JP2016070469A - Piping joint cover, piping joint cover mounting method, and splash prevention device of piping joint part - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a piping joint cover capable of preventing the situation in which the cover is destroyed when high-pressure fluid is leaking or blowing out from piping.SOLUTION: In a piping joint cover 100 covering a joint part constituted of a plurality of connected pipe arrangements 10, the pipe arrangements 10 include: a pipe part 11 through which fluid circulates; a flange part 12 formed at the end edge of the pipe part; and the joint part formed by joining butt the flange part 12 of the pipe arrangements 10. The piping joint cover 100 comprises: a cylindrical cover body 30 capable of storing the joint part; mounting means 40 provided at one end of the cover body 30 for fixing the joint part; and an opening 50 formed at the other end of the cover body 30 capable of discharging to outside the fluid leaked from the joint part.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a pipe joint cover that covers a joint portion to which a plurality of pipes are connected, and a method for mounting the pipe joint cover. The present invention also relates to a fluid scattering prevention device for a pipe joint provided with a pipe joint cover and a local exhaust device.

  General piping has a pipe part through which fluid (gas, liquid, fine powder, etc.) flows, and a flange part formed at the tip of the pipe part. For this reason, when two pipes are connected, it is general that the flange portions are brought into contact with each other and then tightened using bolts and nuts. As a result, the pipe portions of the two pipes are connected to each other, and the fluid flows continuously.

  By the way, in factories that handle chemicals, for example, acidic or alkaline fluids may flow through the pipes described above, and the flanges that form the joints between the pipes may deteriorate and corrode over time. . When the deterioration of the flange portion proceeds, a situation in which the fluid flowing in the pipe leaks or jets out from the joint portion between the pipes. In particular, when the fluid is circulating in the pipe at high pressure, when this high-pressure fluid leaks or spouts from the joint, the flange may be broken with a large impact. In addition, when the fluid is circulating in the piping under high pressure and high temperature, the danger of this fluid leaking or ejecting from the joint is extremely high. For example, if the fluid ejected from the joint of a pipe adheres to a worker nearby, damage such as normal burns caused by heat or chemical burns caused by chemicals may occur. In order to prevent such fluid ejection accidents, the bolts on the flanges are thoroughly tightened and the flanges are inspected and maintained regularly. To prevent such accidents completely, difficult.

  For this reason, conventionally, a pipe joint cover has been attached to this joint in order to prevent the fluid from being scattered even if the fluid leaks or spouts from the pipe joint. (For example, patent document 1). The piping joint cover of Patent Document 1 relates to a cover that covers a joint portion of a hot water supply pipe or a drain pipe of a hotel, for example. In the cover of Patent Document 1, a small hole is formed in the cover body that covers the periphery of the joint portion of the pipe, and after the filler is poured into the cover body from the small hole and completely condensed, the small hole is closed. Therefore, it is configured so that the periphery of the joint part of the pipe can be sealed.

Japanese Patent Laid-Open No. 51-129928

  As in the case of the conventional pipe joint cover described above, by sealing the periphery of the pipe joint, it is possible to temporarily prevent the fluid from scattering from the joint. However, when a high-pressure fluid (for example, 1.0 MPa or more) is circulating in the pipe, if the pipe joint cover is sealed around the joint, the joint is destroyed and fluid is ejected at the same time. The cover itself may be destroyed. As a result, there was a risk that a large accident was caused with a large impact, and the fluid in the pipe was scattered all around. In particular, when the fluid in the pipe is a chemical and is in a high pressure state and a high temperature state, the damage when the pipe joint cover is damaged or destroyed becomes extremely serious. Also, if a small hole is provided in the cover body itself as in the pipe joint cover of Patent Document 1, when the high pressure fluid is ejected from the joint and the pipe joint cover receives an impact, the small hole breaks down. Or it may be the starting point of destruction.

  As described above, the conventional pipe joint cover can prevent the fluid from scattering from the joint part to some extent by sealing the periphery of the joint part of the pipe, but when a high-pressure fluid flows in the pipe In addition, there is a problem that the cover itself may be damaged or destroyed.

  In addition, the joints of pipes are tightened with bolts and nuts, but the bolts may loosen over time. For this reason, it is necessary to retighten the bolts periodically to prevent fluid leakage and ejection from the pipe joint. Such work is also called retightening. However, since the conventional pipe joint cover seals the entire pipe joint, when retightening the bolt, remove the pipe joint cover from the pipe joint, and then tighten the bolt or nut. It was necessary to expose. In addition, after the bolts had been tightened, the pipe joint cover had to be reinstalled so as to cover the pipe joint. Such a work for attaching and detaching the pipe joint cover is very troublesome and increases the burden of the additional tightening work of the bolts. In addition, if the burden of tightening the bolts is increased, the frequency of inspection work to check the looseness of the bolts decreases, so there is a possibility that fluid leaks or spouts from the joint as described above. There was also concern that it would increase.

  As described above, the conventional pipe joint cover needs to be removed and reattached every time the bolts connecting the flange portions of the pipe are tightened, which increases the burden of the additional tightening work. was there.

  Therefore, the present invention prevents at least the pipe joint cover from being damaged or destroyed even when fluid leaks or jets from the pipe joint, and controls the fluid scattering state to prevent fluid leakage.・ The primary purpose is to minimize damage during ejection. A second object of the present invention is to enable easy retightening of a joint portion of a pipe. The present invention provides means for achieving at least one of the above objects.

  The inventors of the present invention have intensively studied the means for solving the problems of the conventional invention. As a result, the tubular cover body covers the periphery of the joint portion between the pipes, and one end of the cover body is connected to the joint portion of the pipe. The structure of fixing to is invented. In other words, in the present invention, one end portion of the cylindrical cover body is fixed to a joint portion where the flange portions of the pipe are connected to each other, not the pipe portion of the pipe. As a result, an opening is formed in the other end of the cylindrical cover body so that the fluid leaking from the pipe portion of the pipe can be discharged. For this reason, even if the fluid leaks / spouts from the joint between the pipes, the leaked / spouted fluid is discharged from the opening of the cover body to the outside. Even if high-pressure fluid leaks or jets from the pipe joint, the internal pressure in the pipe joint cover can be released to the outside, so that at least the pipe joint cover can be prevented from being damaged or destroyed. In addition, it is possible to minimize damage during fluid leakage and ejection by keeping the pipe joint cover around the pipe joint without being destroyed. Further, by fixing one end portion of the cylindrical cover body to the joint portion of the pipe, connection means such as bolts and nuts connecting the flange portions can be exposed on this end side. Therefore, the bolts can be tightened without removing the cover body from the pipe joint. This reduces the burden of retightening work. Then, the present inventors have conceived that the problems of the conventional invention can be solved based on the above knowledge, and have completed the present invention. If it demonstrates concretely, this invention has the following structures or processes.

The first aspect of the present invention relates to a pipe joint cover 100.
The pipe joint cover 100 of the present invention can cover the joint part 20 connecting a plurality of pipes 10.
The pipe 10 has a pipe part 11 through which a fluid flows and a flange part 12 formed at the tip of the pipe part 11. In addition, the joint portion 20 is formed by fastening the flange portions 12 together via a connecting means 15 including a bolt 13 and a nut 14 in a state where the flange portion 12 of the pipe 10 is abutted.
Here, the pipe joint cover 100 includes a cover body 30 and attachment means 40.
The cover body 30 is a cylindrical member that can accommodate the joint portion 20. The attachment means 40 is means for fixing one end of the cover main body 30 to the joint portion 20. The attachment means 40 may be constituted by a single member or may be constituted by a plurality of members.
An opening 50 is formed at the other end of the cover body 30 so that the fluid leaking from the joint portion 20 can be discharged to the outside.

  As described above, the pipe joint cover of the present invention covers the periphery of the joint portion 20 between the pipes 10 with the cover body 30, and the opening 50 is formed in the cover body 30. As a result, even when a high-pressure fluid leaks or spouts from the joint portion 20 of the pipe 10, the internal pressure in the pipe joint cover can be released to the outside, so that at least the pipe joint cover is lost or destroyed. Can be prevented. As a result, it is possible to prevent the high-pressure fluid from being scattered all around the joint portion 20 of the pipe 10. Further, by forming the opening 50 in the cover body 30, the discharge direction of the leaked or ejected high-pressure fluid can be controlled in a safe direction with the least damage. That is, since it is considered that there is a low possibility that workers in the factory are present in the direction in which the pipe portion 11 of the pipe 10 extends, the high-pressure fluid is discharged along the extending direction of the pipe portion 11. By doing so, the danger to workers can be minimized. Furthermore, if the discharge direction of the high-pressure fluid is known in advance, the operator can be alerted and measures for fluid leakage and ejection can be easily taken. Therefore, according to the pipe joint cover of the present invention, it is possible to minimize damage when fluid is leaked and ejected from the joint portion 20 between the pipes 10.

  In the pipe joint cover of the present invention, the attachment means 40 preferably fixes the cover body 30 to the joint portion 20 so that the connecting means 15 is exposed on one end side of the cover body 30. Here, the state in which the connecting means 15 is exposed means that even after the cover body 30 is attached to the joint portion 20 of the pipe 10, the bolts 13 and nuts 14 are tightened using a tool such as a torque wrench. It means a state that can be performed.

  Since the cover body 30 is fixed to the joint portion 20 so that the connecting means 15 is exposed as in the above configuration, the bolts 13 and the nuts 14 are tightened without removing the cover body 30 from the joint portion 20. Will be able to do. Therefore, it is not necessary to remove the cover main body 30 from the joint portion 20 one by one, so that the burden of retightening work can be reduced.

In the pipe joint cover according to the present invention, it is preferable that the attachment means 40 includes a side contact portion 41, a relay portion 42, standing portions 43 and 44, and a cover attachment portion 45.
The side contact portion 41 has a fitting hole 41a into which the connecting means 15 is fitted. The side surface abutting portion 41 is a portion that abuts on the side surface 12a of the flange portion 12 in a state where the connecting means 15 is fitted in the fitting hole 41a. The relay portion 42 is connected to the side surface contact portion 41 and is a portion that extends along the peripheral surface 12 b of the flange portion 12. The standing portions 43 and 44 are connected to the relay portion 42 and are portions that stand up with respect to the peripheral surface 12 b of the flange portion 12. The cover attachment portion 45 is a portion that is connected to the standing portions 43 and 44 and extends in a direction in which the pipe portion 11 of the pipe 10 extends. One end of the cover body 30 is fixed to the cover mounting portion 45.

  By configuring the attachment means 40 as described above, the opening 50 can be formed at the other end of the cover body 30 while exposing the connecting means 15 on one end side of the cover body 30. In particular, according to the above-described configuration, the cover main body 30 can be fixed to the pipe portion 11 of the pipe 10 only at one end by the attachment means 40, so that the opening 50 formed at the other end of the cover main body 30. Can be opened widely. This can more reliably prevent the pipe joint cover from being damaged or broken. Further, since the connecting means 15 (one of the bolt or nut) is fitted and restrained in the fitting hole 41a of the side surface abutting portion 41, it does not rotate during retightening. Thereby, since the idling of the connecting means 15 (bolts and nuts) is prevented, the retightening operation can be performed more reliably.

The 2nd side surface of this invention is related with the fluid scattering prevention apparatus of a pipe joint part.
The fluid scattering prevention device of the present invention is a device for preventing fluid from scattering from the joint portion 20 connecting a plurality of pipes 10.
The fluid scattering prevention device of the present invention includes a pipe joint cover 100 that covers the joint portion 20 and a local exhaust device 200 that can suck and discharge the fluid to the outside.
The pipe joint cover 100 includes a cover body 30 that can accommodate the joint portion 20 therein. The pipe joint cover 100 includes a cylindrical cover body 30 that can accommodate the joint portion 20, and attachment means 40 for fixing one end of the cover body 30 to the joint portion 20. In addition, an opening 50 is formed at the other end of the cover body 30 so that the fluid leaking from the joint 20 can be discharged to the outside.
Further, the local exhaust device 200 is arranged at a position where the fluid discharged from the opening 50 of the pipe joint cover 100 can be sucked.

  As described above, by forming the opening 50 in the cover body 30 of the pipe joint cover 100, the discharge direction of the leaked or ejected high-pressure fluid can be controlled in a safe direction with the least damage. In addition, since the direction in which the high-pressure fluid is discharged can be easily grasped by controlling the discharge direction of the high-pressure fluid, it is easy to take a measure of disposing the local exhaust device 200 at the end of the opening 50. Therefore, even when a high-pressure fluid leaks or jets from the joint portion 20 of the pipe 10, almost the entire amount of the fluid discharged from the opening 50 can be sucked by the local exhaust device 200 and discharged to the outside. . As a result, the risk of a leakage accident can be further reduced.

A third aspect of the present invention relates to a method for attaching a pipe joint cover.
The attachment method of the present invention is a method of attaching the pipe joint cover 100 so as to cover the joint part 20 connecting the plurality of pipes 10.
In the mounting method of the present invention, one end of the cover body 30 is connected to the joint portion 20 via the mounting means 40 so that the connecting means 15 is exposed on one end side of the cylindrical cover body 30. A fixing step.

  By attaching the pipe joint cover 100 to the joint part 20 of the pipe 10 as described above, it is possible to minimize damage caused when fluid leaks from or is ejected from the joint part 20. Further, by attaching the cover body 30 to the joint portion 20 of the pipe 10 as described above, the bolt 13 and the nut 14 can be tightened without removing the cover body 30 from the joint portion 20. become.

  According to the present invention, even when fluid leaks or jets from the pipe joint, at least the pipe joint cover is prevented from being damaged or broken, and the fluid scattering state is controlled to prevent fluid leakage.・ Damage during ejection can be minimized. Further, according to the present invention, it is possible to easily retighten the joint portion of the pipe.

FIG. 1 is a perspective view showing an example of a structure of a joint portion of a pipe. FIG. 2 is a perspective view showing an example of a pipe joint cover according to the present invention. FIG. 3 is a structural schematic diagram showing an example of a pipe joint cover. FIG. 4 is a perspective view showing an example of a fluid scattering prevention device according to the present invention.

  Hereinafter, embodiments for carrying out the present invention will be described with reference to the drawings. The present invention is not limited to the embodiments described below, but includes those appropriately modified by those skilled in the art from the following embodiments.

[1. Piping joint cover]
With reference to FIGS. 1-3, embodiment of the pipe joint cover of this invention is described.
FIG. 1 shows the state of the pipe before the pipe joint cover is attached. Moreover, FIG. 2 has shown the state which attached the pipe joint cover to the joint part of several piping. FIG. 3 is a schematic diagram showing a specific structure of the fitting means for the pipe joint cover.

  As shown in FIGS. 1 and 2, the pipe joint cover 100 is used as a cover for covering and protecting the joint portion 20 connecting the two pipes 10. The pipe joint cover 100 of the present invention can be attached to a general pipe 10 through which a fluid flows. The shape of the pipe 10 is not particularly limited. The pipe 10 may be linear, or may be bent in a curve. As shown in FIG. 1, each of the pipes 10 has a tubular pipe part 11 through which a fluid flows, and a flange part 12 formed at the tip of the pipe part 11. The flange portion 12 is a portion formed with a larger diameter than the tube portion 11.

  The two pipes 10 are connected by the connecting means 15 in a state where the end faces of the respective flange portions 12 are abutted. More specifically, the connecting means 15 includes a bolt 13 and a nut 14. In addition, the connecting means 15 may include a known member such as a washer. Each flange portion 12 is formed with a plurality of screw holes 16. For this reason, in a state where the positions of the screw holes 16 of the flange portions 12 are aligned, the bolts 13 are inserted into the screw holes 16 of the flange portions 12, and the nuts 14 are screwed into the end portions of the bolts 13. Thereby, the flange portions 12 are connected to each other by the screw action (tightening action) by the bolt 13 and the nut 14. In addition, as a connection means 15, a well-known thing can be used. For example, in the example shown in FIG. 1, the bolt 13 is composed of a hexagonal head and a screw thread extending from the head, and a nut 14 is screwed onto the tip of the screw thread. Can be done. Moreover, in the other example shown in FIG. 1, the bolt 13 is formed in the rod shape which consists of a screw thread. For this reason, the nut 14 can be screwed to both ends of the rod-shaped bolt 13. As described above, the connecting means 15 may be any one that can connect the flange portions 12 to each other by the screw action (tightening action) between the bolt 13 and the nut 14.

  When the pipes 10 are connected to each other via the connecting means 15, the fluid flows continuously in the pipe parts 11. In FIG. 1, the flow direction of the fluid is indicated by a solid arrow F. As shown in FIG. 1, a portion where the two flange portions 12 are connected in a palmed state is a joint portion 20 between the pipes 10.

  The fluid flowing through the pipe 10 is not particularly limited. The fluid may be a gas, a liquid, a fine powder, or the like. However, when the fluid flowing through the pipe 10 is in a high pressure state, the possibility of fluid leaking or jetting from the joint portion 20 formed by connecting the two flange portions 12 increases. Specifically, when the tightening state of the bolt 13 and the nut 14 is loosened, the fluid is easily leaked and ejected from the gap between the flange portions 12. For example, in FIG. 1, the direction in which the fluid may be ejected from the joint portion 20 between the pipes 10 is indicated by a dashed arrow S. In the direction of the arrow S shown in FIG. 1, there is a possibility that an operator or the like may be present, so that the danger when the fluid is scattered is very high. In particular, the danger is further increased when the fluid is in a high-pressure and high-temperature state. For this reason, it is necessary to prevent at least the fluid from scattering in the direction of the arrow S. Therefore, the pipe joint cover 100 of the present invention is used to prevent the fluid from scattering in such a direction.

  As shown in FIGS. 2 and 3, the pipe joint cover 100 includes a cover body 30 and attachment means 40. The cover body 30 is a cylindrical member that can accommodate the joint portion 20 between the pipes 10 inside. The attachment means 40 has a structure that allows one end of the cylindrical cover main body 30 to be fixed and attached to the joint portion 20 of the pipe 10. That is, the attachment means 40 has a structure in which one end of the cylindrical cover body 30 can be fixed to the joint portion 20 of the pipe 10 instead of the pipe portion 11 of the pipe 10.

  As shown in FIGS. 2 and 3, the cylindrical cover body 30 is fixed to the joint portion 20 of the pipe 10 at one end, so that an opening 50 is formed at the other end. That is, the inner diameter of the cover body 30 is larger than the outer diameter of the pipe portion 11 of the pipe 10 and the outer diameter of the flange portion 12. For this reason, an opening 50 is formed between the cover main body 30 and the pipe 10. When a fluid leaks or ejects from the joint portion 20 between the pipes 10, the fluid is discharged to the outside through the opening 50 of the cover body 30.

  In FIG. 2, an example of a path through which the fluid ejected from the joint portion 20 of the pipe 10 is discharged to the outside in a state where the pipe joint cover 100 is attached to the pipe 10 is indicated by a dashed arrow S. . As shown in FIG. 2, the fluid ejected from the joint portion 20 is discharged to the outside through the opening 50. The fluid discharge path (scattering direction) at this time is the same direction as the extending direction of the pipe portion 11 of the pipe 10. The extending direction of the pipe 10 is a direction in which workers and the like are unlikely to exist. For this reason, even if the fluid is discharged from the opening 50, it is difficult for the worker or the like to be damaged. Therefore, by attaching the pipe joint cover 100 having the opening 50 to the pipe 10, a situation in which the fluid is directly ejected in the direction in which the worker exists, as indicated by the arrow S shown in FIG. It can be effectively prevented.

  In addition, as shown in FIG. 2, in the state where the pipe joint cover 100 is attached to the pipe 10, the connecting means 15 (the bolt 13 and / or the nut 14) that connects the flange portions 12 of the pipe 10 are exposed. ing. For this reason, the worker can easily access the connecting means 15 without removing the pipe joint cover 100. Thereby, the worker can easily retighten the bolt 13 and the nut 14 using a tool such as a torque wrench even when the pipe joint cover 100 is attached to the pipe 10. In addition, since the frequency of performing the tightening operation of the bolts 13 and the like can be increased, it is possible to more reliably prevent fluid leakage and ejection accidents caused by loosening of the bolts 13 and the like.

  Next, a specific configuration of the pipe joint cover 100 will be described with reference to FIGS. 2 and 3. FIG. 3 shows a cross-sectional shape of the pipe joint cover 100. However, in FIG. 3, the appearance of the pipe 10 is conceptually shown instead of a cross section.

  As shown in FIGS. 2 and 3, the pipe joint cover 100 includes a cylindrical cover body 30. In the example shown in FIG. 2, the cover main body 30 is formed in a substantially cylindrical shape. The shape of the cover main body 30 is not limited to a cylindrical shape, and can be formed in a rectangular cylindrical shape, a pentagonal cylindrical shape, or other polygonal cylindrical shapes. However, the cover body 30 is particularly preferably cylindrical from the viewpoint that the internal pressure can be evenly distributed. Inside the cylindrical cover body 30, the pipe part 11 and the flange part 12 of the pipe 10 are accommodated. For this reason, at least the inner diameter of the cover body 30 is set larger than the outer diameters of the pipe portion 11 and the flange portion 12 of the pipe 10.

  Further, the pipe joint cover 100 of the present invention is preferably used for the purpose of preventing scattering of fluid at a high pressure (for example, 1.0 MPa or more) and a high temperature (for example, 100 ° C. or more). For this reason, it is preferable that the cover main body 30 is comprised with the member which has the pressure resistance (impact resistance) and heat resistance which can endure the pressure of at least 1.0 Mpa, and the temperature of 100 degreeC. For example, the cover main body 30 can be made of synthetic resin (plastic), metal, or glass. In the example shown in FIG. 2, the cover body 30 is made of a transparent (or translucent) high-stiffness synthetic resin material. For example, the cover body 30 can be formed of a material selected from polycarbonate resin, polyester resin, polyamide resin, polypropylene resin, polyacetal resin, fluorine resin, and the like. In particular, from the viewpoint of high transparency and excellent pressure resistance and heat resistance, the cover body 30 is preferably formed of a polycarbonate resin. Since the cover main body 30 is transparent (or translucent) to the extent that the inside of the cover main body 30 is visible, it is easy to visually confirm the state of the fluid leaking from the pipe 10. Further, the cover main body 30 can be made of metal such as steel, copper, stainless steel, aluminum, or other alloy.

  In addition, although illustration is abbreviate | omitted, the cylindrical cover main body 30 may consider the easiness of attachment to the piping 10, and may form the slit (cut | notch) from one end to the other end. Further, the cover body 30 may be divided into two half cylinders, and one cover body 30 may be formed by connecting two half cylinders. Further, when a slit is formed in the cover body 30 or the cover body 30 is composed of two halved cylinders, a lug or flange is formed on the cover body 30 and the lug or flange is screwed. Good. As described above, the cover main body 30 may be in the form of a cylinder when attached to the joint portion 20 of the pipe 10. Thereby, it becomes easy to attach the cover main body 30 with respect to the joint part 20 of the piping 10 already.

  As shown in FIG. 3, the cylindrical cover main body 30 is fixed to the joint portion 20 between the pipes 10 via the attachment means 40. As shown in FIG. 3, the attachment means 40 includes a side contact portion 41, a relay portion 42, standing portions 43 and 44, and a cover attachment portion 45. In the present embodiment, the “side contact portion” corresponds to the presser ring 41. The “relay portion” corresponds to a plurality of joint plates 42. Further, the “standing portion” corresponds to the base ring 43 and the joint ring 44. Further, the “cover mounting portion” corresponds to the punching plate 45. Further, the attachment means 40 may include a bolt 46, a nut 47, a fixing plate 48, and a presser bolt 49. Below, the structure of the attachment means 40 is demonstrated taking a specific member as an example.

  As shown in FIG. 3, the presser ring 41 is a member that comes into contact with the side surface 12 a of one flange portion 12 of the two connected flange portions 12. The presser ring 41 is in contact with the side surface 12a of the flange portion 12, and is formed in a substantially ring shape (ring shape). The pipe portion 11 of the pipe 10 is inserted into the center hole of the presser ring 41. Further, the holding ring 41 is formed with a plurality of fitting holes 41a into which the connecting means 15 are fitted at positions corresponding to the connecting means 15 (bolts 13 or nuts 14) attached to the side surface 12a of the flange portion 12. ing. For example, when the hexagonal nut 14 is attached to the side surface 12a of the flange portion 12, the fitting hole 41a formed in the presser ring 41 also has a hexagonal shape. The hexagonal nut 14 is preferably non-rotatable when fitted into the fitting hole 12 a of the presser ring 41. In this way, the nut 14 is restrained by the fitting hole 41a of the presser ring 41 so that the nut 14 cannot be rotated, so that when the bolt 13 on the opposite side is rotated, the nut 14 rotates as the bolt 13 rotates. Can be prevented. Thereby, since the idling of the connecting means 15 (bolts and nuts) is prevented, the retightening operation can be performed more reliably. The fitting hole 41a of the presser ring 41 may have a shape corresponding to the connecting means 15 such as the bolt 13 and the nut 14. For example, if the nut 14 is a pentagon, the fitting hole 41a may be a pentagon. The presser ring 41 can be formed of a metal material or a plastic material.

  As shown in FIG. 3, a plurality of joint plates 42 are connected to the presser ring 41. The joint plate 42 is a plate member for relaying the presser ring 41 described above and a base ring 43 described later. It is preferable that the joint plate 42 is integrally joined to the presser ring 41 and the base ring 43 by welding or the like. The plurality of joint plates 42 extend along the peripheral surface 12 b of the flange portion 12. The joint plate 42 may be in contact with the peripheral surface 12b of the flange portion 12 or may not be in direct contact. In FIG. 3, some of the plurality of joint plates 42 are indicated by dotted lines. In the present embodiment, the plurality of joint plates 42 are arranged at intervals in the circumferential direction of the peripheral surface 12 b of the flange portion 12. Thus, it is preferable that the joint plate 42 does not completely cover the gap between the flange portions 12. Since the plurality of joint plates 42 are intermittently arranged at intervals in the circumferential direction, the fluid ejected from the gaps between the flange portions 12 passes between the joint plates 42. Thereby, the fluid ejected from the gap between the flange portions 12 flows into the inside of the cylindrical cover body 30. Similar to the presser ring 41, the joint plate 42 can be formed of a metal material or a plastic material.

  As shown in FIG. 3, a base ring 43 is connected to the plurality of joint plates 42. The base ring 43 is a member for securing a space (space) for attaching the cover main body 30. The base ring 43 is a member formed in a substantially ring shape (ring shape), and the flange portion 12 of the pipe 10 is inserted through the center hole thereof. For this reason, the base ring 43 stands up with respect to the peripheral surface 12 b of the flange portion 12. The inner peripheral portion of the central hole of the base ring 43 is preferably in contact with the peripheral surface 12 b of the flange portion 12. Since the inner peripheral portion of the base ring 43 is in contact with the peripheral surface 12 b of the flange portion 12, the opening on the one end side of the cover body 30 can be closed. As a result, only the opening 50 on the other end side of the cover main body 30 is opened. Accordingly, even when fluid is ejected from the gap between the flange portions 12, it is difficult for the fluid to be discharged from one end side of the cover body 30, and the opening 50 on the other end side of the cover body 30 is opened. Fluid is easily discharged through. From such a viewpoint, it is preferable that the inner peripheral portion of the base ring 43 is in contact with the entire peripheral surface 12b of the flange portion 12. The base ring 43 may be formed of a metal material or a plastic material.

  Also, as shown in FIGS. 2 and 3, a plurality of fixing plates 48 are connected to the base ring 43. As shown in FIG. 3, the fixing plate 48 extends from the base ring 43 in the direction opposite to the joint plate 42. For example, the fixing plate 48 is integrally joined to the base ring 43 by welding or the like. Each fixing plate 48 is formed with a screw hole, and a presser bolt 49 is inserted into the screw hole. As shown in FIG. 3, the presser bolt 49 is inserted into the screw hole of the fixing plate 48 so as to be perpendicular to the peripheral surface 12 b of the flange portion 12. The presser bolt 49 is in contact with the peripheral surface 12 b of the flange portion 12 while being held by the fixing plate 48. Thereby, the base ring 43 can be stably fixed to the peripheral surface 12 b of the flange portion 12 by the pressing force of the presser bolt 49. Two or more pairs of fixing plates 48 and presser bolts 49 may be provided, but for example, four pairs are preferably provided at an interval of 90 degrees with respect to the circumference of the flange portion 12. The fixing plate 48 and the presser bolt 49 are members for assisting in fixing the attachment means 40 to the joint portion 20, and are not essential members. For this reason, the fixing plate 48 and the presser bolt 49 can be omitted.

  As described above, in this embodiment, the presser ring 41, the plurality of joint plates 42, the base ring 43, and the plurality of fixing plates 48 are welded to form a single integral member. Here, as shown in FIG. 3, the pressing ring 41 is fixed to the side surface 12 a of one of the two flange portions 12 connected to each other. The plurality of joint plates 42 are formed so as to extend from one flange portion 12 to the other flange portion 12 across the joint between the flange portions 12. For this reason, the base ring 43 is located on the peripheral surface 12b of the other flange portion 12 to which the presser ring 41 is not fixed, of the two flange portions 12 connected to each other. By adjusting the length of the joint plate 42 in this way, even when a fluid is ejected from the joint between the flange portions 12, the fluid passes between the plurality of joint plates 42 and covers the cover body 30. Then, the air is appropriately discharged from the opening 50 of the cover main body 30.

  As shown in FIG. 3, the base ring 43 is in contact with the peripheral surface 12 b of the flange portion 12, and exceeds the peripheral surface 12 b of the flange portion 12, so that the connecting means 15 (the bolt 13 and / or the nut 14. It is preferable that it does not protrude to the side. If the base ring 43 protrudes toward the connecting means 15, it will be difficult to retighten the connecting means 15 using a tool such as a torque wrench. On the other hand, as shown in FIG. 3, by adjusting the length of the joint plate 42 so that the base ring 43 does not protrude toward the connecting means 15, the worker can easily access the connecting means 15, Retightening work becomes easy.

  As shown in FIG. 3, the base ring 43 is connected to the joint ring 44 in an overlapping manner. Similar to the base ring 43, the joint ring 44 is a member for securing a space (space) for mounting the cover body 30. The joint ring 44 is a member formed in a substantially ring shape (ring shape), and the flange portion 12 of the pipe 10 is inserted into the center hole thereof. For this reason, the joint ring 44 is erected with respect to the peripheral surface 12 b of the flange portion 12, similarly to the base ring 43. The joint ring 44 may be overlapped with the inner side of the base ring 43 (the side where the presser ring 41 exists), or may be overlapped with the outer side of the base ring 43 (the side where the presser ring 41 does not exist). May be. For the connection of the joint ring 44 and the base ring 43, for example, a bolt 46 and a nut 47 may be used. Specifically, insertion holes for the bolts 46 may be formed in the joint ring 44 and the base ring 43 at a plurality of positions corresponding to each other. Accordingly, the joint ring 44 and the base ring 43 can be connected using the bolt 46 and the nut 47. Thus, in this embodiment, the joint ring 44 and the base ring 43 are configured as separate members that can be separated.

  As shown in FIG. 3, a tubular punching plate 45 is connected to the joint ring 44. For example, it is preferable that the joint ring 44 and the punching plate 45 are integrally joined by welding. The punching plate 45 is a member for attaching the cover main body 30. For this reason, the punching plate 45 is formed in a cylindrical shape, like the cover main body 30. As shown in FIG. 3, the punching plate 45 extends in a direction in which the pipe portion 11 of the pipe 10 extends. More specifically, the punching plate 45 extends in the same direction as the direction in which the pipe portion 11 of the pipe 10 to which the holding ring 41 is attached extends. For this reason, the punching plate 45 is also prevented from projecting to the pipe 10 side to which the presser ring 41 is not attached. The punching plate 45 may be formed of a metal material or a plastic material.

  As shown in the perspective view of FIG. 2, the punching plate 45 is punched to form a large number of regularly arranged small holes. Thus, by employing the punching plate 45 that has been subjected to punching as a member (cover attachment portion) for attaching the cover main body 30, the cover main body 30 can be easily attached and at the same time the state inside the cover main body 30 can be easily seen. Become. That is, as shown in FIG. 3, when the cover main body 30 is attached to the punching plate 45, the bolt 46 is inserted into the small hole of the punching plate 45 and the insertion hole formed in the cover main body 30. A nut 47 may be screwed onto the bolt 46. Thereby, the punching plate 45 and the cover main body 30 can be easily connected using the bolt 46 and the nut 47. In addition, since the punching plate 45 has a large number of small holes, it is easy to adjust the attachment position of the cover body 30 appropriately. Furthermore, when the cover main body 30 is formed of a transparent member, the state inside the cover main body 30 can be easily seen through the small holes of the punching plate 45.

  Further, as shown in FIG. 3, when the cover body 30 is attached to the punching plate 45, it is preferable that the cover body 30 is attached so as to be positioned on an extension line of a joint (gap) between the flange portions 12. That is, the fluid in the pipe 10 is likely to be ejected from the joint between the flange portions 12. For this reason, by installing the cover main body 30 on the extension line of the joint of the flange portion 12, the fluid ejected from the seam appropriately flows into the cover main body 30.

  As described above, in the present embodiment, the attachment means 40 includes the presser ring 41, the plurality of joint plates 42, the base ring 43, the joint ring 44, and the punching plate 45. As shown in FIG. 3, the attachment means 40 is fixed to one flange portion 12 of the two flange portions 12 connected to each other, once extended toward the other flange portion 12 side, and again. The shape is such as to return toward the one flange portion 12 side. For this reason, as shown in FIGS. 2 and 3, connecting means 15 (bolts for connecting the flange portions 12 to each other by attaching the cover body 30 to the joint portion 20 of the pipe 10 via the attaching means 40. 13 and / or nut 14) become exposed.

  Although not shown, the various members 41 to 45 constituting the attachment means 40 may be formed with slits (cuts) from one end to the other in consideration of ease of attachment to the pipe 10. Good. The various members 41 to 45 are divided into two or more members, and may be configured by connecting a plurality of members. Further, for example, when connecting a plurality of members, a lug or flange may be formed and the lug or flange may be screwed.

  The configuration of the attachment means 40 has been described above by taking the preferred embodiment as an example. However, the attachment means 40 is limited to the above configuration as long as the cover body 30 can be fixed to the joint portion 20 of the pipe 10 so that the connecting means 15 is exposed at one end side of the cover body 30. Not. As shown in FIGS. 2 and 3, it is preferable that the cover main body 30 and the attachment means 40 do not protrude from the flange portion 12 of the pipe 10. However, if the bolts 13 and nuts 14 can be tightened using a tool such as a torque wrench while the cover body 30 is attached to the pipe 10, the cover body 30 and the attachment means 40 are connected to the flange of the pipe 10. It may protrude somewhat from the portion 12.

[2. Fluid scattering prevention device]
FIG. 4 shows an outline of a fluid scattering prevention device for a pipe joint. As shown in FIG. 4, the fluid scattering prevention device includes a pipe joint cover 100 and a local exhaust device 200. Here, the pipe joint cover 100 has the same structure as that described with reference to FIGS. Further, the local exhaust device 200 is arranged at a position where the fluid discharged from the opening 50 of the pipe joint cover 100 can be sucked. For example, at least one local exhaust device 200 is provided near the opening 50 of the pipe joint cover 100. Further, a plurality of local exhaust devices 200 can be provided near the opening 50 of the pipe joint cover 100.

  The local exhaust device 200 is, for example, a ventilation device capable of sucking gas or fine powder from the hood 210 and exhausting it to the outside through the duct 220 or the like. As shown in FIG. 4, the local exhaust device 200 is preferably disposed in the vicinity of the opening 50 of the pipe joint cover 100 and can suck the fluid discharged from the opening 50. In this way, the fluid discharged from the pipe joint cover 100 is sucked by the local exhaust device 200 and discharged to the outside of the factory, for example, and the environment inside the factory is polluted by the fluid leaked or ejected from the pipe 10. Can be prevented in advance.

  The local exhaust device 200 is not limited to the canopy type as shown in FIG. 4, and for example, a known type such as a slot type, a louver type, or a grit type can be adopted.

  In addition, the fluid scattering prevention device may include a sensor (not shown) for detecting the discharge of fluid from the opening 50 of the pipe joint cover 100. In this case, it is preferable that the local exhaust device 200 is operated when fluid discharge is detected by this sensor, or the intake capability of the local exhaust device 200 that is already operating is set to high power. As a result, in the event of an emergency in which fluid leaks or spouts from the pipe 10, it is possible to quickly respond so that the fluid does not scatter.

  In the fluid scattering prevention device of the present invention, the discharge direction and the discharge position of the fluid leaking and ejecting from the pipe 10 are controlled by the structure of the pipe joint cover 100. For this reason, it is easy to specify the position where the local exhaust device 200 and its sensor (not shown) are provided in order to suck the leaked / spouted fluid. That is, since the opening 50 is formed in the pipe joint cover 100, the pipe joint cover 100 is not easily damaged or broken, and it is possible to easily grasp that the fluid is discharged from the opening 50. Therefore, by providing the suction portion (hood 210) of the local exhaust device 200 and its activation sensor at the tip of the opening 50 of the pipe joint cover 100, the fluid discharged from the opening 50 can be quickly and efficiently supplied. It can be sucked and discharged to the outside.

  As mentioned above, in this specification, in order to express the content of this invention, embodiment of this invention was described, referring drawings. However, the present invention is not limited to the above-described embodiments, but includes modifications and improvements obvious to those skilled in the art based on the matters described in the present specification.

  The present invention relates to a pipe joint cover, a method for mounting the pipe joint cover, and a fluid scattering prevention device including the pipe joint cover. The present invention can be suitably used, for example, in a factory where a high-pressure chemical or the like needs to be conveyed through a pipe.

DESCRIPTION OF SYMBOLS 10 ... Piping 11 ... Pipe part 12 ... Flange part 13 ... Bolt 14 ... Nut 15 ... Connection means 16 ... Screw hole 20 ... Joint part 30 ... Cover main body 40 ... Mounting means 41 ... Presser ring (side contact part) 41a ... Fit Joint hole 42 ... Joint plate (relay part) 43 ... Base ring (standing part)
44: Joint ring (standing part) 45 ... Punching plate (cover mounting part)
46 ... Bolt 47 ... Nuts 48 ... Fixing plate 49 ... Presser bolt 50 ... Opening 100 ... Piping joint cover 200 ... Local exhaust device 210 ... Hood 220 ... Duct

Claims (5)

A pipe joint cover (100) covering a joint part (20) connecting a plurality of pipes (10),
The pipe (10) has a pipe part (11) through which a fluid flows, and a flange part (12) formed at the tip of the pipe part (11).
The joint portion (20) is connected to the flange portion (12) via connecting means (15) including a bolt (13) and a nut (14) in a state where the flange portion (12) of the pipe (10) is abutted. ) Formed by joining together,
The pipe joint cover (100)
A cylindrical cover body (30) capable of accommodating the joint (20);
Mounting means (40) for fixing one end of the cover body (30) to the joint (20),
An opening (50) capable of discharging the fluid leaking from the joint (20) to the outside is formed at the other end of the cover body (30). The attachment means (40) fixes the cover body (30) to the joint part (20) so that the connecting means (15) is exposed on the one end side of the cover body (30). The piping joint cover according to claim 1. The attachment means (40)
There is a fitting hole (41a) into which the connecting means (15) is fitted, and the side face (12a) of the flange portion (12) in a state where the connecting means (15) is fitted into the fitting hole (41a). A side abutting portion (41) that abuts against
A relay portion (42) connected to the side surface contact portion (41) and extending along the peripheral surface (12b) of the flange portion (12);
Standing parts (43, 44) connected to the relay part (42) and standing up with respect to the peripheral surface (12b) of the flange part (12);
It is connected to the upright portions (43, 44), extends in the direction in which the pipe portion (11) of the pipe (10) extends, and the one end portion of the cover body (30) is fixed. The pipe joint cover according to claim 2, including a cover mounting portion (45). A device for preventing fluid from scattering from a joint (20) connecting a plurality of pipes (10),
The pipe (10) has a pipe part (11) through which a fluid flows, and a flange part (12) formed at the tip of the pipe part (11).
The joint portion (20) is connected to the flange portion (12) via connecting means (15) including a bolt (13) and a nut (14) in a state where the flange portion (12) of the pipe (10) is abutted. ) Formed by joining together,
The device is
A pipe joint cover (100) covering the joint part (20);
A local exhaust device (200) capable of sucking fluid and discharging it to the outside,
The pipe joint cover (100)
A cylindrical cover body (30) capable of accommodating the joint (20);
Mounting means (40) for fixing one end of the cover body (30) to the joint (20),
The other end of the cover body (30) is formed with an opening (50) through which fluid leaked from the joint (20) can be discharged to the outside.
The local exhaust device (200)
A fluid scattering prevention device for a pipe joint, which is disposed at a position where the fluid discharged from the opening (50) of the pipe joint cover (100) can be sucked. A method of attaching a pipe joint cover (100) so as to cover a joint part (20) connecting a plurality of pipes (10),
The pipe (10) has a pipe part (11) through which a fluid flows, and a flange part (12) formed at the tip of the pipe part (11).
The joint portion (20) is connected to the flange portion (12) via connecting means (15) including a bolt (13) and a nut (14) in a state where the flange portion (12) of the pipe (10) is abutted. ) Formed by joining together,
Said method is:
One end of the cover body (30) is connected to the end of the cover body (30) via the attachment means (40) so that the connection means (15) is exposed on one end side of the cylindrical cover body (30). A method of attaching a pipe joint cover including a step of fixing to the joint part (20).

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