FI81661B - KULVENTIL. - Google Patents

Description

8166!

This invention relates to a ball valve for pipelines, etc., and more particularly to a double shut-off type ball valve in which, as the pressure inside the nest cavity abnormally increases, this nest cavity is contacted with a fluid passage to suppress such abnormal pressure growth in the cavity.

In those types of ball valves in which the spherical closure member rotatably remains in place in the housing by means of a stem and the fluid passage is opened and closed by rotating the spherical closure member, single closure type and double closure type are known as typical closure methods, as disclosed in Piping Technique 89.

Fig. 1 shows a section of the main part of a conventional single-closure type ball valve, in which the spherical closure member 2 as a valve member is closed in the housing 1 so as to rotate around a stem (not shown) to open and close the fluid passage 3 formed in the housing. A seat retainer 4 is arranged in the housing to surround the fluid passage, and an annular valve seat 6 is mounted opposite the spherical closure member between the seat retainer 4 and the outer ring 5 attached thereto. the outer ring 5 is forced behind it towards the spherical closing member by means of compression springs 7 located at predetermined intervals in the circumferential direction, whereby the annular valve seat 6 is brought into contact with the surface of the spherical closing member to provide a seal between the seat stop and the spherical closing member.

An O-ring 8 is mounted on the part of the outer circumferential surface of the seat stop 4 which is in sliding contact with the inner wall surface of the housing, the outer diameter D2 of which is larger than the sealing point diameter of the valve seat, for sealing the housing and the seat stop.

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between. The ball valve of Figure 1 further has a sealant passage 9 for injecting sealant from the injector (not shown) to a sealing point that opens near the inner surface of the valve seat to temporarily perform the sealing function in the event of possible seat damage.

When such a one barrier-type valve, the fluid channel is subjected to fluid pressure, and the primary side fluid pressure is greater than the secondary side 10 of the fluid pressure P2 will istukanpidäke therefore exposed to guarantee the active itsepuristavalle a force that is proportional to the annular portion of the region having a width corresponding to the difference between the valve seat 6 of the sealing point between the diameter and the outer diameter D2 at the seat ring O-ring 15 and at the product of the pressure difference between the liquid pressure P1 and the internal pressure P1 of the housing cavity, i.e.; ; <D2 'D?> ‘P1 – p3> so that the valve seat comes into close contact with the ball. In this manner, the primary side fluid is sealed.

20 On the other hand, if the primary side fluid leak receptacle cavity, thereby increasing the receptacle cavity internal pressure P is ^ higher than the secondary side fluid pressure P2 "following force: π February 2, 'D2 - Di" P3 - P2> affect istukanpidäkkeeseen depressurization force for urging istukanpidäkkeen back to its back surface 25 facing When this pressure reduction force. becomes greater than the compressive force of the compression spring 7, the valve seat therefore moves away from the ball, whereby the pressure inside the housing cavity can be lowered to the secondary side to prevent an abnormal increase in the pressure inside the housing cavity.

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One type of shut-off valve according to the abnormal growth of receptacle cavity internal pressure, therefore, prevents the reaction of the receptacle cavity in connection with the secondary side. However, liquid compaction occurs only on the primary side.

A double seal type is known as a sealing method which can seal a liquid on both the primary and secondary sides, as shown in Figure 2. According to this sealing method, a stepped portion is formed in the outer circumferential portion of the seat retainer 4 where the seat retainer 10 is in sliding contact with the inner wall surface of the housing 1, the stepped portion extending from a surface larger in diameter D2 than the valve seat 6 sealing point diameter. smaller diameter than the sealing point diameter. These larger and smaller diameter surfaces form a closed chamber in connection with the inner wall surface of the housing which is in sliding contact therewith. The closed canister acts as an O-ring groove 11 in which an O-ring 8 is placed to provide a seal between the housing 1 and the seat retainer 6 20.

In normal mode, the primary side is the primary side fluid pressure P1 therefore will be greater than the receptacle cavity 10 of the internal pressure P L so that the power itsepuristava V -, p - P 4 affects istukkapidäkkeen the back surface of the valve seat 6 and 25 on the primary fluid seals.

On the other hand if the internal pressure of the receptacle cavity increases receptacle cavity due to leakage or high temperature and receptacle cavity primary-side fluid internal pressure P L becomes larger than the secondary fluid pressure P2 in the allowed 30 within the supplied internal pressure of the receptacle cavity O-ring groove 81 661 11 so that the O-ring 8 is pressed against O towards the right-hand housing wall of the annular groove 11 as shown in Fig. 3, and the pressure inside the housing cavity acts up to the surface having a smaller diameter D1. As a result, five itsepuristava power V - φ (Ρ3 - P) 4 affects istukanpidäkkeen 4 on the rear surface, which has the valve seat 6 to seal the secondary liquid. In other words, leakage of the liquid medium from the primary side to the secondary side is prevented.

10 receptacle cavity must therefore be of such a double barrier method, the closed pressure, in which case in particular in the event that the liquid medium is an incompressible fluid, for example, when the primary side fluid leak receptacle cavity for more than a certain amount, an internal pressure of 15 receptacle cavity to increase to an abnormal value and to cause the valve damage. Such an abnormal increase in pressure in the nest cavity can be avoided by connecting a relief valve to the nest cavity but this does not apply when the liquid is flammable. Even when the capacity of the relief valve 20 is insufficient, regardless of the type of fluid, the valve will be damaged.

Accordingly, it is an object of the invention to provide a double shut-off type ball valve in which, as the pressure inside the nest cavity increases above a predetermined level 25, the nest cavity is contacted with a fluid passage using this pressure to prevent abnormal pressure build-up in the nest cavity.

According to an object of the present invention, there is provided a ball valve having a housing; a movable spherical closure member 30 for opening and closing the fluid passage in the housing, a housing cavity formed between the movable spherical closure member and the housing, an annular seal insulating the housing cavity from the fluid passage, and a diverter valve for selectively connecting the housing cavity to the fluid a plane in which the reversing valve comprises an axially movable member between two positions, the arrangement being such that when the movable member is in the first position it allows communication between the fluid passage and the housing cavity and when the movable member is in the second position it closes the connection between the fluid passage and the housing cavity, wherein the movable member is pressed towards its second position by a spring, wherein when the pressure inside the housing cavity is within the permissible range, the member is held in said second position to cut off the fluid passage and the washing a connection between the cavity, and when the pressure inside the housing cavity reaches a predetermined level, the movable member moves to said first position to establish a connection between the housing cavity and the fluid passage, characterized in that said movable member comprises a main piston axially movable in the master cylinder and a lower piston are interconnected, and the interior of the master cylinder is divided by a main piston into an atmospheric communication chamber communicating with the atmosphere and a housing cavity communication chamber communicating with the housing cavity, the interior of the lower cylinder being divided by a lower piston into a fluid passage communication chamber communicating with the fluid passage, the arrangement is such that when the internal pressure of the nest cavity reaches a predetermined value with respect to the atmospheric pressure, the lower piston is displaced by the compression spring and move the main piston to said first position to contact the housing cavity with the fluid passage, and to have means for damping the pressure drop in the control chamber while the main piston is in the first position, allowing the housing cavity pressure to drop to the fluid passage pressure level.

Thus, according to the ball valve described above, the connection between the fluid passage and the housing cavity is severed both in the case where the fluid pressure is higher than the pressure inside the housing cavity and in the case where the pressure inside the housing cavity is higher than the fluid pressure but within predetermined limits so that the self-pressing force acts on the seat stop. to seal the liquid and on the primary or secondary side. On the other hand, in the event that the pressure inside the housing cavity increases abnormally beyond predetermined allowable limits, this pressure acting on the control chamber uses a lower and main piston, allowing the housing cavity to communicate with the fluid passage through the primary chamber in the master cylinder.

According to another object of the present invention, there is provided a ball valve characterized in that said means for slowing down the pressure drop comprises an additional piston forming a movable wall of a guide piston moving in a closed chamber located on the opposite side of the additional piston to a control chamber containing a closed chamber. a gas at a specified pressure, wherein the piston moves into the closed chamber before the main piston moves from its second position to its first position.

Thus, when the pressure inside the nest cavity is within predetermined allowable limits, the connection between the fluid passage and the nest cavity is broken according to this ball valve so that a self-compressing force acts on the seat stop maximum, the piston rod in the reversing valve moves to the control chamber by applying the above pressure to communicate the fluid passage communication chamber with the small diameter communication port through the communication passage which communicates with the housing cavity so that the internal pressure in the housing cavity In addition, the diverter valve only reacts to the pressure inside the housing cavity, regardless of the fluid pressure.

Fig. 1 shows a section of the main part of a ball valve of the conventional single-shut-off type 15;

Figures 2 and 3 show sections of the main part of a conventional double-shut-off type ball valve;

Fig. 4 shows a section of the main part of a ball valve according to an embodiment of the present invention; Fig. 5 shows a section of the diverter valve used therein and its principle of operation;

Figures 6 and 7 show sections of structural examples of other diverter valves used in the ball valve of Figure 4; Fig. 8 is a sectional view of a main part of a ball valve according to another embodiment of the present invention;

Fig. 9 shows a section of the diverter valve used therein and its principle of operation; 8 81 661

Fig. 10 shows a section of a detailed structural example of a diverter valve; and

Fig. 11 shows a section of the main part of another structural example 5 of the diverter valve used in the ball valve according to Fig. 8.

Embodiments of the present invention are described in detail below with reference to the accompanying drawing.

Referring first to Fig. 4, there is shown a section of a ball valve main body 10 according to an embodiment of the present invention, in which an annular seat retainer 4 is arranged in the housing 1 around the fluid passage 3 and an annular valve seat 6 is mounted between the seat retainer 4 and the outer ring 5 attached thereto. on the other hand, the outer ring 5 is forced from behind the spherical closure member 15 by means of compression springs 7 fixed to the inner wall surface of the housing at predetermined intervals in the circumferential direction, the annular valve seal being brought into contact with the spherical closure surface to provide a seal between the seat

A stepped portion comprising a surface having a diameter D2 larger than the sealing point diameter of the valve seat 6 and a surface having a diameter D3 smaller than D3 is formed in the outer circumferential surface portion of the seat retainer 4 in which the seat retainer is in sliding contact with the inner wall surface of the housing 1. The larger and smaller diameter surfaces, which form a stepped portion, form a closed chamber in connection with the inner wall surface of the housing which is in sliding contact therewith. The closed chamber 30 acts as an O-ring groove 11 in which an O-ring 8 is placed to provide a seal between the housing 1 and the seat stop 4.

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The ball valve is further provided with a diverter valve 31. The diverter valve 31 is provided with a master cylinder 32 and a lower cylinder 33, and axially movable main piston 35 and lower piston 36, 5 are formed in these cylinders, which are integrally formed at the ends of the stem 34. The main piston 35 divides the interior of the master cylinder into a primary chamber 40 which communicates with the fluid passage 3 via line 44 and a secondary chamber 42 which communicates with the housing cavity 10 via lines 46 and 45. The lower piston 36 10 divides the interior of the lower cylinder into a communication chamber 41 which communicates with the primary chamber through an opening 37 and a control chamber 43 which communicates with the housing cavity via lines 48 and 45.

The master cylinder is further connected to a conduit 47 which communicates 15 primary or secondary chambers with the housing cavity via a conduit 45 depending on the operation of the main piston. When the fluid pressure is greater than the pressure inside the housing cavity and when the pressure inside the housing cavity is within predetermined allowable limits, the main piston is located on the right side 20 in the figure to disconnect the primary and secondary chambers, i.e. between the fluid channel and the housing cavity in the master cylinder.

In the lower cylinder, the lower piston 36 is moved towards the control chamber by means of a compression spring 38. The force 25 of the compression spring is adjusted so that the lower piston can operate or move to the left in the figure when the internal pressure P1 of the housing cavity is higher than allowed and reaches a predetermined level £ 3 '· The lower cylinder piston diameter d 1 is selected to be larger than the main cylinder 30 piston diameter d1. When the pressure inside the housing cavity reaches a predetermined level, the lower piston therefore shifts to the left in the figure against the action of the compression spring and activates the main piston in the primary chamber so that line 44 leading to the fluid passage communicates with line 47.

When the primary side fluid pressure is greater than the internal pressure P is set receptacle cavity of the master cylinder main piston May 34, therefore, the ball valve according to the fluid channel to the right side of Figure 4 and a contact receptacle cavity is cut off so that, as described above, the self-compressive force:

; <d2 - Di "pi - V

istukanpidäkkeen affect the back surface of the valve seat 10 therefore comes into contact with the spherical closing member on the primary fluid seal.

Also, in the case that the receptacle cavity 10 of the internal pressure P L is greater than the fluid pressure of the secondary liquid channel 3, but is within the allowable range, remains in the lower piston 15 still in position through 38 position, compression of the spring from the right-hand side, as shown in Figure 4, so that the itsepuristava force: π 2 2 - <D - D 2) "P3 - P2) acts on the secondary side istukanpidäkkeen rear surface of the liquid seal.

On the other hand, when the pressure inside the housing cavity 10 abnormally exceeds the allowable limits and reaches a predetermined level Pj '/ this pressure acts on the control chamber 43 and thus the lower piston moves to the left against the compression spring 38 as shown in Fig. 5 so that in the primary chamber communicates with line 44 leading to fluid passage 3; i. the housing cavity 10 communicates with the secondary fluid passage 3, whereby the pressure inside the housing cavity can be discharged to the secondary 11 81661 side, whereby the abnormal pressure increase is thus suppressed.

Since the receptacle cavity in this manner, it is placed in connection with the secondary side fluid channel of the internal pressure of 5 to rapidly reduce the change can be stabilized by the operation of the valve 31 configured by including a non-return valve 51 of the lead 48, as shown in Figure 6.

In the above description may be available in public areas receptacle cavity 10 make the secondary side with the fluid passage when the internal pressure exceeds the allowable limits and achieve a predetermined abnormal value. In this case, the receptacle cavity can be placed on the primary side connection fluid channel.

Referring now to Fig. 7, there is shown a section of another example of a diverter valve 31 used in the above ball valve, in which a communication chamber 50 not communicating with the primary cylinder primary chamber 40 but communicating with outside air through the opening 49 is formed in the lower cylinder instead of the communication chamber 41.

Its mode of operation is exactly the same as that of the reversing valve just shown, except that the communication chamber 50 is brought into contact with the outside air instead of being pressurized to the same pressure as the primary chamber.

25 When the pressure inside the housing cavity increases abnormally, the housing cavity of the ball valve according to the above embodiment is brought into contact with the fluid passage by applying this pressure in the diverter valve, whereby the abnormal pressure increase in the housing cavity can be suppressed.

Another embodiment of the present invention 12 81 661 will now be described with reference to Figures 8-11.

Referring to Fig. 8, there is shown a section of the main part of a ball valve according to another embodiment of the invention, in which an annular seat holder 4 is arranged in the housing 1 around the fluid passage 3 and an annular valve seat 2 is fitted between the seat holder 4 and the outer ring 5 attached thereto. The outer ring 5 is forced towards the ball behind it by means of compression springs 7 fixed to the inner wall surface 10 of the housing at predetermined intervals in the circumferential direction, whereby the annular valve seat is brought into contact with the ball surface to provide a seal between the seat stop and the ball.

A stepped portion comprising a surface having a diameter greater than the sealing point diameter of the valve seat 6 and a surface having a diameter less than a sealing diameter is formed in the outer circumferential surface portion of the seat stop 4 in which the seat stop 15 is in sliding contact with the inner wall surface of the housing 1. These larger and smaller diameter surfaces, which form a stepped portion, form a closed chamber in connection with the inner wall surface of the housing which is in sliding contact therewith. This closed chamber acts as an O-ring groove 11 in which an O-ring 8 is placed to provide a seal between the housing 1 and the seat stop 4.

A ball valve according to this embodiment is provided with a diverter valve 31. The diverter valve 31 comprises a cylinder 34 having a smaller diameter portion 32 having a diameter d1 and a larger diameter 33 having a diameter d2, the smaller diameter portion 32 communicating with the housing cavity 10 through a connection port 51 and 13 81 661 thereafter via lines 61 and 62. The cylinder 34 has an axially movable piston rod 35. In the small diameter portion 32 of the cylinder, the piston rod has a small diameter piston 36 having an end face diameter 5 in the small diameter cylinder portion d1 # to form a housing cavity communication chamber 37 which communicates with the housing cavity 51. In the small diameter cylinder portion, the piston rod is further provided with an annular connection opening 38 formed on its circumferential surface 10 communicating with the fluid channel connection colony 41 via the connection channel 46, as will be explained later.

In the large diameter portion 33 of the cylinder, the piston 35 is provided with a first large diameter 15 piston 39 having a diameter d2 formed at the end opposite to the above-described small diameter piston end surface and formed with a guide housing 43 connected to line 52. , via line 64 and flow check valve 20 to 49 and is thus connected to the nest cavity. The flow check valve 49 may be mounted inside the cylinder 34. The piston rod further has a second large diameter piston 44 having a diameter d2 and located adjacent to the large diameter piston 39 25, and an annular fluid passage communication chamber 41 having an inner diameter d1 is formed in the large diameter portion of the cylinder between the first and second large diameter pistons. in connection with the liquid channel 3 via the connection opening 53 and the line 63. A communication channel 46 is formed inside the stem 35 of the piston-30 to provide a connection between the communication chamber 41 of the liquid channel and the communication opening 38.

The second large diameter piston 44 further defines and forms a normal pressure arm 42 having an inner diameter d 1 in a large diameter portion of the cylinder and separate from the control chamber 43. A normal pressure chamber 42 communicating with the outside air through a connection port 54 is provided with a compression spring 47. forces a second large diameter piston 44 toward the control chamber 43. When the pressure P 1 inside the housing cavity is within predetermined allowable limits, the compression spring 47 keeps the piston rod 35 in the right-hand end position, as shown in the figure.

In this position of the piston rod, the connection between the connection opening 51 communicating with the housing cavity 10 and the connection opening 38 in the piston rod is broken by a wall of a small diameter cylinder part to disconnect the fluid passage communication chamber 41 and the housing cavity 10 15.

The strength of the compression spring 47 is selected so that when the pressure inside the housing cavity P 1 exceeds predetermined permissible limits and reaches a predetermined level P 1, the piston rod can be moved towards the housing cavity contact chamber 37, 20, i.e. to the left in the figure, by a small diameter piston 36 and diameter 36 the effect of the pressure difference between the pressures acting. When the pressure inside the housing cavity reaches a predetermined level, the piston rod 35 accordingly moves to the left against the action of the compression spring 47 until the connection opening 38 aligns with the connection opening 51 of the small diameter part 32 of the cylinder, as shown in Fig. 9.

In this way, the fluid channel communication chamber 41 is connected to the communication port 51 via the communication channel 46 and then to the housing cavity 10 via the lines 61 and 62.

Therefore, in the ball valve of this embodiment, the reversing valve reacts only to the pressure ib 81661 inside the housing cavity. More specifically, if the pressure inside the housing cavity is within predetermined limits, the piston rod is in the displaced position and remains in place to the right by the compression spring 46, as shown in Figure 8, so that a self-compressing force acts on the seat retainer to seal the fluid.

In the event that the pressure inside the housing cavity abnormally increases above predetermined limits and reaches a predetermined level P 1, this pressure acts on the control chamber 43, the piston rod moving to the left against the compression spring 47 as shown in Fig. 9 so that the fluid channel communication chamber 41 is passed through the channel 46 in communication with the connection port 51 in communication with the housing cavity, whereby the pressure 15 inside the housing cavity may be released into the fluid passage to suppress the abnormal pressure increase.

Although the housing cavity contacts the fluid passage in this manner and its internal pressure therefore decreases, the diverter valve 31 continues to operate smoothly because the control chamber 20 is connected to the line 62 through the flow check valve 49 as described above.

Fig. 10 shows a section of a detailed structural example of the diverter valve shown in Fig. 8.

In the diverter valve 101 shown in Fig. 10, an inner cylinder 25 103 is fitted to an outer cylinder 102, the inner cylinder forming a cylinder comprising a small diameter cylinder portion 104 and a large diameter cylinder portion 105. This cylinder has an axially movable piston rod 107. The piston rod 107 is provided with a diameter an end surface having a diameter d1 is directed towards the interior of the small diameter cylinder part. By means of the small diameter piston 106, a connecting chamber 108 of the housing cavity is defined in the small diameter cylinder part 16 by 16 81 661. The nest cavity communication chamber 108 is connected through a connection port 109 to a conduit 62 which communicates with the nest cavity. The end face of the piston rod is further provided with a notch 115 for maintaining communication between the connection opening 109 and the housing cavity communication chamber 108 although the piston rod operates as a result of an abnormal increase in pressure inside the housing cavity and comes into close contact with the mouth of the cylinder opening 109.

An annular flow control chamber 111 is formed between the outer wall of the small diameter cylinder portion 104 and the outer cylinder 102 around the communication chamber of the housing cavity. The flow control chamber 111 is connected to the connection chamber 108 of the housing-cavity in two ways, i.e. through the connection opening 112 and the connection opening 113, which are formed in the small diameter cylinder part. For the flow control chamber, a more detailed explanation will follow later.

The large diameter cylinder portion 105 has a piston rod 107 at its end opposite the nest cavity connecting chamber, provided with a large diameter piston 121 defining a guide chamber 122. A connecting passage 123 is formed in the piston rod which opens from one end to the nest cavity connecting chamber 108 and the other 122 through the non-return valve 126, the non-return valve 126 being supported by a spring support 125 having a connection opening 124. The communication channel 123 establishes a connection between the communication chamber 108 and the control chamber 122 of the housing cavity. The spring support 125 is supported by the cylinder base 114 through the arm 127.

A flow control passage 17 81 661 131 is formed in the inner cylinder 103, extending from the control chamber 122 to the flow control chamber 111. A flow control valve 132 is located in the end portion of the flow control channel 131 which opens to the flow control chamber 111. when adjusted by the flow control valve 132. The valve 132 is actuated, for example, by a lock nut 133 located outside the outer cylinder.

The piston rod is further provided with a second large diameter piston 141 located near the first large diameter piston 105. A fluid passage communication chamber 142 is formed in the large diameter cylinder portion between the first and second large diameter pistons 121 and 141, the chamber 142 communicating with the fluid 15 channel 145 and 146.

A communication passage 143 is also formed in the piston rod, which at one end opens into the fluid passage communication chamber 142 and at the other end is connected to an annular connection opening 144 formed in the circumferential surface of the piston rod 20 in a small diameter cylinder portion.

The second large diameter piston 141 further defines a normal pressure chamber 151 in a large diameter cylinder portion separate from the control chamber 122. The normal pressure chamber 151 communicates with the outside air through the connection ports 152 and 153. Mounted in the normal pressure chamber 151 is a compression spring 154 which acts on the second large diameter piston so as to move the piston rod to its extreme right position as shown in the figure when the pressure inside the housing cavity is within predetermined allowable limits, disconnecting the fluid passage between the chamber 142 and the housing.

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The strength of the compression spring 154 is adjusted so that as the pressure inside the housing cavity increases to predetermined allowable limits and reaches a predetermined level P 1, the piston rod can be operated and moved to the left toward the housing cavity communication chamber 108 in the figure. When the pressure inside the housing cavity reaches a predetermined level P 1, the piston rod moves to the left against the action of the compression spring 154, whereby the connection opening 144 can align with the connection opening 113 so that the fluid channel communication chamber 142 communicates with the connection port 113 via the communication channel 143. 108 and through the connection opening 109. The compression spring 154 can be placed in the normal pressure chamber in the cylinder in any suitable position.

A reversing valve of the above type operates in the following manner.

When the internal pressure P 1 of the housing cavity 10 is within predetermined allowable limits, the piston rod 107 resiliently stays in place in its extreme right position as shown in Fig. 8 and the internal pressure of the housing cavity conducted from the non-return-25 through the valve 126 and partly from the connection chamber of the housing cavity to the flow control chamber 111 through the connection opening 112 and the connection opening 113. On the other hand, the fluid pressure of the fluid passage is transferred to the fluid passage communication chamber 142 through the communication port 146 of the outer cylinder and the communication port 145 of the large diameter cylinder portion 30. In this case, the fluid pressure has no effect on the operation of the piston rod because the fluid passage communication chamber 142 is formed on the piston rod and the normal pressure chamber has no effect on the piston rod 19 81 661. When the internal pressure of the receptacle cavity is predetermined allowable range is thus connected to the receptacle cavity from the fluid channel, so that the itsepuristava istukanpidäkkeen force acts on the rear surface as described above is shown in 5, which results in that the valve seat seals the primary or secondary side fluid.

On the other hand, if the pressure inside the housing cavity 10 increases abnormally beyond predetermined allowable limits and reaches a predetermined level, the pressure of the first large diameter piston in the control chamber 10 and the difference of the pressure 2 in the housing cavity contact chamber 2 (lä2 - -p, 3 4 compression spring 154 so that the piston rod 15 moves to the left in the figure, whereby the connecting passage 144 of the connecting passage in the piston rod can align with the connecting passage 113 of the small diameter cylinder part. As a result, the housing cavity is brought into contact with the fluid passage pur-20 falls on the liquid channel side to suppress abnormal pressure rise.

When the pressure inside the housing cavity is discharged in this way, the non-return valve 126 prevents the internal pressure of the control chamber 122 from being released back into the communication chamber 25 of the housing cavity through the communication channel 123 in the piston rod. The flow control valve 132 also prevents re-discharge through the communication passage 131 to the flow control chamber 111. Therefore, the pressure inside the housing cavity transferred to the control chamber is maintained for a certain period of time. Thus, the pressure inside the housing cavity 30 can be completely released because the compression spring does not immediately return the piston rod to its original extreme position on the right.

Reference is now made to Fig. 11, which is a sectional view of the main part of another structural example of a changeover valve included in the ball valve of this embodiment, in which the same components as those shown in Fig. 10 are provided with the same reference numerals. This diverter valve comprises the components of the diverter valve of Figure 10 as well as a few additional members, for which reason only the additional members will be explained below.

In the diverter valve shown in Fig. 11, the outer cylinder 102 extends past the control chamber 122, and the outer cylinder and the cylinder base 202 form a gas shut-off chamber 203.

The arm 204 supporting the spring support 125 is extended to and attached to the bottom 202 of the cylinder, and a movable piston 201 is attached to the arm 204 15 to form a partition between the control chamber and the gas barrier chamber. Gas is supplied to the gas-closing chamber 203 at a suitable pressure according to a predetermined pressure level P 1 '.

This diverter valve works as follows. As the pressure inside the housing cavity 20 increases and moves into the control chamber, the pressure inside the control chamber increases and at the same time the moving piston moves towards the bottom of the cylinder, i.e. right in the figure, while increasing the pressure inside the gas chamber to equilibrate with the pressure inside the control chamber. And when the pressure inside the nest cavity reaches a predetermined level, it is contacted with the fluid channel communication chamber 142 and discharged. In this case, the pressure in the control chamber is also reduced, but the gas barrier chamber expands because the gas in the gas barrier chamber is a compressible liquid medium so that the movable piston moves towards the control chamber due to the pressure reduction in the same chamber 21 81661. In addition to preventing the pressure relief of the check valve 126 and the flow control valve 132, the variable volume gas barrier chamber adjacent the control chamber effectively prevents the pressure in the control chamber from decreasing in the fluid passage and thus preventing the piston rod 107 from rapidly returning to its original position. As a result, the operation of the piston rod 10 is stabilized and the pressure inside the housing cavity is completely released.

This diverter valve is particularly effective when the liquid medium to be transferred is an incompressible liquid. Since, in the case of a liquid, the pressure of the amount of liquid in the control chamber 15 decreases relatively rapidly when the pressure inside the housing cavity is discharged into the liquid passage, but the gas barrier chamber expands so that the pressure reduction is prevented by the control chamber contraction.

As the pressure inside the housing cavity increases abnormally, the housing cavity is brought into contact with the fluid passage according to the double-closing type ball valve of the present invention by applying this pressure in the reversing valve, thereby suppressing the abnormal pressure increase in the housing cavity.

In addition, forming a gas barrier chamber defined by the movable piston adjacent the control chamber prevents a pressure drop in the control chamber when the pressure inside the housing cavity is released to ensure effective release of such internal pressure.

Claims (3)

A ball valve with a valve housing (1), a movable ball-shaped closure means (2) for opening and closing a liquid channel (3, 63) in the valve housing (1), one between the movable ball-shaped closing member (2) and the valve housing (1) ) formed valve housing cavity (10), an annular seal (5) separating valve housing cavity (10) from liquid channel (3, 63), and a reversing valve (31, 101) for selectively interconnecting valve housing cavity (10) and fluid channel (3) , 63) so that liquid co-flows from the valve housing cavity (10) to the fluid channel (3, 63) as the internal pressure (P3) of the valve housing cavity reaches a predetermined level (P31), the reversing valve (31, 101) comprising an axial between two positions. movable member (35, 106), the device being such that the movable member (35, 106) is in a first position, allowing a connection between the fluid passage (3, 63) and the valve housing cavity (10) and the movable member (35, 106) is located within a second position, it closes the connection between the fluid passage (3, 63) and the valve housing cavity (10), the movable member (35, 106) being pressed against its second position with a spring (47, 154), the valve housing cavity (P3) being internal pressure is within permissible limits, the means (35, 106) is held in said second position to interrupt the connection between the fluid passage (3, 63) and the valve housing cavity (10), and the internal pressure (P3) of the valve housing cavity (10) reaches a predetermined level (P3 ·), the movable member (35, 106) is displaced to said first position to form a connection between the valve housing cavity (10) and the fluid passage (3, 63), characterized in that said movable member comprises a a main cylinder (32, 104) axially movable main piston (35, 106) and a axially movable lower piston (39, 121) in a subcylinder (33, 105), the main piston (35, 106) and the lower piston (39, 121) being together -connected, and the interior space of the main cylinder (32, 104) is divided by means of the main piston (35, 106) into an atmospheric communication chamber (42, 50, 151) communicating with the atmosphere and a valve housing cavitation communication chamber (37, 108) communicating with the valve housing cavitation (10), the inner space of the sub-cylinder (33, 105) is divided by means of the sub-piston (39, 121) into a liquid channel communication chamber (41, 142) communicating with the liquid channel (3, 63) and a control chamber (43, 122) communicating with the valve housing cavitation (10), the device being such when the internal pressure (P3) of the valve body cavitation reaches a predetermined value (P31) in relation to the atmospheric pressure, the lower piston (39, 121) is displaced against the action of the compression spring (47, 154) and displaces the main piston (35, 106) to said first position said valve housing cavity (10) communicates with fluid passage (3, 63) and has means (49, 132, 203) for delaying pressure in the control chamber (43, 122) of the main piston a 27 81 661 (35, 106) is in its first position, whereby the pressure of the valve housing cavitation (10) may drop to the level of the pressure of the liquid channel (3, 63). Ball valve according to claim 1, characterized in that said means (49, 132, 203) for delaying the pressure drop comprises an additional piston (201) which forms the movable wall of the control chamber (122), (201) moves in a closed chamber (203) which is located on the opposite side of the auxiliary piston (201) in relation to the control chamber (122), which closed chamber (203) contains a gas which starts during a predetermined period. compressed pressure (P3), the piston (201) moving into the closed chamber (203) before the main piston (35, 106) moves from its second position to its first position. Ball valve according to claim 2, characterized in that the means (49, 132, 203) for delaying said pressure drop further comprise a control valve (49) or a flow control valve (132) between the control chamber (43, 122) and the valve housing cavitation ( 10).