JP3536218B2 - Supply pressure adjusting device for carbon dioxide gas in raw beer storage barrel - Google Patents

Description

Description: BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for storing charcoal in raw beer storage barrels.
The present invention relates to an acid gas supply pressure adjusting device. 2. Description of the Related Art Raw gas stored in a keg is supplied with carbon dioxide gas in advance and dissolved therein. When selling raw bead, carbon dioxide gas is further added to the keg. The raw beer is filled, extruded, cooled down through a cooler, and distributed to a mug or the like. However, a pressure adjusting device for carbon dioxide is provided between the carbon dioxide storage tank and the raw beer storage barrel.
The pressure of the carbon dioxide gas is adjusted by adjusting the lever of the pressure adjusting device according to the temperature. However, the lever is manually operated in a normal device. FIG. 5 schematically shows a conventional means for introducing carbon dioxide into a raw beer storage barrel, in which a carbon dioxide storage tank 51 and a pressure regulator 52 for supplying carbon dioxide are connected. The pressure adjusting device 52 and the beer storage barrel 53 are connected. The pressure adjusting device 52 includes a lever-5.
2 ₁ Adjust the elastic force of the spring or diaphragm (not shown) in the pressure adjusting device 52 according to the temperature of the surroundings by, has as causing the strength to open and close the valve for supplying the carbon dioxide. Normally, the carbon dioxide gas is always supplied from the storage tank 51 into the vial storage barrel via the pressure adjusting device 52, so that the carbon dioxide gas is constantly exposed to the liquid surface, so that it is easy to continue dissolving in the liquid. On the other hand, if the pressure of the carbon dioxide gas is too low, the carbon dioxide gas previously dissolved in the raw beer foams, resulting in a so-called deflated beer. [0004] Therefore, when the supply of carbon dioxide is very important, but the pressure regulating device 52 is lever -52 ₁ is provided so as to correspond to the supply pressure of the carbon dioxide gas, usually depending on the temperature Manual adjustment. [0005] For this reason, since the lever provided in the carbon dioxide gas supply pressure regulator must be adjusted each time depending on the ambient temperature, it is extremely troublesome. Usually, it is not so much adjusted by the lever. Therefore, it is desirable that the amount of carbon dioxide dissolved in the raw beer solution is constant, but it is necessary to avoid a change in the amount of carbon dioxide dissolved in advance depending on the pressure of the supplied carbon dioxide. However, it has been pointed out that the amount of dissolved carbon dioxide in the raw beer brought into the mug through the cooler differs, and the taste of the raw beer is not constant. That is, the amount of dissolved carbon dioxide in the raw beer solution changes with the passage of time, and it is impossible to provide a constant taste. [0006] The present invention relates to a method for storing carbon dioxide gas in a raw beer storage barrel.
Respect of the supply pressure regulator and, more, Namabi are reserved in the barrel - aims to temperatures of Le solution, to provide a pressure adjusting device for automatically adjusting the pressure of the carbon dioxide gas to be supplied It is assumed that. The present invention employs the following structure to achieve the above object. That is, in the present invention, the hollow portion of the pressure adjusting device body is divided into two rooms A and B by a partition, and the inlet and the outlet of the carbon dioxide gas in the room A, and
Room B is provided with a shaft extending from the room B to the room A through the partition wall and having an inlet and an outlet for the raw beer liquid.
The shaft is resiliently held by a heat-sensitive spring inside, and the end of the shaft is fitted with a valve sheet through a valve cone in the room A, and the heat-sensitive spring is placed in a raw beer storage barrel. The elasticity is increased or decreased by sensing the temperature of the liquid stored in the raw beer , and the shaft is slid accordingly, thereby changing the distance between the valve sheet at the tip of the shaft and the valve cone. Carbon dioxide into a raw beer storage barrel
Raw bead storage characterized by adjusting the supply pressure of the raw material
Supply pressure adjusting device for carbon dioxide gas in the storage barrel . According to the present invention, there is provided a gaseous carbonate according to the temperature of a raw bead solution.
This is a device for automatically adjusting the supply pressure of the raw material . In particular, a temperature-sensitive spring, that is, a spring using a shape memory alloy (coil spring, disc spring, etc.) is used to sense the temperature of the raw bead liquid. The shaft is slid by changing the spring constant or the shape of the spring, and the opening and closing between the valve sheet and the valve cone provided at the tip of the shaft is adjusted to automatically adjust the supply pressure of carbon dioxide gas. . That is, depending on the temperature of the raw beer solution , carbon dioxide
The supply pressure of the scan is to automatically be changed, raw
A required amount of carbon dioxide is automatically supplied in accordance with the temperature of the raw beer solution in the beer storage barrel, and carbon dioxide at a desired pressure is introduced into the barrel. Therefore, the dissolved amount of carbon dioxide dissolved in the raw beer solution is kept substantially constant, and the taste of the raw beer itself is always constant. The present invention will be described in more detail with reference to the following examples. FIG. 1 is a schematic view of the carbon dioxide gas in the raw beer storage barrel of the present invention.
Ru conceptual diagram der supply pressure regulator. In the figure, 1 is carbon dioxide
And is divided into two rooms A and B by a partition wall 2. A shaft 3 is penetrated into the room B, and a projection 4 formed on the shaft 3 is used as a locking portion, and a spring 5 formed of a shape memory alloy is used.
Is fitted on the shaft 3. The shaft 3 protrudes into the room A through the partition 2, and a valve sheet 8 is fixed to the tip of the shaft 3 through a nozzle 7 serving as a valve cone 6. Further, Barubuko room A forms a nozzle 7 mentioned above - are bisected by emissions 6 is a room A ₁ and the room A _2, the inlet 9 accommodation A ₁ side of the carbon dioxide gas to be supplied, the outlet 10 the accommodation provided a ₂ side. On the other hand, the room B is provided with an inlet 11 and an outlet 12 for the raw bead liquid . In the figure, 13 is a primary pressure reducing regulator, and 14 is a flow rate regulating valve. Other reference numerals are the same as those in FIG. Now, in the room A side, carbon dioxide to be supplied
From the inlet 9 and through the nozzle 7 to the outlet 1
It will go outside from 0. On the other hand, room 11 has entrance 11
The raw bead liquid is fed in and flows out from the outlet 12. Then, the raw bead liquid comes into contact with the spring 5 in the room B, and the spring 5 is made of a heat-sensitive material. Therefore, the spring constant or the shape of the spring 5 depends on the temperature of the raw bead. And the force that pushes the shaft 3 changes to provide resilience. Here, the pressure in the room A ₁ is P ₁ (= constant), the pressure in the room A ₂ is P ₂ , and the pressure in the room B is P ₃
And Now, F ₂ is applied to the shaft 3 by the spring 5.
Works, while the pressures P ₁ and P _{2 in} rooms A ₁ and A _{2
According to 2} , the pressure receiving area of each room × the total force F of the pressures
₁ will work in opposition to the F ₂ described above. The carbon dioxide supply pressure adjusting device of the present invention comprises:
A nozzle 7 by the relationship of the size of the F ₁ and F ₂ in accordance with the shaft 3 Barubushi - be one interval between bets 8 is opened and closed, the spring 5 is Namabi - F by sensing Le liquid temperature ₂ size is changed, thereby adjusts the pressure in the room a _2, resulting in Namabi - according le of liquid temperature, the pressure of the carbon dioxide gas flowing out is that a can be adjusted automatically. Therefore, the pressure of the supplied carbon dioxide gas can be automatically changed in accordance with the temperature of the raw beer , and the carbon dioxide dissolved in the raw bead liquid can be automatically changed.
Thus, the amount of heat can be kept constant at all times. 2 and 3 show the supply pressure of carbon dioxide gas according to the present invention.
It is a sectional view showing a more specific embodiment of the force adjusting device ,
Figure 2 is a sectional view of when a force F ₂ of the heat-sensitive spring is smaller than F _1, FIG. 3 is a sectional view in the state of F ₁ <F _2. In the figure, reference numeral 21 denotes a main body of a carbon dioxide gas supply pressure adjusting device, and its hollow portion is divided into two chambers A and B by a partition wall 22. The side covers 23 and 24 are screwed into the ends of the rooms A and B, respectively, so that the rooms A and B are partitioned. In the room A, an inlet 25 for carbon dioxide is formed on the side cover 23 and an outlet 26 is formed on the side of the room A. On the other hand, the room B is provided with an inlet 27 for the raw bead liquid , and an outlet 28 is provided facing the side of the room B. Each of these inlets and outlets is provided with a female screw and is connected to a pipe or the like (not shown). Now, a through hole 29 is formed in the center of the side cover 24 on the room B side, and a shaft 30
Is inserted, and a heat-sensitive spring 32 made of a shape memory alloy is fitted between the projecting peripheral portion 31 formed on the shaft 30 and the inner end of the side cover 24, and both ends thereof are fixed, and the shaft 30 is elastically resilient. The property is given. The shaft 30 penetrates through the partition wall 2 and protrudes toward the room A. A thin shaft 33 is formed at the tip of the shaft 30, and a portion of the shaft 33 passes through a play hole 35 formed in the valve cone 34. And it is growing further. The position of the valve cone 34 is specified by the step 36 in the room A, and the position is fixed by the tip of the side cover 23. The tip of the shaft 33 extends through the valve cone 34 as described above, and is located inside the side cover 23, and includes a valve sheet 37 and a valve casing 38 for supporting and fixing the valve sheet 37. Screwed to the tip. Barubuko - down 34 has been made to bisects room A further room A ₁ and the room A _2, Barubushi - DOO 37, Barubuko -
A gap S is formed between the cylindrical portion 39 formed around the play hole 35 of the pin 34 and the cylindrical portion 39 or between the cylindrical portion 39 and the cylindrical portion 39. On the other hand, the other end of the shaft 30 is outside the side cover 24 and an adjusting nut 40 is screwed thereto. In the drawing, reference numerals 41 denote O-rings, which prevent fluid from leaking from the contact surfaces of the respective members. Now, on the room A side, carbon dioxide to be supplied
Scan enters from the inlet 25 of the room A ₁ side, so that the step out from the room A ₂ side of the outlet 26. On the other hand, the raw bead liquid is fed into the room B from the inlet 27 and flows out from the outlet 28. Then, Namabi - liquid Le is in contact with the spring 32 in the room B, because the spring 32 is made of a thermally sensitive material, the Namabi - spring 32 resiliently forces the liquid temperature of the Le (F ₂₎ Is given. [0020] Figure 2 is a spring 32 Namabi - although those given the power of F ₂ to the shaft 33 in accordance with the liquid temperature in Le,
Shaft 3 by pressure in room A ₁ and room A ₂
3 is a cross-sectional view when the relationship between the force F ₁ acting on the shaft 3 and the force F ₁ satisfies the relationship of F ₁ ≧ F ₂ , wherein the shaft 33 moves to the room B side, The tubular portion 39 comes into contact with the tubular portion 39 to cut off the flow path of the carbon dioxide gas . On the other hand, FIG. 3 is a sectional view when each of the above-mentioned forces acting on the shaft 33 satisfies F ₁ <F ₂ , wherein a gap S is formed between the valve sheet 37 and the cylindrical portion 39. It becomes. Accordingly, the carbon dioxide gas in the room A (A ₁ , A ₂ ) is supplied through the gap S from the outlet 26 into the raw beer storage barrel.
Re is a shall. In other words, the raw beer on the room B side
The supply pressure of the carbon dioxide gas on the room A side can be changed depending on the difference in the temperature of the liquid . Therefore, the raw bead depends on the temperature of the raw bead.
Thus, the pressure of the carbon dioxide gas supplied into the storage barrel can be automatically changed, so that the amount of carbon dioxide dissolved in the raw beer solution can be always kept constant. FIG. 4 is a sectional view of a second embodiment of the carbon dioxide supply pressure adjusting device according to the present invention. The precedent of the point of difference between the supply pressure regulator is configured pressure regulator apparatus main body by the two-split members 21 _1, 21 _2, member 21 _1, 2
1 to ₂ of the flange 21 _3, 21 ₄ is obtained by fixing with bolts 43 and nuts 44 across the peripheral edge of the diaphragm 42, the diaphragm 42 is attached surrounding around the shaft 30. The right side of the diaphragm 42 is connected to the outside air. In this embodiment, the change in the pressure of the carbon dioxide gas can be smoothly changed in accordance with the change in the liquid temperature of the raw beer . The present invention provides a raw bead storage having the above structure.
This is a pressure adjusting device for supplying carbon dioxide gas into the storage barrel. Since a spring using a shape memory alloy is used, the spring constant of the spring changes depending on the liquid temperature of the raw bead. Thus, the pressure of carbon dioxide can be adjusted. For this reason, the amount of carbon dioxide dissolved in the raw beer solution can always be automatically controlled to be constant.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 shows carbon dioxide gas in the raw beer storage barrel of the present invention.
It is a conceptual diagram of the supply pressure adjustment apparatus of FIG. FIG. 2 is a sectional view showing a more specific first embodiment of the carbon dioxide gas supply pressure adjusting device according to the present invention, in which a spring is contracted in accordance with the liquid temperature of the raw bead . FIG. FIG. 3 is a cross-sectional view when the spring of the carbon dioxide supply pressure adjusting device shown in FIG. 2 is extended according to the liquid temperature of the raw beer . FIG. 4 is a sectional view of a second embodiment of the carbon dioxide supply pressure adjusting device according to the present invention. FIG. 5 is a schematic view of a conventional means for mixing and dissolving carbon dioxide gas in a raw beer storage barrel. [Description of Signs] A, A ₁ , A ₂ , B {pressure control device room, S} clearance between valve sheet and cylinder, 1} carbon dioxide gas supply pressure control Main body of device, 2mm partition, 3mm shaft, 4
{Protrusions formed on the shaft, 5} Spring formed of shape memory alloy, 7 # Nozzle, 8 # Valve sheet, 9 # Inlet of carbon dioxide supplied to room A,
10 cm outlet of carbon dioxide supplied to room A, 11 cm
Inlet for raw beer liquid supplied to room B, 12 ° outlet for raw bead liquid supplied to room B, 13 ° primary pressure reducing regulator, 14 ° flow control valve, 21, 21
₁ , 21 ₂本体 Main body of carbon dioxide supply pressure regulator, 2
1 _3, 21 ₄ ‥‥ flange of the supply pressure regulator body member of carbon dioxide, 22 ‥‥ carbon dioxide hollow portion of the partition wall in the supply pressure control device, 23, 24 ‥‥ side cover -, 25 ‥‥ room A Of carbon dioxide gas at room 26cm in room A
Outlet for carbon dioxide gas , 27 ° inlet for raw beer liquid in room B, 28 ° outlet for raw bead liquid in room B,
29 ‥‥ side cover center through hole, 30 、, 33 ‥‥ shaft, 31 ‥‥ shaft periphery, 32 ‥‥ heat sensitive spring, 34 ‥‥ valve cone, 35 ‥‥ valve cone A play hole, a 36.degree. Step in the room A, a 37.degree. Valve sheet, a 38.degree. Valve casing, a cylindrical portion formed around a play hole of a 39.degree.
41 ‥‥ O-ring, 42 ‥‥ diaphragm, 43 ‥‥
Bolt, 44 ‥‥ nut, 51 ‥‥ carbon dioxide storage tank, 52 ‥‥ pressure regulator for carbon dioxide supply, 52 ₁ ‥
レ Lever provided in the pressure regulator, 53 ‥‥ beer storage barrel, 54 ‥‥ cooler, 55 ‥‥ mug.

──────────────────────────────────────────────────続 き Continuation of the front page (56) References JP-A-2-76987 (JP, A) JP-A-59-69575 (JP, A) JP-A-63-225800 (JP, A) JP-A-2- 187582 (JP, A) JP-A-3-14980 (JP, A) JP-A-62-161698 (JP, U) JP-A-63-166991 (JP, U) JP-A-1-176282 (JP, U) (58) Field surveyed (Int. Cl. ⁷ , DB name) B67D 1/00 F16K 31/70 G05D 16/00

Claims (1)

(57) Patent Claims 1. A two chambers A hollow portion of the supply pressure regulator body at the partition walls of carbon dioxide gas, and is B, the room A carbon dioxide gas
The room B is provided with an inlet and an outlet for the raw bead liquid , and the room B is provided with a shaft extending from the room B to the room A through the partition wall. The shaft is resiliently held, and the end of the shaft is provided with a valve sheet through a valve cone in the room A, and the heat-sensitive spring is placed in a raw beer storage barrel.
Senses the temperature of the raw beer liquid stored in the tank and increases or decreases the resilience, slides the shaft accordingly, and changes the distance between the valve sheet at the tip of the shaft and the valve cone. by Namabi - it is characterized in that by adjusting the supply pressure of the carbon dioxide gas to Le storage barrels within Namabi - to Le storage barrels in carbon dioxide
Supply pressure regulator.