JP2017076188A - Pressure adjustment device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a pressure adjustment device that can stably release a secondary pressure.SOLUTION: A pressure adjustment device 5 is configured to control a secondary pressure in a secondary chamber CS by a main valve 33 provided between a primary chamber CP and the secondary chamber CS. A movable valve body 32 of the main valve 33 is driven by a diaphragm 26. Between the movable valve body 32 and a central member 27, a relief valve 34 is provided. When the main valve 33 is closed, if the secondary pressure is excessively high, the diaphragm 26 is retracted, and the relief valve 34 is opened. The secondary pressure is emitted to an atmosphere or a corridor CD via a relief chamber CR. Force in which the secondary pressure acts on the movable valve body 32 in the main valve 33 and force in which the secondary pressure acts on the movable valve body 32 in the relief valve 34 act in a direction where the forces cancel each other. A seal member 37 of the main valve 33 and a seal member 38 of the relief valve 34 are separate members. The central member 27 and the movable valve body 32 are guided by engagement of a concavity part with a convexity part.SELECTED DRAWING: Figure 1

Description

  The disclosure in this specification relates to a pressure adjusting device that adjusts the pressure of a gas mixed in a liquid.

  Patent Document 1 and Patent Document 2 disclose a pressure adjusting device. These pressure adjusting devices adjust the pressure of carbon dioxide mixed in the beverage. Patent Document 1 discloses a manual relief valve (reference numeral 50, etc.).

  Patent Document 2 discloses an automatic relief valve that opens a relief port and lowers the secondary pressure when the secondary pressure rises excessively. The relief port of Patent Document 2 is formed between a valve (27) operated by a diaphragm (25) and a diaphragm pin center (26). The relief port is opened by moving the diaphragm pin center away from the valve by the retraction of the diaphragm.

  In the relief valve of Patent Document 2, when the temperature detected by the temperature-sensitive member is constant, the temperature-sensitive member and the main bias spring face the diaphragm in the direction in which the valve is separated from the seat (the valve opening direction). A force F1 is applied to. The secondary pressure causes a force F2 to act on the diaphragm in the direction in which the valve is seated on the seat (valve closing direction). When the valve is seated on the seat, the seal area between the relief port and the valve is smaller than the seal area between the seat and the valve. For this reason, when the valve is seated on the seat, the secondary pressure applies a force F3 in the valve opening direction to the valve. A force F4 in the valve closing direction is applied to the valve by the primary pressure, and a force F5 in the valve closing direction is applied by the auxiliary bias spring. However, since F3 <F4 + F5, the valve can be kept closed. If the temperature is constant, the force balance around the valve is F1 = F2-F3 + F4 + F5.

JP 2011-163481 A JP 2006-27651 A

  In the relief valve of Patent Document 2, when the valve is seated on the seat, a force F3 due to the secondary pressure acts on the valve. Thus, when the valve is seated on the seat, the force F3 due to the secondary pressure changes the force pressing the valve toward the seat.

  In the relief valve of Patent Document 2, when the relief port is opened, the secondary pressure gradually decreases. As a result, the force F3 in the valve opening direction due to the secondary pressure decreases, and the force pressing the valve toward the seat becomes relatively strong. Thereby, a sheet | seat is compressed and the sealing force in a sheet | seat rises. In addition, the relief may stop.

  From another viewpoint, in the pressure adjusting device of Patent Document 2, the seat of the main valve and the seat of the relief valve are provided by a common member. For this reason, it is difficult to achieve both the sealing performance required for the main valve and the sealing performance required for the relief valve. For example, a relief valve is required to have high responsiveness, but it is difficult to achieve both high sealing performance required for a main valve.

  In still another aspect, in the relief valve of Patent Document 2, the front end surface of the diaphragm pin center comes into contact with the sheet. In this case, the valve closing state and the valve opening state may not be stable due to the inclination of the diaphragm pin center and the inclination of the seat.

  In view of the above, or other aspects not mentioned, there is a need for further improvements in the pressure regulator.

  One disclosed object is to provide a pressure regulator that can stably relieve the secondary pressure.

  Another object to be disclosed is to provide a pressure regulating device in which a main valve and a relief valve have different sealing performances.

  Still another object of the present invention is to provide a pressure regulator that can obtain a stable behavior in a relief valve.

  One pressure regulating device disclosed here regulates the pressure of gas mixed in the liquid. The pressure adjusting device is disposed so as to be in contact with the gas of the secondary pressure supplied to the liquid, the pressure-sensitive member (26) that is displaced according to the secondary pressure, and the movable valve body (32) operated by the pressure-sensitive member. ) And is provided between a primary chamber (CP) for a gas having a primary pressure higher than the secondary pressure and a secondary chamber (CS) for a gas having a secondary pressure. A relief valve that is provided between the main valve (33) that is opened and closed, and is opened and closed by the pressure-sensitive member and is released by the pressure-sensitive member and releases the gas in the secondary chamber when the secondary pressure becomes excessively high. 34), and a pressure receiving portion that receives the secondary pressure in the main valve and a pressure receiving portion that receives the secondary pressure in the relief valve include a force that the secondary pressure acts on the movable valve body in the main valve, The secondary pressure is configured to cancel out the force acting on the movable valve body.

  According to the disclosed pressure adjusting device, the force that the secondary pressure acts on the movable valve body is canceled out. The secondary pressure acts on the pressure receiving portion of the main valve. The secondary pressure also acts on the pressure receiving portion of the relief valve. These pressure receiving portions are configured such that the force at which the secondary pressure acts on the movable valve body in the main valve cancels out the force at which the secondary pressure acts on the movable valve body in the relief valve. For this reason, the influence of the secondary pressure in the force acting on the movable valve body is suppressed. As a result, even if the secondary pressure fluctuates, a stable relief function can be obtained in the relief valve.

  Another pressure regulating device disclosed herein regulates the pressure of the gas mixed into the liquid. The pressure adjusting device is disposed so as to be in contact with the gas of the secondary pressure supplied to the liquid, the pressure-sensitive member (26) that is displaced according to the secondary pressure, and the movable valve body (32) operated by the pressure-sensitive member. ) And is provided between a primary chamber (CP) for a gas having a primary pressure higher than the secondary pressure and a secondary chamber (CS) for a gas having a secondary pressure. A relief valve that is provided between the main valve (33) that is opened and closed, and is opened and closed by the pressure-sensitive member and is released by the pressure-sensitive member and releases the gas in the secondary chamber when the secondary pressure becomes excessively high. 34), the main valve includes a first seal member (37) that is compressed by the movable valve body when the main valve is closed, and the relief valve is movable when the relief valve is closed. A second sealing member (38) is provided that is compressed by the body.

  According to the disclosed pressure regulator, different sealing performance is provided to the main valve and the relief valve. The material, shape, and the like of the first seal member can be set according to the function required for the main valve. Further, the material, shape, and the like of the second seal member can be set according to the function required for the relief valve.

  One pressure regulating device disclosed here regulates the pressure of gas mixed in the liquid. The pressure adjusting device is disposed so as to be in contact with the gas of the secondary pressure supplied to the liquid, the pressure-sensitive member (26) that is displaced according to the secondary pressure, and the movable valve body (32) operated by the pressure-sensitive member. ) And is provided between a primary chamber (CP) for a gas having a primary pressure higher than the secondary pressure and a secondary chamber (CS) for a gas having a secondary pressure. A relief valve that is provided between the main valve (33) that is opened and closed, and is opened and closed by the pressure-sensitive member and is released by the pressure-sensitive member and releases the gas in the secondary chamber when the secondary pressure becomes excessively high. 34), and the relief valve is formed between the central member (27) provided in the diaphragm and the movable valve body, and the central member and the movable valve body include the central member and the movable valve body. Relative to the central member and the movable valve body in the radial direction while allowing relative movement in the axial direction It is guided by a guide mechanism for restricting the movement Do (27e, 32a).

  According to the disclosed pressure regulating device, the relief valve is formed between the central member and the movable valve body. The central member and the movable valve body are guided by a guide mechanism. The guide mechanism allows relative movement of the central member and the movable valve body in the axial direction. On the other hand, the guide mechanism restricts the relative movement of the central member and the movable valve body in the radial direction. The relative posture between the central member and the movable valve body is stabilized by the guide mechanism. Thereby, a stable behavior can be obtained in the relief valve.

  The disclosed embodiments of the present specification employ different technical means to achieve each purpose. The reference numerals in parentheses described in the claims and this section exemplify the correspondence with the embodiments described later, and are not intended to limit the technical scope. The objects, features, and advantages disclosed in this specification will become more apparent with reference to the following detailed description and accompanying drawings.

It is sectional drawing of the pressure regulator which concerns on one Embodiment. It is a partial expanded sectional view of one embodiment. It is a partial expanded sectional view of one embodiment. It is a graph which shows the hardness of a sealing member.

  A plurality of embodiments will be described with reference to the drawings. In embodiments, functionally and / or structurally corresponding parts and / or associated parts may be assigned the same reference signs or reference signs that differ by more than a hundred. For the corresponding parts and / or associated parts, the description of other embodiments can be referred to.

  In FIG. 1, a beverage supply device 1 is a device that supplies beer as a beverage, a so-called beer server. The beverage supply device 1 supplies beer from the beer tank 2 to the tap 3. The beer tank 2 is a so-called barrel. The tap 3 is a faucet for supplying beer to a container such as a mug when operated by a user. The beverage supply apparatus 1 mixes carbon dioxide as gas in beer. The beverage supply device 1 supplies carbon dioxide gas from the gas cylinder 4 to the beer tank 2 via the pressure adjustment device 5.

  The pressure adjusting device 5 adjusts the pressure of the gas mixed into the liquid. The pressure adjusting device 5 is called a temperature-sensitive type that adjusts the pressure of carbon dioxide mixed in beer according to the atmospheric temperature or the temperature of beer. In the following description, the pressure of the carbon dioxide gas supplied from the gas cylinder 4 is called a primary pressure, and the pressure adjusted by the pressure adjusting device 5 is called a secondary pressure. The pressure adjusting device 5 increases the secondary pressure when the detected temperature increases, and decreases the secondary pressure when the detected temperature decreases.

  The pressure adjusting device 5 has a housing 11 that partitions and forms a passage for beer and a passage for carbon dioxide gas and accommodates a valve mechanism for pressure adjustment. The housing 11 is composed of a plurality of members. The plurality of members constituting the housing 11 are made of resin or metal. A seal member, for example, an O-ring, for maintaining airtightness is disposed between the plurality of members as necessary. The housing 11 has a gas inlet 12 and a gas outlet 13 for carbon dioxide. The gas inlet 12 is connected to the gas cylinder 4. The gas outlet 13 is connected to the beer tank 2, specifically to the gas inlet of the dispense head. The housing 11 has a beer inlet 14 for beer and a beer outlet 15. The beer inlet 14 is connected to the beer tank 2, specifically to the beer outlet of the dispense head. The beer outlet 15 is connected to the tap 3. The pressure adjusting device 5 provides a part of the pipe connecting the beer tank 2 and the tap 3. The pressure adjusting device 5 may be provided apart from the pipe.

  The pressure adjusting device 5 includes a beer passage 16, a temperature sensing mechanism 17, and a valve mechanism 18. The beer passage 16 defines and forms a passage CD for flowing beer. The passage CD is a cavity into which a temperature-sensitive medium is introduced. The beer passage 16 has a joint part for providing a beer inlet 14 and a beer outlet 15.

  The temperature sensing mechanism 17 is provided between the beer passage 16 and the valve mechanism 18. The temperature sensing mechanism 17 senses the temperature of the beer in the beer passage 16 and corrects the pressure adjustment operation in the valve mechanism 18 according to the sensed temperature. The temperature sensing mechanism 17 changes the reference value of the bias mechanism in the valve mechanism 18 according to the sensed temperature. More specifically, the temperature sensing mechanism 17 is configured to change the preload of the bias spring that provides the bias mechanism. The temperature sensing mechanism 17 has a thermo wax 19. The thermo wax 19 is a temperature sensitive member that senses the temperature of beer. The thermo wax 19 expands when the temperature of the beer increases, and contracts when the temperature of the beer decreases.

  The valve mechanism 18 reduces the primary pressure supplied from the gas cylinder 4 and supplies the adjusted secondary pressure carbon dioxide gas. The valve mechanism 18 defines a carbon dioxide gas passage. The passage includes a primary chamber CP that is filled with carbon dioxide at a primary pressure and a secondary chamber CS that is filled with carbon dioxide at a secondary pressure. The valve mechanism 18 has a pressure regulating valve disposed in the passage. The pressure regulating valve is provided between the primary chamber CP and the secondary chamber CS.

  The valve mechanism 18 includes a first body 21, a second body 22, a valve holder 23, a cover 24, and an adjuster 25. These members provide the housing 11. The first body 21 accommodates a pressure regulating valve and defines and forms a passage for carbon dioxide gas. The second body 22 accommodates the bias mechanism and the temperature sensing mechanism 17 and defines and forms a relief passage.

  The valve holder 23 is a cylindrical member having a partition wall. The valve holder 23 is accommodated in a cylindrical cavity formed by the first body 21 so as to be movable in the axial direction thereof. The adjuster 25 is provided between the valve holder 23 and the cover 24 so as to cover the opening end of the first body 21. The adjuster 25 is put on the opening end of the first body 21. The adjuster 25 is formed as an adjustment knob that can be manually rotated. By rotating the adjuster 25, the valve holder 23 can be moved in the axial direction, and the set value of the secondary pressure by the valve mechanism 18 can be manually set.

  The valve mechanism 18 has a diaphragm 26. The diaphragm 26 is a pressure-sensitive member that senses secondary pressure. The pressure-sensitive member is disposed so as to be in contact with the secondary pressure gas supplied to the liquid, and is displaced according to the secondary pressure. The outer peripheral edge portion of the diaphragm 26 is sandwiched and fixed between the first body 21 and the second body 22. A central member 27 is provided at the center of the diaphragm 26. The central member 27 applies a bias mechanism force to the diaphragm 26. The central member 27 is also a member that provides a relief valve described later.

  The valve mechanism 18 has a fixed valve body 31. The fixed valve body 31 is fixed to the valve holder 23. The fixed valve body 31 provides a valve seat for the main valve for reducing the primary pressure to the secondary pressure. The fixed valve body 31 is formed in a cylindrical shape. The fixed valve body 31 has a valve seat at the end on the secondary chamber CS side.

  The valve mechanism 18 has a movable valve body 32. The movable valve body 32 is disposed so as to penetrate through the fixed valve body 31. The movable valve body 32 has a cylindrical shaft portion and valve portions provided at both ends thereof. The shaft portion has a small diameter and is disposed in the fixed valve body 31. The valve portion has a larger diameter than the shaft portion. The valve portion is disposed so as to protrude from both ends of the fixed valve body 31. The movable valve body 32 can be formed by two members connected in the axial direction.

  Between the fixed valve body 31 and the shaft portion, a passage portion for allowing carbon dioxide gas to flow is formed. The passage portion can be provided by various structures such as a flat portion provided in the shaft portion, a hollow portion provided in the shaft portion, or a groove portion provided in the through hole of the fixed valve body 31.

  A main valve 33 is formed between the fixed valve body 31 and the movable valve body 32. The main valve 33 has a movable valve body 32 operated by a pressure sensitive member. The main valve 33 is provided between the primary chamber CP for the primary pressure gas higher than the secondary pressure and the secondary chamber CS for the secondary pressure gas. The main valve 33 is opened and closed by the movable valve body 32. The movable valve body 32 forms a main valve 33 by a portion protruding from the fixed valve body to the primary chamber CP. The main valve 33 intermittently supplies the carbon dioxide gas from the primary chamber CP to the secondary chamber CS so as to maintain the secondary pressure at a predetermined pressure.

  A relief valve 34 is formed between the central member 27 and the movable valve body 32. The relief valve 34 is provided between the pressure sensitive member and the movable valve body 32. The relief valve 34 is formed between the central member 27 provided on the diaphragm 26 and the movable valve body 32. The relief valve 34 is provided between the secondary chamber CS and the relief chamber CR. The movable valve body 32 forms a relief valve 34 by a portion protruding from the fixed valve body 31 to the secondary chamber CS.

  The relief valve 34 is opened and closed by a pressure-sensitive member, and releases the gas in the secondary chamber CS when the secondary pressure becomes excessively high. The relief valve 34 is opened and closed by the relative movement of the central member 27 and the movable valve body 32 in the axial direction. The relief valve 34 is configured to open and close in response to the movement of the diaphragm when the main valve 33 is closed, that is, the pressure sensitive member. The relief valve 34 is opened when the diaphragm 26 is further retracted when the main valve 33 is in the closed state.

  The relief chamber CR is defined in the second body 22. The relief chamber CR communicates with the atmosphere through the communication hole 39. The secondary pressure in the secondary chamber CS can be discharged to the relief chamber CR via the relief valve 34. Furthermore, the pressure in the relief chamber CR can be released to the atmosphere.

  The valve mechanism 18 has a main bias spring 35. The main bias spring 35 is disposed in a compressed state between the thermowax 19 and the central member 27. The main bias spring 35 applies a load to the diaphragm 26. The main bias spring 35 applies a force in the valve opening direction of the main valve 33 to the diaphragm 26 and the movable valve body 32.

  The valve mechanism 18 has a sub bias spring 36. The auxiliary bias spring 36 is disposed in a compressed state between the valve holder 23 and the movable valve body 32. The auxiliary bias spring 36 applies a load to the movable valve body 32. The auxiliary bias spring 36 applies a force in the valve closing direction of the main valve 33 to the movable valve body 32.

  The main valve 33 includes a first seal member 37 that is compressed by the movable valve body 32 when the main valve 33 is closed. The relief valve 34 includes a second seal member 38 that is compressed by the movable valve body 32 when the relief valve 34 is closed.

  In FIG. 2, the central member 27 defines and forms a relief passage 27a. The relief passage 27 a passes through the diaphragm 26.

  The central member 27 has guide rings 27b and 27c arranged so as to sandwich the diaphragm 26 therebetween. The guide ring 27b is formed in a dish shape. The guide ring 27c has a dish-shaped part and a cylindrical part. The guide ring 27c defines a relief passage 27a. A cylindrical portion of the guide ring 27 c passes through the diaphragm 26. The relief passage 27a is formed in a cylindrical portion. The central member 27 has a seat plate 27 d as a seat portion of the main bias spring 35.

  The guide ring 27c has a guide recess 27e. The guide recess 27e is provided at the end of the relief passage 27a on the secondary chamber CS side. The guide recess 27e is provided on the end surface of the guide ring 27c. The movable valve body 32 has a guide protrusion 32a at its end. The guide convex portion 32 a is provided at the end of the movable valve body 32 on the relief valve 34 side. The guide convex portion 32a is inserted into the guide concave portion 27e. Further, the guide convex portion 32a is formed and arranged so as to partition a passage between the guide convex portion 32a and the guide concave portion 27e. The passage can be provided by a flat surface portion or a groove portion formed in the guide convex portion 32a.

  The guide recess 27e and the guide protrusion 32a provide a guide mechanism. The guide mechanism allows relative movement of the central member 27 and the movable valve body 32 in the axial direction. On the other hand, the guide mechanism restricts the relative movement of the central member 27 and the movable valve body 32 in the radial direction. The guide concave portion 27e and the guide convex portion 32a suppress the radial displacement between the central member 27 and the movable valve body 32. The guide concave portion 27e and the guide convex portion 32a form a flow path communicating with the relief passage 27a while suppressing the inclination of the movable valve body 32. When the relief valve 34 is open, the carbon dioxide gas in the secondary chamber CS passes through the relief valve 34, passes through the gap between the guide concave portion 27e and the guide convex portion 32a, passes through the relief passage 27a, It is discharged to the relief chamber CR.

  The movable valve body 32 has a seal member 37 for forming the main valve 33. The seal member 37 is a resin O-ring. The movable valve body 32 has a constricted portion 32 b for supporting the seal member 37. The seal member 37 seals between the primary chamber CP and the secondary chamber CS by contacting the end surface of the fixed valve body 31. The separation of the sealing member 37 from the end face of the fixed valve body 31 allows the supply of carbon dioxide gas from the primary chamber CP to the secondary chamber CS. When the seal member 37 comes into contact with the end face of the fixed valve body 31 and is pressed, the supply of carbon dioxide gas from the primary chamber CP to the secondary chamber CS is blocked.

  The movable valve body 32 has a seal member 38 for forming a relief valve 34. The seal member 38 is a resin O-ring. The movable valve body 32 has a constricted portion 32 b for supporting the seal member 38. The seal member 38 seals between the secondary chamber CS and the relief chamber CR by contacting the end surface of the central member 27, that is, the guide ring 27c. The release of the carbon dioxide gas from the secondary chamber CS to the relief chamber CR is allowed by separating the seal member 38 from the end surface of the central member 27. When the seal member 38 comes into contact with the end surface of the central member 27 and is pressed, the release of carbon dioxide gas from the secondary chamber CS to the relief chamber CR is blocked.

  FIG. 3 shows the force acting on the movable valve body 32 and the diameters D37 and D38 of the seal lines in the main valve 33 and the relief valve 34. The valve closing direction CL33 of the main valve 33 is a direction in which the movable valve body 32 is directed from the primary chamber CP to the secondary chamber CS, that is, an upward direction in the drawing. The valve opening direction OP33 of the main valve 33 is a direction in which the movable valve body 32 is directed from the secondary chamber CS to the primary chamber CP, that is, a downward direction in the drawing. When the main valve 33 is in the closed state, that is, when the seal member 37 is seated on the fixed valve body 31, the relief valve 34 is opened by the backward movement of the diaphragm 26. The valve opening direction OP34 of the relief valve 34 is a direction in which the central member 27 is directed from the secondary chamber CS to the relief chamber CR, that is, an upward direction in the drawing. A valve closing direction CL34 of the relief valve 34 is a direction from the relief chamber CR toward the secondary chamber CS, that is, a downward direction in the drawing. Thus, the opening / closing direction of the main valve 33 is opposite to the opening / closing direction of the relief valve 34. In the following description, directions are described in terms of upward and downward directions based on the drawings.

  The bias mechanism including the main bias spring 35 generates a downward force F1. The diaphragm 26 generates an upward force F2 due to a pressure difference between the secondary chamber CS and the relief chamber CR. These forces F1 and F2 are transmitted to the movable valve body 32 via the guide mechanisms 27e and 32a between the central member 27 and the movable valve body 32, the relief valve 34, and the seal member 38.

  The secondary pressure in the secondary chamber CS acts on the main valve 33 to generate a downward force F31 that pushes the movable valve body 32 downward. The secondary pressure acts on the seal area in the main valve 33. The pressure receiving portion that receives the secondary pressure in the main valve 33 is characterized by a seal area. The seal area can be calculated from the contact portion between the seal member 37 and the fixed valve body 31, that is, the diameter D37 of the seal line.

  The secondary pressure in the secondary chamber CS acts on the relief valve 34 to generate an upward force F32 that pushes the movable valve body 32 upward. The secondary pressure acts on the seal area in the relief valve 34. The pressure receiving portion that receives the secondary pressure in the relief valve 34 is characterized by a seal area. The seal area can be calculated from the contact portion between the seal member 38 and the central member, that is, the diameter D38 of the seal line.

  In this embodiment, the force that the secondary pressure acts on the movable valve body 32 in the main valve 33 and the force that the secondary pressure acts on the movable valve body 32 in the relief valve 34 are configured to cancel each other. . Specifically, the diameter D37 and the diameter D38 are set so that the force F31 and the force F32 cancel each other. The diameter D37 and the diameter D38 can be set so that the force F31 and the force F32 partially cancel each other. For example, they can be set to such an extent that the change in the secondary pressure after the relief valve 34 is opened does not change the load on the seal member 37 excessively. For example, the diameter D37 and the diameter D38 can be set equal. In this embodiment, the diameter D37 and the diameter D38 are set so that the force F31 and the force F32 completely cancel each other.

  The primary pressure in the primary chamber CP acts on the main valve 33 to generate an upward force F4 that pushes the movable valve body 32 upward. The sub-bias spring 36 acts on the movable valve body 32 to generate an upward force F5 that pushes the movable valve body 32 upward.

  FIG. 4 is a graph showing the hardness of the seal members 37 and 38. The horizontal axis indicates the load F (N) acting on the seal members 37 and 38. The vertical axis represents the compression rate CM (%). The seal member 37 exhibits a characteristic C37. The seal member 38 exhibits a characteristic C38. CML indicates a seal limit value by the seal member 38. FIG. 4 shows that the seal member 38 cannot seal between the secondary chamber CS and the relief chamber CR at a compression rate lower than the seal limit value CML.

  In this embodiment, the seal member 37 for the main valve 33 and the seal member 38 for the relief valve 34 are provided by different members. Therefore, the material and shape of the seal member 37 can be selected so as to satisfy the specifications required for the main valve 33. At the same time, the material and shape of the seal member 38 can be selected so as to satisfy the specifications required for the relief valve 34. In this embodiment, the seal member 37 has a lower hardness and is softer than the seal member 38. In other words, the seal member 38 is harder than the seal member 37. The hardness of the seal member 38 is set to slightly exceed the seal limit value CML when receiving F4 + F5 as a load. In other words, the hardness of the seal member 38 is set so that when the relief valve 34 is to be closed, the compression rate CM exceeds the seal limit value CML, but the compression rate CM is close to the seal limit value CML. ing.

  Such a difference in hardness between the sealing member 37 and the sealing member 38 enables high responsiveness of the relief valve 34. This is because a slight displacement of the diaphragm 26 and the central member 27 causes the compression rate of the seal member 38 to fall below the seal limit value CML. Further, the seal member 37 can seal between the primary chamber CP and the secondary chamber CS with a relatively small load. Such a design makes it possible to optimize by changing the combination of parts even if part errors occur. In other words, the contract of the dimensions of the parts is suppressed, and the degree of freedom in design is expanded.

  When the main valve 33 is closed, the primary pressure is constant. When the temperature of the beer is stable at a predetermined value, since the length of the thermowax 19 is constant, the force F1 is constant. In this case, the main valve 33 adjusts the secondary pressure so that F1 = F2 + F4 + F5 is established. At this time, carbon dioxide gas is supplied from the gas cylinder 4 to the secondary chamber CS through the main valve 33, through the gap between the fixed valve body 31 and the movable valve body 32.

  The force with which the movable valve body 32 pushes the seal member 37 for the main valve 33 can be expressed as F4 + F5 or F1-F2. According to this embodiment, since the force F31 and the force F32 are offset, the secondary pressure does not affect the force pushing the seal member 37. As a result, fluctuations in the sealing performance of the sealing member 37 are suppressed. Further, the position of the movable valve body 32 in the axial direction is stabilized. Thereby, the relief valve 34 is stably opened. Further, even if the secondary pressure is lowered by opening the relief valve 34, the discharge is continued until the secondary pressure is lowered to a desired pressure.

  When the secondary pressure becomes excessive due to the temperature of the beer decreasing, the relief valve 34 is opened to release the secondary pressure. For example, when the beer temperature falls at night, the amount of carbon dioxide dissolved in the beer increases. If beer is supplied the next day, foam will be excessive. In such a case, the relief valve 34 releases carbon dioxide gas from the secondary chamber CS according to the temperature of the beer, and lowers the secondary pressure. At this time, according to this embodiment, a stable relief operation is realized. Further, according to this embodiment, a high sealing performance can be obtained in the relief valve 34.

  According to this embodiment, when the main valve 33 and the relief valve 34 are closed, the force that the secondary pressure of the secondary chamber CS acts on the movable valve body 32 is offset. As a result, the influence of the secondary pressure on the force acting on the movable valve body 32 is suppressed. Therefore, even if the secondary pressure fluctuates, a stable relief function can be obtained in the relief valve 34.

  According to this embodiment, the seal member 37 and the seal member 38 are employed. Thereby, different sealing performance is given to the main valve 33 and the relief valve 34. The material and shape of the seal member 37 can be set according to the function required for the main valve 33. Further, the material and shape of the seal member 38 can be set according to the function required for the relief valve 34. Since the hardness of the seal member 38 is higher than the hardness of the seal member 37, high responsiveness can be given to the relief valve 34.

  According to this embodiment, the guide mechanism by the guide recessed part 27e and the guide convex part 32a is provided between the central member 27 and the movable valve body 32. FIG. Therefore, the displacement between the members in the relief valve 34 is suppressed. By the guide mechanism, the relative posture between the central member 27 and the movable valve body 32 is stabilized. Thereby, a stable behavior can be obtained in the relief valve 34.

  The disclosure in this specification is not limited to the illustrated embodiments. The disclosure encompasses the illustrated embodiments and variations by those skilled in the art based thereon. For example, the disclosure is not limited to the combinations of parts and / or elements shown in the embodiments. The disclosure can be implemented in various combinations. The disclosure may have additional parts that can be added to the embodiments. The disclosure includes those in which parts and / or elements of the embodiments are omitted. The disclosure encompasses the replacement or combination of parts and / or elements between one embodiment and another. The technical scope disclosed is not limited to the description of the embodiments. Some technical scope disclosed is indicated by the description of the claims, and should be understood to include all modifications within the meaning and scope equivalent to the description of the claims. .

  In the above embodiment, an example in which the pressure adjusting device is applied to a beer server has been described. It replaces with this and a pressure regulation device may be applied to the device which supplies soft drinks, such as carbonated water and carbonated juice.

  In the above embodiment, the central member 27 is provided with a guide concave portion, and the movable valve body 32 is provided with a guide convex portion. Instead, the central member 27 may be provided with a guide convex portion, and the movable valve body 32 may be provided with a guide concave portion. Thus, the central member 27 and the movable valve body 32 include a guide concave portion provided in one member and a guide convex portion provided in the other member and disposed in the guide concave portion. Note that the disclosure in this specification includes a configuration in which the central member 27 and the movable valve body 32 are not provided with a guide mechanism.

  In the above embodiment, resin O-rings are used as the seal members 37 and 38. Instead, various seal members such as a rubber O-ring, a lip seal, or a metal O-ring such as stainless steel can be employed as the seal member. Further, instead of the seal member, the main valve 33 or the relief valve 34 is provided by direct contact between the fixed valve body 31 and the movable valve body 32 or direct contact between the central member 27 and the movable valve body 32. May be.

1 beverage supply device, 2 beer tank, 3 taps, 4 gas cylinders,
5 pressure regulator, 11 housing, 12 gas inlet, 13 gas outlet,
14 beer entrance, 15 beer exit, 16 beer passage,
17 temperature sensing mechanism, 18 valve mechanism, 19 thermowax,
21 first body, 22 second body, 23 valve holder,
24 cover, 25 adjuster, 26 diaphragm,
27 central member, 27a relief passage, 27b guide ring,
27c guide ring, 27d seat plate, 27e guide recess,
31 fixed valve body, 32 movable valve body,
32a guide convex part, 32b constricted part, 32c constricted part,
33 Main valve, 34 Relief valve,
35 main bias spring, 36 sub bias spring,
37 sealing member, 38 sealing member, 39 communicating hole,
CP primary room, CS secondary room, CR relief room.

Claims (9)

In the pressure adjustment device that adjusts the pressure of the gas mixed in the liquid,
A pressure-sensitive member (26) disposed so as to be in contact with a gas having a secondary pressure supplied to the liquid and displaced in accordance with the secondary pressure;
A movable valve body (32) operated by the pressure-sensitive member, and a primary chamber (CP) for a primary pressure gas higher than the secondary pressure and a secondary for the secondary pressure gas A main valve (33) provided between the chamber (CS) and opened and closed by the movable valve element;
A relief valve (34) provided between the pressure-sensitive member and the movable valve body, opened and closed by the pressure-sensitive member, and releasing the gas in the secondary chamber when the secondary pressure becomes excessively high. ,
The pressure receiving portion that receives the secondary pressure in the main valve and the pressure receiving portion that receives the secondary pressure in the relief valve include a force that the secondary pressure acts on the movable valve body in the main valve, and the relief A pressure adjusting device configured to cancel the force exerted on the movable valve body by the secondary pressure in the valve. The main valve includes a cylindrical fixed valve body (31) disposed between the primary chamber and the secondary chamber,
The movable valve body is disposed so as to penetrate the fixed valve body and protrude into both the primary chamber and the secondary chamber,
The movable valve body forms the main valve by a portion projecting from the fixed valve body to the primary chamber, and a direction from the secondary chamber toward the primary chamber is defined as a valve opening direction of the main valve. And the direction from the primary chamber toward the secondary chamber is the valve closing direction of the main valve,
The movable valve body forms the relief valve by a portion protruding from the fixed valve body to the secondary chamber, and a direction from the secondary chamber toward the pressure-sensitive member is a valve opening direction of the relief valve. And the direction from the pressure-sensitive member toward the secondary chamber is the valve closing direction of the relief valve,
The pressure regulator according to claim 1, wherein the relief valve is configured to open and close in response to movement of the pressure-sensitive member when the main valve is closed. The main valve includes a first seal member (37) that is compressed by the movable valve body when the main valve is closed.
The pressure regulating device according to claim 1 or 2, wherein the relief valve includes a second seal member (38) that is compressed by the movable valve body when the relief valve is closed. In the pressure adjustment device that adjusts the pressure of the gas mixed in the liquid,
A pressure-sensitive member (26) disposed so as to be in contact with a gas having a secondary pressure supplied to the liquid and displaced in accordance with the secondary pressure;
A movable valve body (32) operated by the pressure-sensitive member, and a primary chamber (CP) for a primary pressure gas higher than the secondary pressure and a secondary for the secondary pressure gas A main valve (33) provided between the chamber (CS) and opened and closed by the movable valve element;
A relief valve (34) provided between the pressure-sensitive member and the movable valve body, opened and closed by the pressure-sensitive member, and releasing the gas in the secondary chamber when the secondary pressure becomes excessively high. ,
The main valve includes a first seal member (37) that is compressed by the movable valve body when the main valve is closed.
The pressure regulating device, wherein the relief valve includes a second seal member (38) that is compressed by the movable valve body when the relief valve is closed.   The pressure adjusting device according to claim 3 or 4, wherein a diameter (D37) of a contact portion provided by the first seal member is equal to a diameter (D38) of a contact portion provided by the second seal member.   The pressure regulating device according to any one of claims 3 to 5, wherein the second seal member is harder than the first seal member. The relief valve is formed between a central member (27) provided in the pressure sensitive member and the movable valve body,
The central member and the movable valve body are relatively relative to each other in the radial direction between the central member and the movable valve body while allowing relative movement in the axial direction between the central member and the movable valve body. The pressure adjusting device according to any one of claims 1 to 6, wherein the pressure adjusting device is guided by a guide mechanism (27e, 32a) for restricting movement. In the pressure adjustment device that adjusts the pressure of the gas mixed in the liquid,
A pressure-sensitive member (26) disposed so as to be in contact with a gas having a secondary pressure supplied to the liquid and displaced in accordance with the secondary pressure;
A movable valve body (32) operated by the pressure-sensitive member, and a primary chamber (CP) for a primary pressure gas higher than the secondary pressure and a secondary for the secondary pressure gas A main valve (33) provided between the chamber (CS) and opened and closed by the movable valve element;
A relief valve (34) provided between the pressure-sensitive member and the movable valve body, opened and closed by the pressure-sensitive member, and releasing the gas in the secondary chamber when the secondary pressure becomes excessively high. ,
The relief valve is formed between a central member (27) provided in the pressure sensitive member and the movable valve body,
The central member and the movable valve body are relatively relative to each other in the radial direction between the central member and the movable valve body while allowing relative movement in the axial direction between the central member and the movable valve body. A pressure adjusting device guided by a guide mechanism (27e, 32a) for restricting movement.   The central member and the movable valve body include a guide concave portion (27e) provided in one member and a guide convex portion (32a) provided in the other member and disposed in the guide concave portion. The pressure regulator according to claim 7 or 8.

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