JPH07132994A - Device for controlling pressure of feed fluid - Google Patents

Abstract

PURPOSE:To automatically control the pressure of carbon dioxide being fed relative to the temperature of draft beer stored in a barrel by a method wherein temperature of a second fluid is sensed by a heat-sensitive spring so that a ring fitted on a pipe is axially displaced by virtue of the change of spring constant or shape thereby sliding a valve shaft. CONSTITUTION:A hollow section is provided in a body 1 of a pressure control device and a pipe 2 is passed through the section, which section is divided into a room A in communication with the atmosphere through a ring 3 and rooms B1-B3. A first fluid flows into the room B3 from an inlet port 9 and flows through a nozzle 7 and is discharged to the outside from an oultet port 10. On the other hand, a second fluid is sent into the pipe 2 and, in the room A, the heat of the fluid is transferred to a heat-sensitive spring 4, so that the spring constant or the shape thereof changes, thereby changing a force pusing a valve shaft 5. If the force has become larger than a force which moves the shaft 5, the shaft 5 is moved to the right side so that the valve is closed and the pressure is controlled, whereby feed pressure is automatically controlled according to the liquid temperature of draft beer to keep the volume of carbon dioxide constant.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a pressure adjusting device for a supply fluid, and more particularly to a pressure adjusting device used for supplying carbon dioxide gas into a raw beer storage barrel.

[0002]

2. Description of the Related Art Carbon dioxide gas is previously supplied to and melted in a raw beer stored in a barrel, and when the raw beer is sold, the carbon dioxide gas must be further filled in the barrel. The raw beer is extruded, cooled through a cooler, and distributed to jugs and the like. However, a carbon dioxide pressure adjusting device is provided between the carbon dioxide storage tank and the raw beer storage barrel,
The pressure of carbon dioxide gas is adjusted by adjusting the lever of the pressure adjusting device depending on the temperature, but the normal device is to manually operate the lever.

FIG. 8 schematically shows a means for introducing carbon dioxide gas into a conventional raw beer storage barrel, in which a carbon dioxide gas storage tank 51 and a pressure adjusting device 52 for supplying carbon dioxide gas are connected. The pressure adjusting device 52 and the beer storage barrel 53 are connected to each other. The pressure adjusting device 52 includes a lever 5
The elastic force of a spring or a diaphragm (not shown) in the pressure adjusting device 52 is adjusted by 2 ₁ according to the ambient temperature, and the opening and closing of the valve for supplying carbon dioxide gas is made stronger and weaker. Normally, carbon dioxide gas is constantly supplied from the storage tank 51 into the beer storage barrel through the pressure adjusting device 52, and since it is always exposed to the liquid surface, it becomes easy to continue to dissolve 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 will foam, resulting in a so-called stray 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 It is supposed to be adjusted manually.

[0005]

Therefore, since the lever provided in the carbon dioxide gas supply pressure adjusting device has to be adjusted each time depending on the ambient temperature, it is extremely troublesome, and normally it is not so much. It is not adjusted by lever. Therefore, it is desirable that the amount of carbon dioxide gas dissolved in the raw beer liquid is constant, but it is avoided that the amount of dissolved carbon dioxide gas is changed by the pressure of the supplied carbon dioxide gas. However, it has been pointed out that the amount of dissolved carbon dioxide gas in the green beer introduced into the jug through the cooler is different and the taste of the green beer is not constant. That is, the present situation is that the amount of carbon dioxide gas dissolved in the raw beer liquid changes with the passage of time, and a constant taste cannot be provided.

The present invention relates to a pressure adjusting device for supplying carbon dioxide gas into, for example, a raw beer storage barrel, and more specifically, it relates to the temperature of the raw beer liquid stored in the barrel.
It is an object of the present invention to provide a pressure adjusting device for automatically adjusting the pressure of supplied carbon dioxide gas.

[0007]

The present invention has the following features to attain the object mentioned above. That is, according to the present invention, a movable ring that divides into a chamber A and a chamber B is fitted in the hollow portion of the main body, and a heat-sensitive spring is mounted in the chamber A to elastically support the ring, and the heat-sensitive type A structure is provided in which a spring is provided with a flow path for transmitting the liquid temperature of the second fluid, and the chamber B is divided into chambers B ₀ and B ₁ by a valve shaft facing the ring and elastically supported by the spring on the opposite side. And the chamber A is an atmospheric pressure chamber, and B ₀ is located in the center of the hollow portion.
A nozzle is formed in the chamber toward the valve shaft from the main body, and a seat portion is provided on the valve shaft so as to face the nozzle, and the chamber is further divided into a B ₂ chamber and a B ₃ chamber. A pressure adjusting device for a supply fluid, characterized in that an inlet and an outlet for a fluid are provided, a second fluid is passed through the flow path, and a temperature of the second fluid is transmitted to the heat-sensitive spring. Is.

Specifically, the hollow portion is divided into an A chamber and a B chamber by a main body having a hollow portion, a pipe penetrating the main body, and a ring externally inserted in the pipe. Is the atmospheric pressure chamber, and a heat-sensitive spring is attached externally to the pipe in the A chamber to elastically support the ring, and in the B chamber it is elastically supported by the spring on the opposite side to the ring. The B chamber is divided into B ₀ and B ₁ chambers with a valve shaft externally attached to the pipe, and a nozzle is formed from the main body in the B ₀ chamber located at the center of the hollow part and faces the nozzle. The valve shaft is provided with a seat portion and is further divided into a B ₂ chamber and a B ₃ chamber, and an inlet and an outlet for the first fluid are provided with this nozzle sandwiched between the chamber and the pipe. The temperature of the second fluid is passed through the second fluid and There is provided a pressure regulator of the feed fluid which is transmitted to the spring.

More specifically, usually, a diaphragm is mounted between the hollow part of the main body and the ring, and the ring is axially moved by the pressure of the first fluid flowing into the B ₁ chamber and the B ₂ chamber. The gap between the seat and the nozzle mounted on the valve shaft is slid or the ring is slid in the axial direction of the pipe by the pressure of the first fluid while maintaining the airtightness between the hollow part of the main body and the ring. Is adjusted.

[0010]

The present invention is an apparatus for automatically adjusting the outflow pressure of the first fluid in accordance with the temperature of the second fluid, and particularly uses a heat-sensitive spring such as shape memory alloy, shape memory resin, bimetal or the like. Springs (coil springs, disc springs, etc.)
The temperature of the second fluid is sensed to displace the ring externally attached to the pipe in the axial direction by the change of the spring constant or the shape, and the valve shaft is slid along with this, and this valve shaft is equipped with By opening and closing the valve sheet and the nozzle, the pressure at which the first fluid flows out is automatically adjusted.

That is, the pressure at which the first fluid flows out is automatically changed according to the temperature of the second fluid. Therefore, for example, when supplying carbon dioxide gas into the raw beer storage barrel,
The required amount of carbon dioxide gas is automatically supplied according to the temperature of the liquid in the barrel, and the carbon dioxide gas of the desired pressure is introduced into the barrel. Therefore, in this example of live beer,
The amount of carbon dioxide gas dissolved in the liquid solution is kept substantially constant, and the taste of the raw beer itself is always constant.

Moreover, the heat-sensitive spring and the second fluid are not in direct contact with each other. Since the heat-sensitive spring functions without affecting the properties of the second fluid at all, the heat-sensitive spring is actuated by the operation of the heat-sensitive spring. For example, when supplying carbon dioxide gas into a raw beer storage barrel, a pressure adjusting device for accurately and automatically adjusting the pressure of the supplied carbon dioxide gas is provided.

If, for example, a complicated shape such as a spring is present in the flow passage of the beer, the carbon dioxide gas of the beer is turbulent and is easily separated. When it adheres to the passage, it is difficult to remove and clean it. However, in the present invention, since the heat-sensitive spring for providing the pressure adjusting function and the beer liquid do not come into contact with each other, such a defect does not exist at all. It has become.

[0014]

EXAMPLES The present invention will now be described in more detail with reference to examples. FIG. 1 is a conceptual diagram of a pressure adjusting device for a supply fluid of the present invention, which is an example used as a device for supplying carbon dioxide into a raw beer storage barrel. In the figure, reference numeral 1 is a main body of a pressure adjusting device for a supply fluid, a hollow portion is provided in the main body 1, and a pipe 2 penetrates through the hollow portion. And
A hollow portion is divided into an A chamber and a B chamber by a ring 3 externally inserted in the pipe 2.

And, while the chamber A is continuous with the atmospheric pressure,
In the room A, a heat-sensitive spring 4 externally attached to the pipe 2
Is mounted to elastically support the ring 3. On the other hand, in the B chamber, the valve shaft 5 is externally inserted into the pipe 2 so as to face the ring 3, and thereby divided into the B ₀ chamber and the B ₁ chamber, and the spring 6 is attached to the B ₁ chamber side so that the valve shaft 5 is Sustained support. On the other hand, in the B ₀ chamber, the substrate 1
An annular nozzle 7 and a sheet portion (not shown) facing the nozzle 7 are mounted in the hollow portion of the chamber to further divide the B ₀ chamber into a B ₂ chamber and a B ₃ chamber. The outer edge of the valve shaft 5 is slidable with respect to the base body 1, and the central chamber B ₂ and the outer chamber B ₁ are communicated with each other through the play hole 8. Then, the B ₃ chamber has the first fluid inlet 9, B ₂
The chamber is provided with an outlet 10, while the pipe 2 will be flushed with a second fluid. In the figure, 11 is a primary depressurization regulator, 12 is a barrel connecting joint, and other reference numerals are the same as those in FIG.

Now, the first fluid La to be supplied enters the B ₃ chamber through its inlet 9, passes through the nozzle 7, and exits from the outlet 10. On the other hand, the pipe 2 receives the second fluid Lb from the inlet 2 ₁ and flows out from the outlet 2 ₂ . The liquid temperature of the second fluid Lb is transmitted to the spring 4 in the chamber A, and the spring 4 is made of a heat-sensitive material. Therefore, depending on the liquid temperature of the second fluid Lb, the spring constant of the spring 4 or the spring Changes its shape, which changes the force pushing the valve shaft 5 to give elasticity. The pipe 2 is made of stainless steel here, but it is preferable that its wall thickness is as thin as possible in order to improve heat conductivity. Further, it is preferable to use a material having a higher heat conductivity than stainless steel, for example, aluminum, copper, iron or the like because the reaction rate with respect to temperature becomes faster.

Here, the pressure in the chamber A is P ₀ (atmospheric pressure), and B is
If the pressure of ₁ .about.B ₃ chamber and each P ₁ to P _3, the pressure of the _first chamber and B ₂ rooms B in communication with遊孔8 becomes P ₁ = P _2. If the force of the spring 4 is F ₄ and the force of the spring 6 is F ₆ , the forces involved in pressure adjustment, that is, the force for moving the valve shaft 5 are P ₁ , F ₄ , and F ₆ . As for this P ₁ , the force F ₁ = P involved in pressure regulation
₁ × S ₁ (pressure receiving area of the ring 3). Therefore, F ₄
When> F ₆ + F ₁ , the shaft 5 moves to the right and the valve opens, while when F ₄ <F ₆ + F ₁ , the shaft 5 moves to the left and the valve closes. , The pressure will be adjusted here.

In the pressure adjusting device of the present invention, the gap between the nozzle 7 and the sheet is opened and closed depending on the magnitude of each of these forces applied to the ring 3, and the spring 4 is the second.
The size of F ₄ is changed by sensing the liquid temperature of the fluid, and thereby the pressure of the B ₂ chamber is adjusted, resulting in the second
The pressure of the first fluid La flowing out can be automatically adjusted according to the liquid temperature of the fluid Lb.

Therefore, if this device is used as a pressure adjusting device for the carbon dioxide gas (La) supplied into the raw beer storage barrel, the carbon dioxide gas supplied according to the liquid (Lb) temperature of the raw beer. This means that the pressure of (La) can be automatically changed, so that the amount of carbon dioxide gas (La) dissolved in the liquid (Lb) can be always kept constant.

2 and 3 are sectional views showing a more concrete embodiment of the pressure adjusting device for the supply fluid of the present invention. FIG. 2 is a state in which the nozzle and the seat portion are open, and FIG. Shows the state in which the space between the nozzle and the sheet is closed.

In the figure, reference numeral 21 denotes a main body of the pressure adjusting device for the supply fluid, and in this example, a hollow portion is constituted by a pair of cylinders 21 ₁ and 21 ₂ . Then, the side cover -23 the tubular member 21 ₁ side with an adjustable lever 22 is the one of the cylindrical body 21 is a _two-side O- ring side cover -25 of maintaining the airtightness cylindrical at 24 Each is screwed on.

The pipe 2 is attached to the covers 23 and 25 on both sides.
6 is penetrated. This pipe 26 is fitted a ring 27, and the diaphragm 28 between the ring 27 and the cylindrical body 21 is stretched, the hollow portion is divided into the A chamber and chamber B, the cylindrical body 21 ₁ side The hollow portion, that is, the chamber A, is continuous with the atmosphere, and the heat sensitive spring 29 is externally inserted into the pipe 27 to press the ring 27.

On the other hand, in the B chamber of the cylindrical body ₂₁₂ side, the leading end opposite the ring 27 valve shaft 30 to the pipe 27 is fitted, the rear end a tubular shape O- ring 2
It is in contact with the side surface cover 25 via the airtight member 4 with airtightness. The valve shaft 30 divides the chamber B into a chamber B _{0 and a} chamber B ₁ on the side of the side cover 25, and these chambers are connected to the valve shaft 30 with a play hole 31. A spring 32 is externally inserted into the pipe 27 on the side of the B ₁ chamber to press and support the valve shaft 30. An annular nozzle 33 is provided in the B ₀ chamber located in the center of the tubular body 21 and is further divided into a B ₂ chamber (central chamber) and a B ₃ chamber. The first fluid is sandwiched by the nozzle 33. An inlet 34 (B ₂ chamber) and an outlet 35 (B ₃ chamber) are provided. In the figure, 36 is a seat portion provided on the surface of the valve shaft 30 facing the nozzle 33, while 37 is another seat portion provided on the surface of the ring 27 facing the valve shaft 30. Reference numeral 38 is a nut provided at the tip of the pipe 27.

Now, the first fluid will pass through the B ₂ chamber and the B ₃ chamber, while the second fluid will flow through the pipe 7, but in this example, F ₄ > F ₆ + F
_In the state of ₁ , the nozzle 33 and the sheet 36 are opened without contact, and the first fluid flows into the B ₂ chamber,
It will flow out from the outlet 35 of the B ₃ chamber through the nozzle 33. On the other hand, in the case of F ₄ <F ₆ + F ₁ , as shown in FIG. 3, the sheet portion 36 of the valve shaft 30 and the nozzle 33 come into contact with each other to interrupt the flow of the first fluid. .

However, the temperature of the second fluid flowing in the pipe 7 is detected by the heat-sensitive spring 29, and the pressing force F ₄ of the ring 27 is changed. Therefore, depending on the temperature of the second fluid, the B ₁ chamber nozzle 33 and the valve shaft 3
It is possible to freely open and close the sheet portion 36 of 0 and to automatically adjust the supply amount of the second fluid.

Therefore, if this apparatus is used, for example, as a carbon dioxide pressure adjusting apparatus to be dissolved in a raw beer liquid,
The pressure of the carbon dioxide gas supplied to the beer liquid can be automatically changed depending on the temperature of the beer liquid, so that the amount of carbon dioxide gas dissolved in the liquid can be always kept constant.

FIG. 4 is a further explanatory view of the first embodiment of the pressure adjusting apparatus of the present invention, and shows the state of the apparatus when the beer temperature is lowered at night or the like. That is, FIG.
In the state, in the nighttime or the like, bi - when Le temperature drops, to reduce the P ₂ to a pressure suitable therefor, the elastic force of the heat-sensitive spring 29 is attenuated, pressure P ₂ Is higher than the force of the spring 29, the ring 27 is pushed away from the valve shaft 30. Therefore, a gap is created between the valve shaft 30 and the sheet portion 37, and the pressure is released through the gap (not shown) between the ring 27 and the pipe 26 to reduce P ₁ to an appropriate pressure. Become. As a result, it is possible to prevent the carbon dioxide gas from being excessively supplied to the beer at a low temperature such as at night and to eliminate unnecessary dissolution of the carbon dioxide gas.

FIG. 5 is a sectional view of a second embodiment of the pressure adjusting device of the present invention, which is in the same state as FIG. 3 described above.
In the this example, without using a diaphragm 28 described above, which has none of the rings 27 and piston-like, slidably while maintaining airtightness through the O- ring 24 between the cylindrical body 21 ₁ It is said that. A valve cone 39 is provided with a nozzle 33. The behavior of the pressure adjusting device is the same as that of the above-described example, and will be omitted here.

FIG. 6 is a partial sectional view of a third embodiment of the pressure adjusting device of the present invention, which is in the same state as FIG. In this example, the pipe is simply the core body 26 '.
A pipe 40 surrounding the heat-sensitive spring 29 is provided inside the chamber, and the second fluid is caused to flow through the pipe 40 to sense the liquid temperature.

FIG. 7 is a partial sectional view of a fourth embodiment of the pressure adjusting device of the present invention, which is in the same state as FIG. This example is a modification of the pressure adjusting device shown in FIG. 6, and is an example in which the core body 26 'is omitted. That is, the core body 26 'does not necessarily need to penetrate the hollow portion, and the side covers 23, 2
5, the ring 27 and the valve shaft 30 are provided with central protrusions 41 ₁ , 41 ₂ , 41 ₃ , 41 ₄ , 41 ₄ , and 41 ₅ , respectively, and the springs, the ring 27, and the valve shaft 30 are utilized by utilizing these opposing protrusions. The whole is constructed by fitting and.

[0031]

The present invention is a pressure adjusting device for a supply fluid having the above structure, and since a spring using a shape memory alloy is used, the spring constant of this spring changes depending on the liquid temperature of the second fluid. The pressure of the first fluid can be adjusted according to this change.
Therefore, for example, by using the pressure adjusting device of the present invention for supplying carbon dioxide gas to the raw beer storage barrel, the dissolved amount of carbon dioxide gas in the raw beer can be constantly and automatically controlled. It came to be like this.

[Brief description of drawings]

FIG. 1 is a conceptual diagram of a supply fluid pressure adjusting apparatus of the present invention.

FIG. 2 is a cross-sectional view showing a first embodiment of a more specific pressure adjusting device for a supply fluid of the present invention, in which a nozzle and a sheath are shown.
It shows a state where the toe parts are open.

FIG. 3 is a view showing a state in which the nozzle and the sheet portion are closed in the pressure adjusting device shown in FIG.

FIG. 4 is a cross-sectional view showing an automatic adjusting function in the force adjusting device shown in FIG. 2 when the liquid temperature of the second fluid is lowered.

FIG. 5 is a sectional view of a second embodiment of the pressure adjusting device of the present invention.

FIG. 6 is a partial cross-sectional view of a third embodiment of the pressure adjusting device of the present invention.

FIG. 7 is a sectional view of a fourth embodiment of the pressure adjusting device of the present invention.

FIG. 8 is a schematic view of a means for mixing and dissolving carbon dioxide in a conventional raw beer storage barrel.

[Explanation of symbols]

1 ... main body of pressure regulator for supply fluid, 2 ... pipe, 2 ₁ ... 2nd fluid inlet, 2 ₂ ... 2nd fluid outlet, 3 ... ring, 4 ... heat sensitive spring, 5 ... Valve shaft, 6 ... Spring, 7 ... Nozzle, 8 ... Free hole, 9 ... First fluid inlet, 10 ... First fluid outlet, 11 ... Primary decompression regulator, 12 ... barrel connection joint, 21 ... supply fluid pressure adjusting device main body, 21 ₁ , 21 ₂ ... cylinder forming the main body, 23 ... side cover, 24 ... O-ring, 25 ... side surface Cover, 26, pipe, 26 ', core, 27, ring, 28, diaphragm, 29, heat-sensitive spring, 30, valve shaft, 31, play hole, 32, spring, 33 ... Nozzle, 34 ... 1st fluid inlet, 35 ... 1st fluid Outlet, 36 ... Seat portion provided on valve shaft 30, 37 ... Seat portion provided on ring 27, 38 ... Nut, 39 ... Valve cone, 40 ... Heat-sensitive spring Surrounding pipes, 41 ₁ , 41 ₂ , 41 ₃ , 41 ₄ , 41 ₄ , 41 ₅ ...
Central protrusion, 51 ... carbon dioxide gas storage tank, 52 ... pressure regulator for supplying carbon dioxide gas, 52 ₁ ... lever equipped with pressure regulator, 53 ... beer storage barrel, 54 ... cooling Machine, 55 ... A mug.

Claims (4)

[Claims] 1. A heat-sensitive spring, wherein a movable ring that divides into a chamber A and a chamber B is fitted in a hollow portion of a main body, and a heat-sensitive spring is mounted in the chamber A to elastically support the ring. Has a flow path for transmitting the liquid temperature of the second fluid, and has a structure in which the chamber B is divided into chambers B ₀ and B ₁ by a valve shaft that opposes the ring and is elastically supported by a spring on the opposite side. The chamber A is an atmospheric pressure chamber, a nozzle is formed from the main body toward the valve shaft in the chamber B ₀ located at the center of the hollow portion, and a seat portion is provided on the valve shaft facing the nozzle. Further, it is divided into a B ₂ chamber and a B ₃ chamber, an inlet and an outlet for the first fluid are provided on both sides of this nozzle, and a second fluid is allowed to pass through the flow passage to change the temperature of the second fluid to the heat-sensitive Pressure adjustment of the supply fluid characterized by transmitting to the mold spring Location. 2. A hollow body is divided into an A chamber and a B chamber by a main body having a hollow portion, a pipe penetrating therethrough, and a ring externally inserted in the pipe, and the A chamber is used as an atmospheric pressure chamber. At the same time, a heat-sensitive spring attached to the pipe in the room A is mounted to elastically support the ring, and in the room B, the ring is elastically supported on the pipe opposite to the ring and oppositely to the pipe elastically supported by the spring. and a valve shaft inserted bisects the B chamber B _0, B ₁ rooms, B ₀ is located in the center of the hollow portion
A nozzle is formed in the chamber from the main body, and a seat portion is provided on the valve shaft facing the nozzle to further divide the chamber into a B ₂ chamber and a B ₃ chamber. The nozzle is sandwiched between the first fluid inlet port. And a second outlet in the pipe.
A pressure adjusting device for a supply fluid, wherein a fluid is allowed to pass through and the temperature of the second fluid is transmitted to the heat-sensitive spring. 3. A diaphragm mounted between the hollow portion of the main body and the ring, the ring being slid in the axial direction of the pipe by the pressure of the first fluid flowing in the B ₂ chamber and the B ₃ chamber, and mounted on the valve shaft. The pressure adjusting device for the supply fluid according to claim 1, wherein a distance between the nozzle portion and the nozzle is adjusted. 4. A seal mounted on the valve shaft by sliding the ring in the axial direction of the pipe by the pressure of the first fluid in the B ₂ chamber and the B ₃ chamber while maintaining airtightness between the hollow portion of the main body and the ring. The supply fluid pressure adjusting apparatus according to claim 1, wherein the distance between the nozzle portion and the nozzle is adjusted.