JP3130751U - Shut-off valve - Google Patents

Abstract

PROBLEM TO BE SOLVED: To reduce the size of a shut-off valve by eliminating the need for a strong member as an elastic member for urging a valve rod in the valve closing direction.
SOLUTION: A valve box 1 having an oil flow path and a valve seat 2, a valve body 3, a valve rod 4, an elastic member 5 for biasing the valve rod 4 in a valve closing direction, and a valve rod The shut-off valve provided with the valve stem lock means 6 that locks 4 and maintains the valve box open state includes a first cylinder portion 7 that houses at least a part of the valve stem 4 and a gas supply portion. The gas supply part supplies compressed gas into the first cylinder part 7 from the other to urge the valve stem 4 in the valve closing direction, and is elastic by releasing the lock of the valve stem lock means 6. The valve rod 4 is moved in the valve closing direction by using the pressure of the gas together with the urging of the member 5.
[Selection] Figure 1

Description

  The device of the present application relates to an improvement of a shut-off valve.

  For example, a conventional general oil tank emergency shut-off valve for a ship, which is defined in FIG. 1 (page 4 / wire type ball valve-structure, shape) of JIS F7399: 2002 (marine oil tank emergency shut-off valve), 6, an oil (fluid) flow path (the flow of oil is indicated by a one-dot chain line arrow in FIG. 6) and a valve box j1 having a valve seat j2 are seated on the valve seat j2. Valve body j3 that closes and shuts off the flow path, valve stem j4 provided with valve body j3, and valve stem lock means that locks valve stem j4 and maintains the valve-opened state of valve box 1 The valve rod j4 is urged in the direction (downward) to close the valve body j3 by the spring j5 (FIG. 6 shows the valve open state. A part of hatching to be attached to is omitted in order to avoid complicated drawing). Further, as shown in FIG. 6, in the valve box j1, the valve body j3 is located on the downstream side (upper side) of the oil passage from the valve seat j2, and when the valve is closed, Side (downward) and seated on the valve seat j2.

More specifically, in the conventional shut-off valve shown in FIG. 6, a spring j5 disposed between a valve stem support bracket fixed to the valve box j1 via a support and a spring receiver provided on the valve stem j4, The spring receiver is biased toward the valve box j1 side (downward), and the valve body j3 is seated on the valve seat j2 provided below the valve body j3 in the valve box j1.
On the other hand, the conventional valve stem locking means used in this shut-off valve has a lever j6 that is fixed to the valve stem support bracket by an operating shaft, and a recess (not shown) provided on the side surface of the valve stem j4. It consists of. A recess (not shown) is also formed on the peripheral surface of the operating shaft. In the valve open state, the peripheral surface of the operating shaft is in contact with the concave portion of the valve stem j4 at a portion other than the recess to lock the valve stem j4. When the valve is closed, the operating shaft is rotated by operating the lever j6, and the recess is made to correspond to the recess of the valve rod j4 to release the lock, and the valve rod j4 is closed by the bias of the spring j5. Advance in the valve direction.

As described above, in such a conventional shut-off valve, the urging of the valve rod j4 in the valve closing direction relies exclusively on the spring j5. Therefore, in the above-described shut-off valve, the higher the pressure of the fluid passing through the valve box j1, that is, the oil that the valve is to shut off in an emergency, the higher the pressure, the more the spring j5 is closed. Therefore, a strong force is required, and the spring j5 has to be bulky. For this reason, the bulk became large as a whole valve.
Further, in the valve opening work at the time of restoration, the stronger the spring j5, the more work is required.
Furthermore, since the required spring strength varies depending on the pressure applied to the fluid, it is necessary to manufacture a valve using a spring having a different strength depending on the required valve performance.
In addition, in the description of this background art, JIS F7399: 2002 (Appendix 1 to 4 and Appendix 5) is used for a configuration (terms other than "valve stem locking means", "recess" and "recess") without symbols. Please refer to.

  The present invention does not require a conventional strong spring for energizing the valve stem to act on the valve closing direction by using compressed gas to energize the valve stem. It was possible to reduce the bulk of the spring and to solve the above problems.

The first device of the present application forms a flow path for a fluid such as oil and has a valve box 1 provided with a valve seat 2, and a valve element 3 that closes and shuts off the flow path by being seated on the valve seat 2. The valve rod 4 provided with the valve body 3, the elastic member 5 for urging the valve rod 4 in the closing direction, and the valve rod lock means for locking the valve rod 4 and maintaining the valve box open state. 6 includes a first cylinder portion 7 that accommodates at least a part of the valve stem 4 and a gas supply portion 8, and the gas supply portion 8 is compressed into the first cylinder portion 7 from the others. Gas is supplied to urge the valve stem 4 in the valve closing direction. By releasing the lock of the valve stem lock means 6, the pressure of the gas is utilized together with the urging of the elastic member 5. What is characterized by moving the rod 4 in the valve closing direction is provided.
The gas here includes air.

  In the second device of the present application, in the first device of the present application, the valve stem locking means 6 includes a pin 61 that contacts the valve stem 4 and locks the valve stem, and the valve stem locking means 6 is A shut-off valve that releases the lock of the valve stem 4 by releasing the pin 61 from the valve stem 4 using the pressure of the compressed gas is provided.

The third device of the present application is the above-described second device of the present application, and provides a shut-off valve having the following configuration.
That is, the valve stem 4 includes a first piston portion 47 that moves the valve stem 4 in the valve closing direction under pressure of the compressed gas in the first cylinder portion 7. A second cylinder portion 63 that accommodates the pin 61 and guides the movement of the pin 61 is provided on the outer peripheral portion of the first cylinder portion 7. The pin 61 includes a second piston portion 65 that moves the pin 61 under pressure of the compressed gas within the second cylinder portion 63. The side surface of the valve stem 4 is provided with a pin receiving portion 62 that retreats in the radially inward direction of the valve stem 4 at least in a portion arranged in the first cylinder portion 7 when the valve is closed. The valve stem locking means 6 locks the valve stem 4 by inserting the tip of the pin 61 into the pin receiving portion 62 of the valve stem 4. The gas supply unit 8 includes a connection unit that connects the second cylinder unit to a compressed gas supply source, and a passage that connects the second cylinder unit 63 and the first cylinder unit 7. The gas supply unit 8 introduces compressed gas into the second cylinder unit 63 from the other through the connection unit, thereby pressurizing the second piston unit 65 to detach the pin 61 from the valve stem 4 and through the passage. The gas is supplied from the second cylinder portion 65 into the first cylinder portion 7 to pressurize the first piston portion 47 and urge the valve rod 4 in the valve closing direction.

  In the fourth device of the present application, in the third device of the present application, the valve body 3 is located on the upstream side of the flow path from the valve seat 2 and moves to the downstream side when the valve is closed to the valve seat 2. Provided is a shut-off valve characterized by being seated.

The fifth device of the present application is the fourth device of the present application, and provides a shut-off valve having the following configuration.
That is, this shut-off valve is a marine oil tank emergency shut-off valve, and the inside of the valve box 1 includes a partition wall 10 separating the upstream side and the downstream side of the fluid passage, and the partition wall 10 includes an upstream side and a downstream side. An opening 11 that communicates with the side is provided. The valve seat 2 is provided on the surface 12 facing the upstream side of the partition wall 10, and the valve body 3 is seated to close the opening 11 and close the valve. The first cylinder portion 7 is arranged with a certain distance from the valve box 1. The valve box 1 includes a through portion 13 that penetrates from the inside of the valve box 1 to the outside of the valve box 1 on the upstream side of the partition wall 10. The valve rod 4 is formed separately from the first rod-shaped portion 41, the first rod-shaped portion 41, the first rod-shaped portion 41 being inserted into the valve box 1 from the penetrating portion 13 and being exposed to the outside from the valve box 1. And a second rod-shaped portion 42 connected to the rear end side of the one rod-shaped portion 41. The valve body 3 is provided in the portion of the first rod-shaped portion 41 inserted into the valve box 1, and the portion exposed to the outside from the valve box of the first rod-shaped portion 41 is biased by the elastic member 5. A force receiving portion 45 is provided. The pin receiving portion 62 is formed in an annular shape along the circumferential direction of the second rod-shaped portion 42 on the outer peripheral surface of the second rod-shaped portion 42. A first piston portion 47 is provided on the second rod-shaped portion 42, and a handle 49 is provided at the rear end of the second rod-shaped portion 42. Either one of the first rod-shaped portion 41 and the second rod-shaped portion 42 is provided with a male screw 43, and either one is provided with a female screw 44 that is screwed with the male screw 43, and the male screw 43 is screwed into the female screw 44. By doing so, the connection of the second rod-shaped portion 42 to the first rod-shaped portion 41 is made. When the valve is closed, the first rod-shaped portion 41 is advanced in the valve closing direction along with the second rod-shaped portion 42 by urging the elastic member 5 and pressurizing the compressed gas. When the operation is restored, the second rod-shaped portion 42 is rotated with respect to the first rod-shaped portion 41 by operating the handle 49, and the male screw 43 is relatively loosened from the female screw 44, thereby being in the valve-closed position. The second rod-like portion 42 is returned to the position at the time of opening the valve while leaving the first rod-like portion 41, and the advancement / retraction of the second rod-like portion 42 restored to the position at the time of opening the valve is fixed by inserting a pin into the pin receiving portion 62. Thereafter, the second rod-shaped portion 42 is reversely rotated by the reverse operation of the handle 49, and the male screw 43 is relatively screwed in a direction to be fastened to the female screw 44, whereby the first against the biasing of the elastic member 5 is performed. The rod-like portion 41 is returned to the position at the time of valve opening, and is restored to the valve opening state.
Note that “relatively” means that either the case where the female screw 44 is screwed (turned) with respect to the male screw 43 or the case where the male screw 43 is screwed (turned) with respect to the female screw 44 may be used. .

The sixth device of the present application is the fifth device of the present application, and provides a shut-off valve having the following configuration.
That is, the first cylinder portion 7 includes a sub bias receiving portion 46, and the elastic member 5 is a compression spring interposed between the bias receiving portion 45 and the sub bias receiving portion 46. The receiving part 45 and the sub bias receiving part 46 are urged away. The penetrating portion 13 of the valve box 1 includes a packing 14 that maintains liquid-tightness between the valve stem 4 and the valve box 1, and the gap between the inner peripheral surface of the penetrating portion 13 and the outer peripheral surface of the first rod-shaped portion 41. And a packing housing portion 15 in which the packing 14 is disposed. The packing housing portion 15 includes an insertion port 15a for the packing 14 that opens from the surface of the valve box 1 to the outside of the valve box 1, and a lid 15b that closes the insertion port 15a. The lid 15b is formed in an annular shape, and the first rod-like portion 41 is inserted through the center of the lid 15b. A gap is provided between the lid 15b with the insertion port 15a closed and the biasing receiving portion 45, and the lid 15b is slid along the first rod-shaped portion 41 toward the biasing receiving portion 45. Thus, the insertion port 15a can be opened. The packing 14 is formed in a C-shape, and is arranged annularly along the periphery of the first rod-shaped portion 41 by being inserted into the packing accommodating portion 15 from the insertion port 15a. The pin receiving portion 62 is provided on the outer peripheral surface of the first piston portion 47. The first cylinder part 7 includes a first through-hole 71 that penetrates from the inside of the first cylinder part 7 to the outside at the rear end of the first cylinder part 7, and a first cylinder part 7 at the side part of the first cylinder part 7. A second through hole 72 penetrating from the inside to the outside and a third through hole 73 penetrating from the inside of the first cylinder part 7 to the outside behind the first piston part 47 to be accommodated are provided. The second rod-shaped portion 42 includes a support shaft 48 that supports the handle 49, and the handle 49 is disposed outside the first cylinder portion 7 by inserting the support shaft 48 through the first through hole 71. The second cylinder part 63 is provided at a position corresponding to the second through hole 72 on the side surface of the first cylinder part 7, and the tip of the pin 61 is received by the pin of the first piston part 47 through the second through hole 72. A secondary elastic member 64 that urges the pin 61 toward the second through hole 72 is accommodated in the second cylinder portion 63. A side portion of the second cylinder portion 63 includes a through hole that is provided on the distal end side of the pin 61 from the second piston portion 65 to be accommodated and penetrates from the inside of the second cylinder portion 63 to the outside. The third through hole 73 of the first cylinder part 7 and the through hole are connected to each other, and a connecting pipe constituting the passage is provided. By connecting a compressor, which is a compressed gas supply source, to the connecting portion, and operating the compressor to supply the compressed gas from the connecting portion into the second cylinder portion 63 and sliding the second piston portion 65. The pin 61 can be removed from the pin receiving portion 62, and the compressed gas in the second cylinder portion 63 can be supplied into the first cylinder portion 7 through the connecting pipe.

Inventions 1-6 of the present application do not require a strong spring like a conventional spring as an elastic member that urges the valve stem to act in the direction of closing the valve by using compressed gas, It was possible to reduce the bulk of the elastic member. As a result, the shut-off valve can be made compact without enlarging the bulk of the shut-off valve, and the shut-off valve can be widely used even in a limited installation space.
That is, conventionally, a spring that has been required as a biasing means for moving the valve stem in the valve closing direction can be used at least with a smaller pressing force than the conventional spring, and the bulk of the shut-off valve is reduced. be able to.
In addition, by eliminating the need for a conventional strong spring for the elastic member, it is possible to smoothly open the valve without requiring a large force as in the prior art.
Furthermore, it is possible to adjust the pressure of the compressed gas according to the fluid pressure, and because the flow pressure is different, it is not necessary to manufacture a valve each time using elastic members having different strengths. .

  In particular, the second device of the present application releases the lock by adopting a valve rod locking means that uses the compressed gas, which is different from the conventional mechanical type. In conjunction with energization, we provided a shut-off valve that closes smoothly when shut off.

  Further, in the third device of the present application, more specific means using the compressed gas for biasing the valve rod is provided to unlock the valve rod.

  In the fourth device of the present application, when the valve is opened, the valve body is positioned on the upstream side of the fluid from the valve seat, so that when the valve is closed, the flow of the fluid is reduced without countering the flow of the fluid. It was used for seating on the valve seat. That is, in the fourth device of the present application, the flow pressure of the fluid flowing in the valve box does not become the resistance of the valve closing operation, and conversely, the fluid flowing in the valve box is directed toward the seat of the valve body when the valve is closed. Compared with the conventional shut-off valve in which the valve body is arranged on the downstream side of the valve seat, the urging force with respect to the valve stem required when the valve is closed can be reduced. The spring (elastic member) required as a biasing means for the single-layer valve stem can be made compact, and the bulk of the entire shut-off valve can be further reduced.

  In the fifth device of the present application, in particular, in a marine oil tank emergency shut-off valve, the above effect is obtained, and more specific means suitable for a marine oil tank emergency shut-off valve are provided. That is, the valve rod is composed of the first rod-shaped portion and the second rod-shaped portion. When the valve is closed, both the rod-shaped bodies are advanced in the valve closing direction, and the second operation is performed by operating the handle when the valve is restored. After the rod-like portion is restored to the opened state prior to the first rod-like portion, the first rod-like portion can be restored to the opened state by reverse operation of the handle.

In the sixth device of the present application, it is possible to replace the packing that maintains liquid tightness between the valve box and the valve stem without disassembling the valve box. In particular, when the shut-off valve is used, the packing can be replaced at least when the shut-off valve is open.
Furthermore, a more specific means for actuating the pin of the valve stem locking means was provided.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
1 to 5 show an embodiment of the present invention. FIG. 1 is an overall longitudinal sectional view showing the open state of a marine oil tank emergency shutoff valve according to an embodiment of the present invention. 2 is an enlarged partially cutaway cross-sectional view of the main part of FIG. FIG. 3 is an overall longitudinal sectional view showing a closed state of the shut-off valve shown in FIG. 4 is an enlarged partially cutaway cross-sectional view of the main part of FIG. FIG. 5 is an overall longitudinal sectional view showing the shut-off valve in the middle of returning from the closed state of FIG. 3 to the open state of FIG.
In addition, a part of hatching which should be attached | subjected to drawing is abbreviate | omitted in order to avoid the complexity of drawing.

As shown in FIGS. 1 and 2, this shut-off valve includes a valve box 1, a valve body 3, a valve stem 4, an elastic member 5, a valve stem locking means 6, a first cylinder portion 7, and a gas supply. Part 8.
Hereinafter, the configuration of each unit will be described in detail.

The valve box 1 constitutes an oil flow path and includes a valve seat 2.
The inside of the valve box 1 includes a partition wall 10 that separates an upstream side and a downstream side of an oil passage (in FIG. 1, the direction of fluid, that is, the flow of oil is indicated by a one-dot chain line arrow). An opening 11 is provided to connect the upstream side and the downstream side. The valve seat 2 is provided on the surface 12 facing the upstream side of the partition wall 10, and the opening 11 is closed when the valve body 3 is seated, and the oil flow path is shut off and the valve is closed. The valve body 3 is positioned upstream of the valve seat 2 in the oil flow path in the valve box 1, and moves to the downstream side of the oil flow path and is seated on the valve seat 2 when the valve is closed.

As shown in FIG. 1, in the example of the shut-off valve, the partition wall 10 is disposed substantially horizontally. The upper side of the partition wall 10 is the upstream side of the fluid (oil) flow path, and the lower side of the partition wall 10 is the downstream side of the fluid (oil) flow path.
Further, the valve box 1 includes a through portion 13 that penetrates from the inside of the valve box 1 to the outside of the valve box 1 on the upstream side of the partition wall 10.
The through portion 13 is formed on the upper surface of the valve box 1. Specifically, the valve box 1 is open to the outside at the top, and is closed by a lid member 1a that is bolted to the opening, and a through-hole 13 is formed in the lid member.

  The penetrating part 13 has a packing 14 that keeps the liquid-tightness between the valve stem 4 and the valve box 1, and a packing housing that arranges the packing between the inner peripheral surface of the penetrating part and the outer peripheral surface of the first rod-like part. Part 15. The packing housing portion 15 includes an insertion port 15a for the packing 14 that opens from the surface of the valve box to the outside of the valve box, and a lid 15b that closes the insertion port 15a.

The valve body 3 is provided on the valve stem 4 formed separately from the valve box 1.
In this embodiment, the valve stem 4 extends in the vertical direction and operates in the vertical direction to open and close the valve body 3. ) Is called progression, and movement in the valve opening direction (upward) is called backward. The lower end of the valve stem 4 is the tip of the valve stem, and the upper end of the valve stem 4 is the rear end of the valve stem 4.
The first cylinder portion 7 accommodates a part of the valve stem 4 and guides the advancement and retraction of the valve stem 4. The first cylinder portion 7 is fixed to the valve box 1 via a stay (not shown), and is arranged at a certain interval with respect to the valve box 1. That is, the stay is a support column that supports the first cylinder portion 7 above the valve box 1.

The rear end side of the valve stem 4 is exposed above the valve box 1 from the through portion 13.
Specifically, the valve rod 4 is formed separately from the first rod-like portion 41, the first rod-like portion 41 having the front end side inserted into the valve box 1 from the through portion 13 and the rear end side exposed from the valve box 1 to the outside. And a second rod-like portion 42 connected to the rear end side of the first rod-like portion 41.
The said valve body 3 is provided in the part inserted in the valve box 1 of the 1st rod-shaped part 41. As shown in FIG.
A male screw 43 is provided on a portion of the first rod-like portion 41 exposed from the valve box 1 to the outside (that is, the outer periphery of the rear end portion). A screw hole is formed at the tip of the second rod-shaped portion 42, and a female screw 44 is formed in the screw hole. By inserting the rear end side of the first rod-shaped portion 41 into the screw hole of the second rod-shaped portion 42 and screwing the male screw 44 to the female screw 43, the first rod-shaped portion 41 and the second rod-shaped portion 42 are Connect as described above.
Contrary to the above, a threaded hole is formed in a portion (rear end surface) of the first rod-shaped portion 41 that is exposed from the valve box 1 to the outside, and a female screw 44 is formed. The outer periphery of the tip portion may be formed with a male screw 43 to connect the first rod-shaped portion 41 and the second rod-shaped portion 42.

The lid 15b of the packing accommodating portion 15 is formed in an annular shape. The first rod-like portion 41 is passed through the center (hollow portion) of the annular lid body 15b. A gap is provided between the lid 15b with the insertion port 15a closed and the bias receiving portion 43, and the lid 15b slides along the first rod-shaped portion 41 toward the bias receiving portion 43. By doing so, the insertion port 15a can be opened and the packing 14 can be replaced.
The packing 14 is formed in a C-shape, and is annularly arranged along the periphery of the first rod-shaped portion by being inserted into the packing accommodating portion from the insertion port.
As the packing 14, it is possible to impart heat resistance by employing a material reinforced with a heat resistant metal wire. Specifically, it is preferable to use as the packing 14 a braided with a glass seal yarn reinforced with a heat-resistant metal wire, and a special lubricant, graphite and anticorrosion treatment. For example, “Super Seal Packing” (trade name) manufactured by NICHIAS Corporation can be used for the packing 14.

In a portion of the first rod-shaped portion 41 exposed to the outside from the valve box 1, a bias receiving portion that receives the bias of the elastic member 5 on the valve box 1 side (closer to the tip of the first rod-shaped portion 41) than the male screw 43. 45 is provided. The first cylinder portion 7 is also provided with a sub bias receiving portion 46 that receives the bias of the elastic member 5. In this embodiment, the urging receiving portion 45 is a flange-like portion provided on the outer peripheral surface of the first rod-like portion 41, and the auxiliary urging receiving portion 46 is provided on the outer peripheral surface of the first cylinder portion 7. A flange-shaped part.
The elastic member 5 is a compression spring (coil spring) interposed between the urging receiving portion 45 and the sub urging receiving portion 46, and moves the urging receiving portion 45 and the sub urging portion 46 away from each other. Energize. That is, the elastic member 5 biases the first rod-like portion 41 (valve rod 4) from the first cylinder portion 7 side toward the valve box 1 side in order to seat the valve body 3 on the valve seat 2.

The second rod-shaped portion 42 includes a first piston portion 47 fitted to the first cylinder portion 7, a support shaft 48 provided at the rear end (upper end) of the first piston portion 43, and a rear end ( And a handle 49 provided at the upper end).
The first piston part 47 receives the pressurization of compressed gas supplied from a gas supply part 8 described later in the first cylinder part 7 to close the second rod-like part 42 (valve bar 4) in the valve closing direction. Energize (downward).
The support shaft 48 fixes the handle 49 to the rear end of the first piston portion 47.

The valve stem lock means 6 prevents (locks) the valve stem 4 that is biased in the valve closing direction (downward) by the elastic member 5 to prevent (lock) the valve stem 4 from moving in the valve closing direction. Keep the valve open.
Specifically, as shown in FIG. 2, the valve stem locking means 6 contacts the second rod-like portion 42 of the valve stem 4 to lock the valve stem 4 and accommodates the pin 61 to move the pin 61. A second cylinder part 63 to be guided and a secondary elastic member 64 accommodated in the second cylinder part 63 are provided.

  A pin receiving portion 62 is provided on the first piston portion 47 of the second rod-shaped portion 42. The pin receiving portion 62 is a retreating portion that is provided on the outer peripheral surface of the first piston portion 47 and retreats in the radially inward direction of the first piston portion 47. The pin receiving portion 62 is formed in an annular shape along the circumferential direction of the second rod-shaped portion 42 on the outer peripheral surface of the second rod-shaped portion 42. In this embodiment, the pin receiving portion 62 is a groove formed in an annular shape along the outer peripheral surface of the second rod-like portion 42.

The first cylinder portion 7 includes a first through hole 71 that penetrates from the inside of the first cylinder portion to the outside at the rear end (upper end) of the first cylinder portion 7, and a first cylinder portion at a side portion of the first cylinder portion 7. And a third through hole 73 that penetrates from the inside of the first cylinder part 7 to the outside behind the first piston part 47 to be accommodated.
The second rod-like portion 42 places the handle 49 outside the first cylinder portion 7 by inserting the support shaft 48 described above into the first through hole 71.
The second cylinder portion 63 is provided at a position corresponding to the second through hole 72 on the side surface of the first cylinder portion 7 and coordinates the pin 61 (in the axial direction thereof) substantially horizontally. Then, the tip of the pin 61 can be inserted into the pin receiving portion 62 of the first piston portion 47 through the second through hole 72 (in FIGS. 1 to 5, the left side of the pin 61 is the tip side, and the right side Is drawn as the rear end side.)

The sub-elastic member 64 urges the pin 61 toward the second through hole 72 in the second cylinder portion 63. Specifically, the pin 61 includes a flange-shaped second piston portion 65 that fits into the second cylinder portion 63. In this embodiment, the auxiliary biasing member 64 is accommodated between the second piston portion 65 and the rear end portion (right end) of the second cylinder portion 63, and the second piston portion 65 and the second cylinder portion. 63 is a spring that biases the rear end (right end) of 63 in a direction to separate it. The second piston portion 65 and the rear end portion of the second cylinder portion 63 serve as a spring receiver for the sub-elastic member 64, and the pin 61 urged by the sub-elastic member 64 has the second rod-shaped portion 42 (the second rod portion 42). It is pressed against the pin receiving part 62 of the 1 piston part 47).
In this way, the pin 61 is locked to the pin receiving portion 62 to lock the valve rod 4 urged by the elastic member 5 and maintain the valve open state.

The gas supply unit 8 includes a connection part 81 provided on the side of the second cylinder part 63, a through hole 83 provided at another position on the side of the second cylinder part 63, the through hole 83, and the A connecting pipe 84 that communicates with the third through hole 73 of one cylinder portion 7.
The connecting portion 81 is a penetrating portion that is provided on the distal end side of the pin 61 from the second piston portion 65 and penetrates from the inside of the second cylinder portion 63 to the outside, and is connected to a compressed gas supply source such as the compressor P. Although not shown in the figure, the connecting portion 81 includes a nipple (a cylindrical raised portion that is provided around the penetrating portion and fits into the mouth of the end portion of the hose P1) for connecting the gas pressure sending hose P1 of the compressor P. Can be formed as In addition, when a stopper having a screw is attached to the end of the hose P1, a screw for screwing the metal fitting may be formed on the nipple so that the metal fitting can be screwed to the nipple. Note that the hose can be implemented by any material, whether it is made of a flexible material, or a plastic or metal pipe.
Compressed air can be used as the compressed gas, but other inert gases can also be used.
The through hole 83 is a hole that is provided on the distal end side of the pin 61 from the second piston portion 65 and penetrates from the inside of the second cylinder portion 63 to the outside. As described above, the through hole 83 communicates with the third through hole 73 of the first cylinder portion 7 through the connection pipe 84. The inside of the connecting pipe 84 provides a passage 82 for sending the compressed gas introduced from the compressor P into the second cylinder part 63 into the first cylinder part 7.
The gas flow path from the compressor P to the first cylinder portion 7 is formed airtight. That is, the insides of the hose P1, the second cylinder part 63, the connecting pipe 84 (passage 82), and the first cylinder part 7 are formed airtight with respect to the outside.

Next, the operation of this shut-off valve will be described.
Normally, as shown in FIG. 1, the valve body 3 is separated (upward) from the valve seat 2. At this time, as shown in FIGS. 1 and 2, the tip of the pin 61 is attached to the auxiliary elastic member 64. The state which entered into the pin receiving part 62 under the force is maintained. At this time, the on-off valve P2 of the compressor P connected to the connection part 81 is closed, and the compressed gas is not supplied to the second cylinder part 63.

In the event of an emergency, when it becomes necessary to close the shut-off valve, the operator operates the on-off valve P2 of the compressor P to open the on-off valve P2, so that the compressor P enters the second cylinder portion 63. Compressed gas is sent. When the second piston portion 65 receives the gas pressure, as shown in FIG. 4, the pin 61 moves backward and comes out of the pin receiving portion 62, and the valve rod 4 can move downward, that is, in the valve closing direction. It becomes. The valve stem 4 receiving the bias of the elastic member 5 starts to move in the valve opening direction. At this time, the first rod passes through the passage 82 in the connecting pipe 84 from the second cylinder portion 63. Compressed gas is sent into the cylinder portion 7 to pressurize the first piston portion 47 and assist the biasing of the valve rod 4 of the elastic member 5 in the valve closing direction.
Under such energization, the valve stem 4 advances in the valve closing direction. As a result, the valve body 3 is seated on the valve seat 2 as shown in FIG. 3, and the shut-off valve is closed.
The compressor P continues to apply pressure to the first cylinder part 7 via the second cylinder part until the restoration work is started. That is, the operation of the on-off valve P2 for stopping the supply of the pressure of the compressor P is not performed until the restoration operation is started, and the state in which the gas pressure is loaded in the first cylinder portion 7 is maintained.
The on-off valve P2 is operated by an operator operating an operation panel (not shown).

When recovering from the closed state to the open state, the on-off valve P2 is closed by the operation through the operation panel, and the supply of gas pressure from the compressor P to the first cylinder unit 7 is stopped. Although not shown, the hose P1 has a switching portion and a communication portion with the outside of the hose P1. By opening the switching valve, the supply of gas pressure is stopped along with the stop of the supply of gas pressure. Release to the outside (degas). The operation of the switching valve is performed together with opening / closing of the on-off valve P2 by operation on the operation panel. Instead of providing a separate switching valve, the on-off valve P2 can be implemented as a function of the switching valve.
As described above, after releasing the gas pressure load into the first cylinder portion 7, the operator turns the handle 49 to rotate the second rod-shaped portion 42 with respect to the first rod-shaped portion 41, so that the male screw becomes the female screw. The second rod-shaped portion 42 is first returned to the valve opening position while leaving the first rod-shaped portion 41 in the valve closing position. By this operation, when the second rod-like portion 42 is retracted (raised) to the position when the valve is open, the pin 61 in the second cylinder portion 63 that is biased by the auxiliary elastic member 64 is moved to the pin receiving portion. Enter 62 (FIG. 5). When the pin 61 enters the pin receiving portion 62, the second rod-like portion 42 can still rotate around its axis, but is fixed in the vertical direction and restrains the valve from moving forward and backward in the opening / closing direction. .
After fixing the advance and retreat of the second rod-shaped portion 42 restored to the position at the time of opening in the above, the second rod-shaped portion 42 is rotated in the reverse direction by rotating the handle 49 in the reverse direction to the above. Then, the male screw is screwed in the direction to be fastened to the female screw. As a result, the first rod-like portion 41 is pulled toward the second rod-like portion 42 extended upward from the first rod-like portion 41 against the biasing of the elastic member, and the first rod-like portion 41 is opened when the valve is opened. The shut-off valve can be restored to the open state (FIG. 1).

  The handle 49 and the support shaft 48 that supports the handle 49 are fixed to the first piston portion 47, and can be implemented as moving up and down together with the first piston portion 47 as the valve is opened and closed. However, although not shown in the drawings, a hole for accommodating the front end side of the support shaft 48 is provided at the rear end of the first piston 47 and the inside of the hole is vertically moved along the axial direction of the valve stem 4. A spline extending to the support shaft 48 and a protrusion engaging with the spline on the outer peripheral surface of the support shaft 48 to allow the support shaft 48 to move up and down relative to the first piston portion 47 and to receive a rotational force from the handle 49. Is surely transmitted from the support shaft 48 to the first piston portion 47, and is in contact with the first cylinder portion 7 such as a protrusion or a flange on the outer periphery of the support shaft 48, so It can also be implemented by forming a hit to prevent the movement of (b) and stopping the handle 49 in a fixed position in the vertical direction.

In this embodiment, the pin receiving portion 62 is formed on the outer peripheral surface of the first piston portion 47. However, the pin receiving portion 62 may be formed on another portion of the second rod-shaped portion 42. Then, the second cylinder part 63 may be formed separately from the first cylinder part 7. Further, the pin receiving portion 62 is formed by forming a large diameter portion and a small diameter portion on the second rod-shaped portion 42 to form the step, or on the outer periphery of the second rod-shaped portion 42 and on the first cylinder portion 7. It can also be carried out by forming a flange in a portion that is not accommodated to form the flange.
Further, the compressed gas for energizing the valve stem 4 is used for unlocking the valve stem lock means 6, but the compressed gas for energizing the valve stem 4 is used for releasing the valve stem lock means. Instead, other means such as providing a handle for pulling out the pin 62 from the pin receiving portion 62 at the rear end of the pin 61 can be adopted. However, as described above, if the compressed gas for urging the valve rod 4 is used, the valve rod lock means 6 is unlocked and the valve rod 4 is urged in the valve closing direction by opening the compressor. Is convenient and can be done at once.

It is a whole longitudinal cross-sectional view which shows the valve opening state of the marine oil tank emergency cutoff valve which concerns on one embodiment of this invention device. FIG. 2 is an enlarged partial cutaway cross-sectional view of a main part of FIG. 1. FIG. 2 is an overall vertical sectional view showing a closed state of the shut-off valve shown in FIG. 1. FIG. 4 is an enlarged partial cutaway cross-sectional view of a main part of FIG. 3. FIG. 4 is an overall longitudinal sectional view showing the shutoff valve in the middle of returning from the closed state of FIG. 3 to the opened state of FIG. 1. It is a whole longitudinal cross-sectional view which shows the valve opening state of the conventional marine oil tank emergency cutoff valve.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Valve box 2 Valve seat 3 Valve body 4 Valve rod 5 Elastic member 6 Valve rod locking means 7 1st cylinder part

Claims (6)

A valve box that constitutes a flow path of a fluid such as oil and that has a valve seat; a valve body that closes by shutting down the valve seat by being seated on the valve seat; and a valve rod provided with the valve body; In a shutoff valve comprising an elastic member that urges the valve stem in the closing direction, and a valve stem locking means that locks the valve stem and maintains the valve box open state,
A first cylinder part that houses at least a part of the valve stem, and a gas supply part;
The gas supply part supplies compressed gas into the first cylinder part from the other to urge the valve rod in the valve closing direction,
A shut-off valve, wherein the valve stem is moved in the valve closing direction by releasing the lock of the valve stem lock means and using the pressure of the gas together with the biasing of the elastic member. The valve stem locking means includes a pin that contacts the valve stem and locks the valve stem,
The shut-off valve according to claim 1, wherein the valve stem lock means releases the lock of the valve stem by separating the pin from the valve stem using the pressure of the compressed gas. The valve stem includes a first piston portion that moves the valve stem in the valve closing direction under pressure of the compressed gas in the first cylinder portion,
A second cylinder part that accommodates the pin and guides the movement of the pin is provided on the outer peripheral part of the first cylinder part,
The pin includes a second piston portion that moves the pin under pressure of the compressed gas in the second cylinder portion,
The side surface of the valve stem is provided with a pin receiving portion that retreats in the radial inward direction of the valve stem at least in a portion that is arranged in the first cylinder portion when the valve is closed
The valve stem locking means locks the valve stem by inserting the tip of the pin into the pin receiving portion of the valve stem,
The gas supply unit includes a connection unit that connects the second cylinder unit to a compressed gas supply source, and a passage that connects the second cylinder unit and the first cylinder unit.
The gas supply part introduces compressed gas from the connection part into the second cylinder part to pressurize the second piston part to detach the pin from the valve rod, and from the second cylinder part through the passage. 3. The shut-off valve according to claim 2, wherein gas is supplied into the first cylinder portion to pressurize the first piston portion and urge the valve rod in the valve closing direction.   4. The shut-off valve according to claim 3, wherein the valve body is located upstream of the valve seat in the flow path, moves to the downstream side when the valve is closed, and is seated on the valve seat. A ship oil tank emergency shut-off valve,
The interior of the valve box includes a partition wall that separates the upstream side and the downstream side of the fluid passage, and the partition wall is provided with an opening that connects the upstream side and the downstream side.
The above-described valve seat is provided on the surface facing the upstream side of the partition wall, and the opening is closed and the valve is closed by seating the valve body,
The first cylinder part is arranged with a certain interval with respect to the valve box,
The valve box has a penetrating portion that penetrates from the inside of the valve box to the outside of the valve box on the upstream side of the partition wall,
The valve rod has a first rod-like portion whose front end side is inserted into the valve box from the penetrating portion and is exposed to the outside from the valve box, and a rear end of the first rod-like portion formed separately from the first rod-like portion. A second rod-like portion connected to the side,
The valve body of the first rod-like part is provided in the portion inserted into the valve box, and the biasing receiving part that receives the bias of the elastic member is provided on the part exposed to the outside from the valve box of the first rod-like part. Provided,
The pin receiving portion is formed in an annular shape along the circumferential direction of the second rod-shaped portion on the outer peripheral surface of the second rod-shaped portion,
The second rod-shaped portion is provided with a first piston portion, and the rear end of the second rod-shaped portion is provided with a handle.
Either one of the first rod-shaped portion and the second rod-shaped portion is provided with a male screw, and either one is provided with a female screw that is screwed with the male screw. By screwing the male screw into the female screw, The above-mentioned connection of the second rod-shaped part to the part is made,
When closing the valve, the first rod-shaped portion is advanced in the valve closing direction with the second rod-shaped portion by urging the elastic member and pressurizing the compressed gas,
When recovering from the closed state to the open state, the second rod-shaped portion is rotated with respect to the first rod-shaped portion by operating the handle, and the male screw is relatively rotated in the direction of loosening the female screw, thereby closing the valve position. Returning the second rod-shaped portion to the position at the time of valve opening leaving the first rod-shaped portion in
After fixing the advancement / retraction of the second rod-shaped portion that has been restored to the valve opening position by inserting a pin into the pin receiving portion, the second rod-shaped portion is reversely rotated by reverse operation of the handle, so that the male screw is relatively turned into the female screw. 5. The first rod-like portion is returned to the position at the time of opening the valve against the urging force of the elastic member by being screwed in the fastening direction, and is restored to the valve opening state. Shut-off valve. The first cylinder part includes a secondary bias receiving part,
The elastic member is a compression spring interposed between the bias receiving portion and the sub bias receiving portion, and biases the bias receiving portion and the sub bias receiving portion in a direction away from each other.
The valve box penetrating part includes a packing for maintaining liquid-tightness between the valve stem and the valve box, and a packing housing part in which the packing is disposed between the inner peripheral surface of the through part and the outer peripheral surface of the first rod-shaped part. And
The packing accommodating portion includes a packing insertion port that opens from the surface of the valve box to the outside of the valve box, and a lid that closes the insertion port.
The lid is formed in an annular shape, and the first rod-like portion is inserted through the center of the lid,
There is a gap between the lid with the insertion port closed and the biasing receiving portion, and the insertion port is opened by sliding the lid along the first rod-shaped portion toward the biasing receiving portion. Can
The packing is formed in a C-shape, and is inserted annularly along the periphery of the first rod-shaped part by inserting it into the packing accommodating part from the insertion port,
The pin receiving portion is provided on the outer peripheral surface of the first piston portion,
The first cylinder part penetrates from the inside of the first cylinder part to the outside at the rear end of the first cylinder part, and penetrates from the inside of the first cylinder part to the outside at the side part of the first cylinder part. A second through hole and a third through hole penetrating from the inside of the first cylinder part to the outside behind the first piston part to be accommodated;
The second rod-shaped portion includes a support shaft that supports the handle, and the handle is disposed outside the first cylinder portion by inserting the support shaft into the first through hole.
The second cylinder part is provided at a position corresponding to the second through hole on the side surface of the first cylinder part, and the tip of the pin is inserted into the pin receiving part of the first piston part through the second through hole. Yes, a secondary elastic member for urging the pin toward the second through hole is accommodated in the second cylinder portion,
The side part of the second cylinder part is provided with a through hole that is provided on the tip end side of the pin from the second piston part to be accommodated and penetrates from the inside of the second cylinder part to the outside,
The third through hole of the first cylinder part and the through hole are connected and provided with a connecting pipe that constitutes the above-described passage,
Connect a compressor as a compressed gas supply source to the connecting part, operate the compressor to supply compressed gas from the connecting part into the second cylinder part, and slide the second piston part to pin the pin The shut-off valve according to claim 5, wherein the shut-off valve can be supplied from the receiving portion and the compressed gas in the second cylinder portion can be supplied into the first cylinder portion through the connecting pipe.

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