321, 331 for supplying water to the capsule accommodation space formed in the capsule housing. For example, at least a portion of the feeder inlet passages 311 , 321 , and 331 may be formed in a space between the lower lid 39 and the upper lid 40 . In addition, the lead module 37 is connected to the feeder inlet flow passages 311, 321, 331, and the capsule receiving part 31 ( 32) (33) may include an inlet body for input. The configuration of the lead module 37 will be described in more detail with reference to FIGS. 4 to 6 .

Figure 4 is a plan view showing the inside of the lead module of the supply shown in Figure 3, Figure 5 is an exploded view of the inlet body included in the lead module shown in Figure 4, Figure 6 is a cross-sectional view of the inlet body.

4 shows a plan view of the lid module from which the upper lid 40 is removed.

Referring to FIG. 4 , the lower lid 39 may include inlet body fastening parts 391 , 392 , 393 for fastening the inlet bodies 41 , 42 , 43 to the lower lid 39 . there is. A part of the inlet body 41, 42, and 43 is accommodated in the space between the inlet body fastening parts 391, 392, 393 and the lower lid 39, and the remaining part is the inlet body fastening part 391. (392) (393) may be exposed to the outside through the upper opening.

The upper lead 40 includes the feeder inlet passages 311, 321, 331, the inlet bodies 41, 42, 43, and the inlet body fastening parts 391, 392, ( 393) may correspond to a cover (or case) that protects it.

* The configuration of the inlet body 41, 42, and 43 will be described with reference to FIGS. 5 and 6 . 5 and 6, only the embodiment of the first inlet body 41 among the inlet bodies 41, 42, and 43 will be described. 42) and the third inlet body 43 are substantially the same applicable.

The inlet body 41 may include an upper body 41A and a lower body 44 .

The upper body 41A may include a connection passage 411 connected to the feeder inlet passage 311 and a connection portion 412 connected to the inlet body connection portion 391 . As described above in FIG. 4 , the connection passage 411 of the upper body 41A may be exposed to the outside through an opening at the upper portion of the inlet body fastening part 391 , and may be connected to the feeder inlet passage 311 .

The lower body 44 includes a capsule perforation portion 441 for piercing the upper portion of the capsule 7, for example, the upper cover 72 of the capsule 7, and between the upper surface of the capsule 7 and the lower body 44, water or At least one inlet hole 442 for supplying air may be included. For example, the capsule perforation portion 441 may be implemented with at least one needle.

According to an embodiment, the lower body 44 may further include a pressing rib 443 formed on the bottom surface to press the upper surface of the capsule 7 . The pressing rib 443 may form a space in which the capsule perforation portion 441 is located.

The inlet body 41 may form an inlet flow path S1 for supplying water or air toward the capsule accommodation space of the capsule housing. The inlet flow path S1 is a connection flow path 411 formed in the upper body 41A, and is formed between the upper body 41A and the lower body 44, and water or air passing through the connection flow path 411 passes through. at least one inlet hole 442 formed in the inner flow path 413 corresponding to the space to there is.

As shown in FIG. 6 , the width of the inner passage 413 may be wider than the width of the connection passage 411 . Accordingly, water or air passing through the connection flow path 411 may spread along the width of the inner flow path 413 . Since water or air is spread from the inner flow path 413 , water or air may be uniformly supplied to the capsule accommodation space through each of the at least one inlet hole 442 formed in the lower body 44 .

Meanwhile, according to an embodiment of the present invention, the inlet body 41 may include a sealing body 47A fixed to at least one of the upper body 41A and the lower body 44 . 6, the sealing body 47A is formed to surround the side surfaces of the upper body 41A and the lower body 44, so that the upper body 41A and the lower body 44 can be fixed to each other. .

As it is formed to surround the side surfaces of the upper body 41A and the lower body 44, the sealing body 47A is provided with the upper body 41A and the lower body 44 when water or air is supplied to the inlet passage S1. ) to prevent water or air from leaking through the gap between them. The sealing body 47A may be implemented with a silicone or rubber material, but this is not necessarily the case.

The sealing body 47A may include a sealing rib 471A formed on the bottom surface. When the lid module 37 covers the capsule accommodation space, the sealing rib 471A may be in contact with the upper surface of the capsule 7 accommodated in the capsule accommodation space, and may be in contact with the capsule housing. Accordingly, when water or air is injected into the upper surface of the capsule 7, water or air leakage into the capsule housing may be prevented from leaking.

According to an embodiment, as shown in FIG. 6 , the distance H1 between the lower end of the capsule perforation part 441 from the lower end of the capsule housing is the distance between the lower end of the sealing rib 471A from the lower end of the capsule housing ( H2) may be shorter. That is, when the lower end of the sealing rib 471A contacts the upper surface of the capsule 7 , the upper portion (or the upper cover 72 ) of the capsule 7 can be easily perforated by the capsule perforation portion 441 . .

An embodiment related to the sealing rib 471A will be described in more detail below with reference to FIGS. 7 to 8 .

7 is a cross-sectional view when the lid module covers the capsule and the capsule container after the capsule is seated in the feeder, and FIG. 8 is an enlarged view of part A of the cross-sectional view shown in FIG. 7 .

First, the components included in the capsule receiving body 36 shown in FIG. 7 will be briefly described.

The capsule accommodating body 36 may include a capsule housing 36A, 36B, 36C in which a beverage material or an accommodation space for accommodating a capsule containing the beverage material is formed. The capsule housings 36A, 36B, and 36C are formed to protrude downward through the lower guides 312A, 322A, and 332A, the main flow path 2 shown in FIG. 2 and the feeder outlet flow paths 312, 322 ) (332). The lower guides (312A, 322A, 332A) may be formed with an extraction passage through which a beverage material or a mixture of water and beverage material is guided. The lower guides 312A, 322A, 332A may be part of the feeder outlet flow paths 312, 322, 332 shown in FIG. 1 . Valves (eg, check valves) 314 , 324 , 334 may be connected to the lower guides 312A, 322A, and 332A.

Depending on the embodiment, the capsule housings 36A, 36B, and 36C may include lower perforations 31A, 32A, 33A which form holes in the lower portion of the capsule 7 . For example, the lower perforations 31A, 32A, and 33A may be installed to protrude from the inner lower portion of the capsule container 317 , 327 , 337 . 7, each of the capsule containers 317, 327, 337 may be provided with a plurality of lower perforations 31A, 32A, and 33A, but this is not necessarily the case.

According to an embodiment, the capsule housings 36A, 36B, and 36C accommodate the capsule containers 317, 327, 337 and protect the exterior of the capsule containers 317, 327, 337 ( 362A), 362B, and 362C. Through-portions 363A, 363B, and 363C through which the lower guides 312A, 322A, and 332A pass may be formed in the housings 362A, 362B, and 362C.

Elastic members 316, 326, 336 may be provided between the lower portions of the housings 362A, 362B, 362C and the capsule containers 317, 327, 337. The elastic members 316, 326, 336 may elastically support the capsule containers 317, 327, 337 from the housings 362A, 362B, and 362C. For example, the elastic members 316, 326, and 336 are implemented as compression springs surrounding some of the outer circumferences of the lower guides 312A, 322A, and 332A and the outer circumferences of the through portions 363A, 363B, and 363C. can be

The elastic members 316 , 326 , 336 may be tensioned upon opening of the capsule housings 36A, 36B, and 36C to lift the capsule containers 317 , 327 , 337 .

Stoppers 315 , 325 , 335 may be disposed on the lower portions of the capsule housings 36A, 36B, and 36C to limit the degree of elevation of the capsule containers 317 , 327 , 337 . The stoppers 315 , 325 , and 335 may be implemented in a form including the above-described valves 314 , 324 , 334 . Depending on the embodiment, the valves 314 , 324 , 334 may function as the stopper.

The lid module 37 may open and close the plurality of capsule housings 36A, 36B, and 36C together. The lid module 37 may be hinged 38A, 38B connected to the capsule receiving body 36 . A hinge shaft 38A may be formed on any one of the lid module 37 and the capsule accommodation body 36 . The hinge shaft 38A may be formed horizontally on any one of the lid module 37 and the capsule accommodating body 36 . A hinge shaft connection portion 38B rotatably supported on the hinge shaft 38A may be formed on the other of the lid module 37 and the capsule receiving body 36 . The lid module 37 may be rotated up and down about the hinge shaft 38A. According to an embodiment, the hinge shaft 38A is formed to surround the outside of the hinge shaft 38A, and may further include a torsion spring for pressing the upper rotation of the lid module 37 .

Still referring to FIG. 7 , the user can seat the capsule 7 in the open capsule housings 36A, 36B, and 36C and close the lid 38 . When the lid 38 is closed to cover the capsule housings 36A, 36B, and 36C, the upper portion of the capsule 7 ( Alternatively, the upper cover 72 may be perforated. In addition, the lower cover 73 of the capsule 7 may be perforated by the lower perforations 31A, 32A, 33A included in the capsule housings 36A, 36B, and 36C. As the upper cover 72 and the lower cover 73 are perforated, a flow path through which the beverage material inside the capsule 7 is extracted may be formed.

8, the capsule housing 36A includes a sealing rib insertion body 364A into which the sealing rib 471A is inserted when the lid module 37 covers the capsule housings 36A, 36B, and 36C. can do. The sealing rib 471A may include an outer peripheral contact portion 472A in contact with the sealing rib insertion body 364A. Further, the sealing rib 471A may include a bottom contact portion 473A that is in contact with the body portion 71 of the capsule 7 . Specifically, the body portion 71 of the capsule 7 may include a accommodating body 711 having an inner space for accommodating the beverage material, and a contact body 712 formed in the accommodating body 711 . In this case, the lower contact portion 473A may contact the upper surface of the contact body 712 .

As the sealing rib 471A comes into contact with the sealing rib insertion body 364A and the contact body 712 of the capsule 7, the second space S2 and the third space S3 inside the sealing rib 471A and , the fourth space S4 between the sealing rib 471A and the capsule housing 36A may be shielded from each other.

Water passing through the inlet hole 442 of the inlet passage S1 may be guided to the second space S2 . At this time, when the size of the perforation formed in the upper portion of the capsule 7 is small, a portion of water may leave the second space S2 and flow into the third space S3 . In this case, since the third space S3 and the fourth space S4 are shielded by the sealing rib 471A, a phenomenon in which water introduced into the third space S3 leaks into the fourth space S4 is prevented can do. Accordingly, the cleanliness of the capsule housing 36A can be maintained.

According to an embodiment, the capsule receiving body 36 may further include a capsule sealing member 365 mounted on the capsule housing 36A to seal between the capsule housing 36A and the capsule 7 . In this case, as shown in FIG. 8 , the upper surface of the contact body 712 of the capsule 7 is in contact with the lower contact portion 473A of the sealing rib 471A, and the lower surface is in contact with the capsule sealing member 365 . there is. For example, even if the third space (S3) and the fourth space (S4) are not completely shielded by the sealing rib (471A) so that water or beverage material partially leaks into the fourth space (S4), the capsule sealing member 365 is It is possible to prevent leaked water or beverage material from moving between the capsule housing 36A and the capsule 7 .

Like the sealing body 47A, the capsule sealing member 365 may be implemented with a silicone or rubber material.

9 is a cross-sectional view when the capsule container is opened and the capsule is withdrawn from the capsule container, and FIG. 10 is an enlarged view of part B of the cross-sectional view shown in FIG.

Referring to FIGS. 9 and 10 , after the beverage material in the capsule 7 flows out together with water into the dispenser extraction passages 312 , 322 , 332 , the user opens the lead module 37 to open the capsule 7 . can be removed from the capsule housings 36A, 36B, and 36C.

As described above, the user can release the lock of the lid 38 by pressing the unlocking unit 371 of the lid module 37 . As the locking is released, the lid 38 may be opened by rotating upward about the hinge shaft 38A.

When capsule housings 36A, 36B, 36C are composed of housings 362A, 362B, 362C and capsule containers 317, 327, 337, capsule containers 317, 327, 337 Upon removal of the capsule 7 accommodated in the capsule 7 , there is a possibility that water or beverage material existing inside the capsule 7 or water accumulated on the upper surface of the capsule 7 may leak to the outside. For example, when the spilled water or beverage material enters the gap between the first housing 362A and the first capsule container 317, the user may use the first capsule container 317 to remove the introduced water or beverage material. You may experience the inconvenience of having to separate the

Referring to FIG. 10 , the capsule receiving body 36 may further include a housing sealing member 319 disposed between the inner circumferential surface of the capsule housing 36A and the outer circumferential surface of the capsule container 317 . The housing sealing member 319 shields the fifth space S5 formed between the inner circumferential surface of the capsule housing 36A and the outer circumferential surface of the capsule container 317 from the outside, thereby protecting the interior of the capsule housing 36A. can be sealed

Like the capsule sealing member 365 and the sealing body 47A, the housing sealing member 319 may be implemented with a silicone or rubber material. Each of the capsule sealing member 365 and the housing sealing member 319 may have a ring shape, but is not limited thereto.

On the other hand, the flow paths such as the main flow path 2, the inlet flow path 4, the beverage outlet flow path 61, and the air injection flow path 81 described in the present invention may be formed by a hose or tube through which a fluid can pass. , It is also possible to consist of a plurality of hoses or a plurality of tubes that are continuous in the longitudinal direction, and of course it is also possible to include two hoses or tubes disposed with other components such as a control valve therebetween.

The above description is merely illustrative of the technical spirit of the present invention, and various modifications and variations will be possible without departing from the essential characteristics of the present invention by those skilled in the art to which the present invention pertains.

Therefore, the embodiments disclosed in the present invention are not intended to limit the technical spirit of the present invention, but to explain, and the scope of the technical spirit of the present invention is not limited by these embodiments.

The protection scope of the present invention should be construed by the following claims, and all technical ideas within the scope equivalent thereto should be construed as being included in the scope of the present invention.

Claims (14)

Pump;
an inlet passage connected to the pump and through which a fluid flows by the pump;
a fermenter assembly having an internal space;
a beer production pack accommodated in the inner space;
A material receiving unit in which the beer material is embedded in the capsule is mounted;
a housing into which the material receiving part is inserted and accommodated; and
A lead module including an upper perforating part for piercing the upper part of the capsule and an inlet body connected to the inlet flow path, and covering the material receiving part;
In the inlet body,
A pressing rib is formed that presses the upper surface of the capsule and forms a space in which the upper perforation is located,
The lead module is
Further comprising a sealing rib disposed to surround at least a portion of the outer circumference of the pressing rib on the inlet body and in contact with the housing,
Beer making equipment. The method of claim 1,
The pressing rib is formed to protrude in a ring shape from the lower surface of the inlet body.
Beer making equipment. According to claim 1,
The upper perforation portion is spaced apart from the pressing rib, beer manufacturing apparatus located inside the pressing rib. According to claim 1,
The upper perforation includes at least one needle,
Beer making equipment. The method of claim 1,
The inlet body is
a connection passage connected to the inlet passage;
an inner flow path through which the fluid passing through the connection flow path flows, and
and at least one inlet hole communicating the inner flow path and the material accommodating part, and through which a fluid passes,
Beer making equipment. 6. The method of claim 5,
The inlet hole is located inside the pressing rib,
Beer making equipment. 6. The method of claim 5,
The width of the inner passage is formed wider than the width of the connection passage,
Beer making equipment. The method of claim 1,
Further comprising an outlet passage connecting the material receiving part and the beer production pack,
The capsule is located between the inlet body and the outlet flow path,
Beer making equipment. The method of claim 1,
The sealing rib prevents air from leaking to the outside,
Beer making equipment. 2. The method of claim 1
The distance between the lower end of the housing and the lower end of the upper perforation,
shorter than the distance between the lower end of the housing and the lower end of the sealing rib,
Beer making equipment. delete delete delete delete

Images