JP2009264538A - Leakage suppressing sealing method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a sealing method capable of closing a leakage part (or a leaking place) of a pipe without adversely affecting a large commercial gas meter by a sealant. <P>SOLUTION: In the sealing method, the sealant 8 for closing the leakage part 6 of the pipe 1 is circulated along with supply gas from an upstream region of the leakage part 6 with respect to a supply gas flow to close the leakage part 6. The sealant 8 is supplied from a supply portion formed in a downstream region of the large commercial gas meter 2 connected to the pipe 1 and capable of supplying the sealant 8 to the pipe 1. <P>COPYRIGHT: (C)2010,JPO&amp;INPIT

Description

  The present invention relates to a sealing method for sealing a leakage portion (such as a screw joint portion) of a pipeline (for example, a gas supply or transportation pipeline such as a gas pipeline), and in particular, an adverse effect of a sealing agent on a commercial large gas meter. The present invention relates to a sealing method for efficiently sealing the leakage portion without exerting any influence.

  Conventionally, when a gas pipe leaks in a building, the location of the gas leak is identified and repaired using a gas detector or the like. For example, when leakage occurs at a threaded joint, the gas supply is stopped, the joint and its peripheral part are cut and removed, and the leaked part is replaced by a replacement gas pipe. Are repairing. However, with such a method, it takes a lot of time and money to find a leaking point and perform repair work (for example, gas pipe replacement work), which is uneconomical. Moreover, since it is necessary to stop supply of gas during repair work, consumers are restricted from using gas. Further, such a method cannot prevent pipes and joints that have not yet been leaked in a preventive manner.

  Japanese Patent Application Laid-Open No. 2002-356670 (Patent Document 1) discloses a sealing agent for suppressing gas leakage from a leakage portion of a pipe, which can be circulated together with a gas flow in the pipe, A sealing agent composed of a sealing compound capable of closing the leakage portion by volume expansion is disclosed. This document exemplifies a moisture reaction curable component, a radical polymerization curable component, a cationic polymerization curable component, and the like as the sealing agent. Examples of the cationic polymerization curable component include vinyl ethers, cationically polymerizable olefins, cycloalkanes, lactones, lactams, cyclic ethers (ethylene oxide, propylene oxide, trimethylene oxide, tetrahydrofuran, tetrahydropyran, etc.) and the like. Are listed. Furthermore, this document also describes a sealing method in which the sealing compound is circulated together with the gas flow in the pipe to suppress gas leakage from the leakage portion. In addition, this document describes that it is effective to seal a leaked area in a wide area using a gas flow.

  Japanese Patent Laid-Open No. 2006-342960 (Patent Document 2) supplies a sealing agent composed of a sealing compound capable of closing a leaking portion of a pipe to a supply gas flow in the pipe to supply the gas. A sealing method that closes the leakage portion by flowing along with the flow, and is located downstream of the leakage portion and upstream of the gas-related equipment connected to the pipe with respect to the gas flow. A sealing method is disclosed in which the leaking portion is closed while capturing the surplus sealing agent that has passed through the piping by the capturing agent disposed at the location where the leakage occurs. In this document, even if excess sealing agent (sealing compound) flows or passes without blocking the leaking portion of the pipe, the sealing agent can be captured (trapped) downstream from the leaking portion. It is described that the leakage part of the pipe can be closed without affecting the gas-related equipment [gas meter, gas consuming equipment (gas stove, gas water heater, etc.)] connected to. In the above-described method, the sealant is, for example, a governor or an appropriate location downstream of the governor for circulating the supply gas under reduced pressure (for example, a governor for depressurizing to an intermediate pressure, an arbitrary location for intermediate pressure piping, and depressurizing to a low pressure. It is described that it may be added to a governor and any pipe (low pressure pipe) passing through the governor).

  Furthermore, Japanese Patent Laid-Open No. 2006-342337 (Patent Document 3) discloses a sealing agent for closing a leaking part of a pipe, which can be circulated together with a supply gas flow in the pipe, and in the leaking part of the pipe. A sealant composed of a sealing compound capable of closing the leaking part by being absorbed and accumulated in the remaining sealant is disclosed. Also in this document, the sealant is distributed under reduced pressure to the supply gas, such as a governor or an appropriate location downstream of the governor (for example, a governor that reduces pressure to an intermediate pressure, an arbitrary location of intermediate pressure piping, and a pressure that is reduced to a low pressure. It is described that it may be added to the governor and any part of the piping (low pressure piping) that has passed through the governor), and is usually sealed with at least a sealing agent (residual sealing agent) from the viewpoint of closing the leaking portion. It is also described that it is preferable to add the sealing agent on the upstream side of the gas flow rather than the location (such as the joint portion).

In the sealing methods of Patent Documents 1 to 3, the sealing agent can be circulated together with the supply gas flow in the pipe, and the repair work can be easily performed without stopping the supply of gas. It is also possible to prevent pipes and joints that are not reached in a preventive manner. However, these documents do not clearly describe the supply site of the sealing agent, and depending on the supply site, the sealing agent may reach a large gas meter for business use and may have an adverse effect. In addition, since a large amount of sealing agent is required, the leaked portion cannot be efficiently sealed, which is uneconomical. Furthermore, depending on the supply site, it may be difficult to supply the sealant and the operability may be poor.
JP 2002-356670 A (Claim 1, Claim 8, paragraphs [0019] [0028]) JP 2006-342960 A (Claim 1, paragraphs [0020] [0095]) JP 2006-342337 A (Claim 1, paragraph [0074])

  Accordingly, an object of the present invention is to provide a sealing method capable of closing a leaking portion (or leaking location) of a pipe without causing a sealing agent to adversely affect a commercial large gas meter.

  Another object of the present invention is to provide a sealing method capable of closing the leakage portion simply and efficiently.

  Still another object of the present invention is to provide a sealing method capable of easily adjusting the supply amount of the sealing agent.

  Another object of the present invention is to provide a sealing method capable of closing the leakage portion while suppressing fluctuations in the supply amount of the supply gas.

  As a result of intensive studies to achieve the above-mentioned problems, the inventors have supplied a sealing agent for closing a leakage portion of a pipe into a pipe from a specific part formed in the pipe. The present invention has been completed by finding that the leaked portion (or leaked portion) of the pipe can be closed without adverse effects.

  That is, the sealing method of the present invention is a sealing method in which a sealing agent for closing a leaking part of piping is circulated together with a supply gas from an upstream region of the leaking part with respect to a supply gas flow, and the leaking part is closed. In this sealing method, the sealing agent is supplied from a supply portion that is formed in a downstream area of a large commercial gas meter connected to a pipe and can supply the sealing agent to the pipe.

  In the method, the supply site may be a pressure detection hole. The sealing agent may be supplied to the pipe as a mixed gas with a combustible medium gas for diffusing the sealing agent.

  Further, in the method, in the flow path connected to the supply site, the sealant and the combustible medium gas for diffusing the sealant are mixed, and the flow rate control means provided in the flow path is used. The amount of the sealing agent supplied to the pipe may be adjusted. The combustible mediator gas may be the same type as the supply gas.

  In the present specification, the “leakage part” of the pipe means an opening formed at an appropriate place of the pipe or a place that is deteriorated and weakened, and the gas does not necessarily have to leak. Specifically, the leakage portion includes, for example, a gap (a seal portion of the pipe (for example, a joint portion)) between the pipe (a threaded joint portion of the pipe) and a sealing agent previously applied to the pipe. Where there is a gap (where the sealant (for example, the sealant that seals the threaded joint of the pipe) has a reduced volume (decrease in volume) (or there is a sealant remaining in the pipe). Part) and parts that are peeled off. ] Etc. are included. Furthermore, in this specification, “class” means that it may have a substituent, for example, “hydroxycycloalkene oxides” means “hydroxycycloalkenyl which may have a substituent”. Alkenoxide "is an agreement.

  The supply gas, the sealing agent, and the combustible medium gas may be simply referred to as “gas”.

  In the sealing method of the present invention, since the sealing agent is supplied into the pipe from a specific portion formed in the downstream area of the commercial large gas meter connected to the pipe, the sealing agent has an adverse effect on the commercial large gas meter. It is possible to close the leaked portion (or leaked portion) of the piping without any trouble. Moreover, since the sealing agent is supplied into the pipe from the specific part, the leaking portion can be closed easily and efficiently. Further, when the sealing agent is supplied to the pipe as a mixed gas with the combustible medium gas for diffusing the sealing agent, the supply amount of the sealing agent can be easily adjusted. When the same kind of gas as the supply gas is used as the combustible medium gas, fluctuations in the supply amount of the supply gas can be suppressed, and the leaking portion (or leakage location) of the pipe can be blocked while maintaining a stable supply amount. it can.

  In the sealing method of the present invention, the sealing agent for closing the leaking portion of the pipe is supplied to the pipe from a specific portion formed in the downstream area of the large business gas meter connected to the pipe. Hereinafter, the present invention will be described in detail with reference to the accompanying drawings as necessary.

  FIG. 1 is a schematic diagram showing an example of the sealing method of the present invention. In addition, the arrow in a figure shows the flow of gas.

  In this example, the supply gas (or city gas) passes through the large commercial gas meter 2 and the pressure detection hole 3 in order from the upstream to the downstream with respect to the supply gas flow, and enters each gas-related device (or property) 5. Supplied. And the leaking part 6 is formed in the joint part 18 located upstream of the gas related equipment (or property) 5 and downstream of the pressure detection hole 3, and gas leakage occurs in this part. ing.

  The sealing agent 8 is supplied to the pipe 1 from the pressure detection hole 3 provided on the downstream side of the large business gas meter 2. In this example, the sealing agent 8 is supplied from a gas cylinder 12 and circulates through a first flow path 9 connected to the pressure detection hole 3 in the form of a mixed gas with a medium gas for diffusing the sealing agent. Then, the pressure is supplied from the pressure detection hole 3 to the pipe 1.

  More specifically, the sealant 8 accommodated in the bubbling device 7 disposed in the upstream area of the first flow path 9 is passed through the second flow path 13 communicating with the bubbling apparatus 7, and the gas cylinder 12. The gas is vaporized (gasified) in the device 7 by the action of the compressed gas (compressed combustible medium gas) supplied from the gas and diffused to become a mixed gas with the medium gas. In this example, the medium gas is the same type of gas as the supply gas (city gas) to be supplied. The second flow path 13 has a pressure adjustment (or control) valve 14 for adjusting the pressure of the compressed gas from the gas cylinder 12 in order from the upstream to the downstream with respect to the intermediate gas flow, and a gas cylinder. A flow meter 11 a for measuring the flow rate of the compressed gas from 12 is formed. The discharge pressure of the compressed gas is greater than the total pressure of the desired supply pressure of the supply gas to the gas-related equipment (or property) 5 and the pressure lost between the gas cylinder 12 and the pressure detection hole 3. Is preferred. Usually, the discharge pressure of compressed gas is often adjusted to be about 100 to 500 Pa (preferably 150 to 450 Pa) larger than the total pressure of the supply pressure and the lost pressure.

  The generated mixed gas flows through the first flow path 9 and is supplied from the pressure detection hole 3 to the pipe 1. The mixed gas diffuses in the pipe 1, is mixed with the supply gas, reaches the leaking part 6, and closes the leaking part 6 (or the leaking part). The pressure detection hole 3 and the first flow path 9 are connected by connecting the first flow path 9 to a female screw provided in the pressure detection hole 3 using a screw joint. Yes. The female screw is normally closed with a plug. The pressure detection hole 3 has a flow meter 4 for measuring the supply amount (or flow rate) of the supply gas, and the first flow path 9 has a supply amount (or sealant) of the mixed gas (or sealing agent). Alternatively, a flow rate control valve 10 for controlling the flow rate) is formed.

  In the example of FIG. 1, since the sealing agent is supplied from the pressure detection hole provided on the downstream side of the large commercial gas meter into the pipe where the gas flow exists, the sealing agent does not adversely affect the large commercial gas meter. The leakage part (or leakage point) of the piping can be closed.

  FIG. 2 is a schematic diagram showing another example of the sealing method of the present invention. In addition, the arrow in a figure shows the flow of gas. In addition, the element or member which fulfill | performs the function similar to the sealing method shown by said FIG. 1 attaches | subjects and demonstrates the code | symbol similar to FIG.

  The sealing method in this example is the same as the sealing method shown in FIG. 1 except that the supply gas flowing through the pipe 1 is used as the combustible medium gas for diffusing the sealing agent 8. .

  In other words, in this example, the supply gas (or city gas) is divided into a third flow path 15 formed by branching from the pressure detection hole 3, and a blower (explosion-proof) for adjusting the pressure of the supply gas is used. Guide to the mold blower 16. The supply gas that has passed through the blower (explosion-proof blower) 16 is guided to the bubbling device 7 via a second flow path 17 that connects the blower (explosion-proof blower) 16 and the bubbling device 7. The discharge pressure of the supply gas discharged from the blower (explosion-proof blower) 16 reaches a desired supply pressure of the supply gas to the gas-related equipment (or property) 5 and the blower 16 to the pressure detection hole 3. It is adjusted (or pressurized) to be about 100 to 500 Pa (preferably 150 to 450 Pa) larger than the total pressure with the pressure lost in between. Due to the action of the supply gas, a mixed gas of the supply gas and the sealing agent is generated by a mechanism similar to the sealing method shown in FIG. 1, and the generated mixed gas passes through the pressure detection hole 3. Supplied to the pipe 1. In the second flow path 17, a flow pressure gauge 11 b for measuring the pressure and flow rate of the supply gas from the blower (explosion-proof blower) 16 is formed.

  In this example, since the supply gas flowing through the pipe 1 is used as the combustible medium gas for diffusing the sealant 8, the leakage portion is blocked while suppressing fluctuations in the supply amount of the supply gas. it can.

  1 and 2, a large business gas meter 2, a pressure detection hole 3, and a gas-related device 5 are connected from upstream to downstream, and a pipe 1 between the pressure detection hole 3 and the gas-related device 5. However, in general, the pipe 1 is branched in the downstream area of the pressure detection hole 3 to form a plurality of branch pipes. The same or different gas related equipment is connected to the end.

  In the sealing method shown in FIG. 1, the discharge pressure of the compressed gas from the gas cylinder 12 is detected from the desired supply pressure of the supply gas to the gas-related equipment (or property) 5 and the gas cylinder 12 as described above. It is not limited to a pressure that is about 100 to 500 Pa higher than the total pressure that is lost while reaching the pressure hole 3, and is even greater unless the supply pressure of the supply gas to the gas-related equipment (or property) 5 is greatly changed. It may be pressure. Specifically, the discharge pressure of the compressed gas from the gas cylinder 12 is the pressure lost between the desired supply pressure of the supply gas to the gas-related equipment (or property) 5 and the gas cylinder 12 to the pressure detection hole 3. 50 to 1000 Pa, preferably 75 to 800 Pa, more preferably about 100 to 600 Pa.

  Further, in the sealing method shown in FIG. 2, the discharge pressure from the blower (explosion-proof blower) 16 is also the desired supply pressure of the supply gas to the gas-related equipment (or property) 5 and the blower 16 as described above. As long as the supply pressure of the supply gas to the gas-related equipment (or property) 5 does not fluctuate significantly, the pressure is not limited to a pressure that is about 100 to 500 Pa higher than the total pressure with the pressure lost between the gas and the pressure hole 3. A large pressure may be used. Specifically, the discharge pressure of the supply gas from the blower 16 is the pressure that is lost between the desired supply pressure of the supply gas to the gas-related equipment (or property) 5 and the pressure detection hole 3 from the blower 16. 50 to 1000 Pa, preferably 75 to 800 Pa, more preferably about 100 to 600 Pa.

  A feature of the sealing method of the present invention is that it is formed in a downstream area of a large commercial gas meter connected to a pipe, and the sealant is supplied from a supply site capable of supplying the sealant to the pipe to block the leaking part of the pipe There is in point to do. By supplying the sealing agent from the supply site in the downstream area of the commercial large gas meter, the sealing agent adversely affects the commercial large gas meter (for example, adhesion of the sealing agent to the inner wall of the commercial large gas meter). Without this, the leaking portion can be efficiently blocked (or sealed).

  The supply site may be a site (for example, a hole, a gap, or the like) that is at the downstream side of the commercial large gas meter and can supply at least the sealant to the pipe. In addition, for example, when the sealing method of the present invention is applied to a leaking part of a piping of a large-scale facility such as a commercial building (department store, etc.), the sealing agent affects the piping diagram of the facility. The supply site may be determined in consideration of the range. The supply site may be a pressure detection hole (a pressure detection hole for pressure detection that collectively manages (detects) the pressure in the pipe line), for example, a valve portion, etc. In general, the supply site is often a pressure detection hole because it can be supplied, has excellent operability, and can easily adjust the supply amount of the sealant.

  The sealing agent supplied from the supply site is a sealing agent for closing (suppressing or sealing) the leaking portion of the pipe, and is not particularly limited as long as the leaking portion can be closed. For example, the sealing agent can be circulated with a gas flow in a pipe and can seal a leaking part by reaction or volume expansion (for example, a moisture reactive monomer, a radical reactive monomer, a cationic reactivity). Monomer, etc.) (for example, the sealing agent described in JP-A-2002-356670), but can be circulated together with the supply gas flow in the pipe, and the pipe Leakage part [specifically, the gap formed between the residual sealant and the pipe (screw joint part of the pipe)] can be blocked by absorbing and accumulating in the residual sealant remaining It may be a sealing agent composed of a simple sealing compound (or sealing agent). As such a sealing agent, the sealing agent described in Unexamined-Japanese-Patent No. 2006-342337 can be used, for example.

  The sealing compound may be circulated together with a supply gas (for example, city gas) circulated in the pipe. That is, the sealing compound typically has a vapor pressure at room temperature and normal pressure, and can normally flow with a supply gas that is in a gaseous state. Moreover, it is preferable that the sealing compound has a property of accumulating without being detached from the residual sealing agent after being absorbed by contact with the residual sealing agent. Such a sealing compound is directly absorbed by the remaining sealing agent, so that it can be sealed efficiently even if it flows with the supply gas at a low concentration, and it may adversely affect the combustion of the gas workpiece or gas. Absent. In addition, the sealant accumulates in the remaining sealant and does not desorb (or hardly desorbs) from the remaining sealant even after being supplied. Therefore, the sealant is effective over a long period regardless of fluctuations in the temperature in the vicinity of the leaking part. The leaking part can be sealed.

  The sealing compound may have a relatively high boiling point, for example, 50 ° C. or higher (for example, 50 to 300 ° C.), preferably 80 ° C. or higher (for example, 80 to 250 ° C.), more preferably 100 degreeC or more (for example, 100-220 degreeC), especially about 120-200 degreeC may be sufficient.

  Further, the vapor pressure of the sealing compound is relatively low from the viewpoint of accumulation, for example, at 20 ° C., 10000 Pa or less (for example, 10 to 9000 Pa), preferably 8000 Pa or less (for example, 20 to 7000 Pa). More preferably, it may be 5000 Pa or less (for example, 30 to 5000 Pa), particularly 40 to 3000 Pa (for example, 50 to 2000 Pa), and usually about 60 to 1500 Pa (for example, 80 to 1000 Pa). In particular, the vapor pressure of the sealing compound (such as the olefin oxides) is, for example, about 500 to 5000 Pa, preferably 600 to 4000 Pa, more preferably 700 to 3000 Pa (for example, 750 to 2500 Pa) at 20 ° C. May be.

  The sealing compound usually has some affinity for the remaining sealant remaining in the leaked portion, and has an affinity group (functional group, characteristic group, affinity for the remaining sealant. In many cases, it has a functional group. In view of the affinity for the remaining sealant, olefin oxides (compounds having an α, β-epoxy group or 1,2-epoxy group, oxiranes) are usually preferred as the sealing compound constituting the sealant. Used for.

Typical olefin oxides include, for example, chain olefin oxides {for example, alkene oxide (such as C _6-20 alkene oxide such as 2,3- _epoxyhexane ), alkene oxide having a substituent [for example, hydroxyalkene Oxides (or α, β-epoxyalkanols) and other alkene oxides having affinity groups or functional groups]}; cyclic olefin oxides (cyclic olefin oxides optionally having substituents) {for example, simple Cyclic olefin oxides [cycloalkene oxides (or α, β-epoxycycloalkanes), cycloalkadiene oxides (or α, β-epoxycycloalkenes), etc.], polycyclic olefin oxides (for example, Dicycloalkene oxides, tricycloalkene oxides Etc.)}. Of these olefin oxides, hydroxyalkene oxides and cycloalkene oxides are preferably used.

Examples of hydroxyalkene oxides (or α, β-epoxyalkanols) include hydroxy C _3-10 alkene oxides such as 2,3-epoxypropanol (glycidol) and 2,3- _epoxybutanol , preferably hydroxy C _3-6 cycloalkene oxides (especially 2,3-epoxypropanol (glycidol) etc.) etc. are mentioned.

Examples of the cycloalkene oxides (or α, β-epoxycycloalkanes) include C _5-10 such as cycloalkene oxide [eg, 1,2-epoxycyclopentane, 1,2-epoxycyclohexane (cyclohexene oxide), etc. Cycloalkene oxide], cycloalkene oxide having a substituent [for example, alkyl cycloalkene oxides (for example, C _1-4 alkyl-C _5-10 cycloalkene oxides such as 1,2-epoxy-4-methylcyclohexane) , Cycloalkene oxides having a hydrocarbon group, such as alkenyl cycloalkene oxides (eg, C _2-4 alkenyl-C _5-10 cycloalkene oxides such as 1,2-epoxy-4-vinylcyclohexane); Alkenoxy Class (e.g., _{C 1-6} alkoxy _{-C 5-10} cycloalkene oxides, such as 1,2-epoxy-4-methoxy cycloheptane), hydroxy cycloalkene oxides (e.g., 2,3-epoxy cyclobutanol, 2 Hydroxy C _5-10 cycloalkene oxides such as 1,3-epoxycyclopentanol), carboxycycloalkene oxides (eg, carboxy C _5-10 cycloalkene oxides such as 1,2-epoxy-4-carboxycyclohexane) , Cycloalkene oxides having a functional group or an affinity group such as aminocycloalkene oxides (for example, amino C _5-10 cycloalkene oxides such as 1,2-epoxy-3-aminocycloheptane) and the like. Can be mentioned. Among these cycloalkene oxides, C _5-10 cycloalkene oxide (particularly 1,2-epoxycyclohexane (cyclohexene oxide) and the like) and the like are preferably used. The olefin oxides may be used alone or in combination of two or more.

  In the sealing agent, the sealing compounds may be used alone or in combination of two or more. The sealing agent used in the present invention may be composed of at least the sealing compound, may be composed of the sealing compound alone, and the sealing compound and the remaining seal of the sealing compound You may comprise with the absorption promoter for promoting the absorption with respect to an agent. When the absorption accelerator is used, the absorption accelerator is absorbed into the remaining sealing agent (further expanded or swollen), and the sealing compound is absorbed more selectively with respect to the remaining sealing agent. The leakage portion may be more efficiently sealed by promoting or improving the absorbability (selective absorbability) of the sealing compound with respect to the remaining sealant. That is, by allowing the absorption promoter to flow along with the sealing compound, it is possible to improve the absorbability and accumulation of the sealing compound with respect to the remaining sealing agent.

As the absorption accelerator, for example, an absorption accelerator described in JP-A-2006-342337 can be used. Typical absorption promoters include conventional solvents such as hydrocarbons (aliphatic hydrocarbons, alicyclic hydrocarbons, aromatic hydrocarbons), alcohols [alkanols (for example, methanol, ethanol, etc.). C _1-10 alkanols such as 1-propanol, 2-propanol, 1-butanol, 2-butanol, isobutanol, isoamyl alcohol, octanol, decanol, etc., preferably C _1-6 alkanols); Cycloalkanols (eg, cycloaliphatic alcohols such as C _5-8 cycloalkanols such as cyclopentanol and cyclohexanol)], ethers [chain ethers such as dialkyl ethers; Cyclic ethers, etc.], ketones [dia Aliphatic ketones such as Kirketon like; cycloalkanone, etc.], esters (ethyl acetate, etc.) and the like. Absorption promoters may be used alone or in combination of two or more. The boiling point of the absorption accelerator is, for example, 30 ° C. or higher (eg, 35 to 250 ° C.), preferably 40 ° C. or higher (eg, 45 to 200 ° C.), more preferably 50 ° C. or higher (eg, 55 to 150 ° C.). In particular, it may be about 55 ° C. or higher (eg, 60 to 120 ° C.).

Preferable absorption accelerators are alcohols [eg, alkanols such as C _1-4 alkanol (methanol, ethanol, butanol, etc.)], depending on the type of residual sealant.

  The use ratio of the sealing compound and the absorption accelerator is the former / the latter (weight ratio) = 90/10 to 1/99, preferably 70/30 to 2/98, more preferably 50/50 to 3/97. In particular, it may be about 30/70 to 5/95. Further, the sealing agent may further contain other components (for example, a reaction or polymerization initiator) as necessary. In addition, when using the said sealing compound and an absorption accelerator, you may mix and use a sealing compound and an absorption promoter, for example, prior to supply of a sealing compound, an absorption promoter is beforehand used. You may use separately or isolate | separated by the aspect of supplying. In a preferred embodiment, the absorption enhancer overlaps with the supply of the sealing compound by utilizing the property that the absorption enhancer gradually desorbs from the remaining sealing agent when the supply is stopped. (Coexistence) may be supplied.

  The supply amount of the sealing agent (or sealing compound) (or the concentration of the sealing agent in the piping) is the entire supply gas flow [or the total amount of all fluids flowing through the piping such as supply gas and sealing agent]. On the other hand, on the volume basis, for example, it can be selected from the range of about 0.1 to 20000 ppm, for example, 0.1 to 5000 ppm, preferably 0.5 to 3000 ppm, more preferably 1 to 2500 ppm, especially 5 to 2000 ppm (for example, However, the supply amount of the sealing agent (or sealing compound) (or the concentration of the sealing agent in the pipe) is from the point that the leaking portion can be sealed within a short time. , 500 ppm or more (for example, 1000 to 20000 ppm), preferably 1200 to 15000 ppm, more preferably 1 on a volume basis with respect to the entire feed gas stream. 00～12000Ppm (e.g., 1500~11000ppm), may in particular about 2000～10000Ppm. Note that at a concentration of 4000 ppm or more, particularly 5000 ppm or more, the leakage portion can be sealed within a short time. The reason why the concentration of the sealing compound (or sealing agent) is greatly involved in the sealing of the leaking part is not clear, but once the residual sealing agent in the leaking part absorbs the sealing compound, the absorption rate of the sealing compound This seems to be due to the sudden increase in size.

  Moreover, the pressure of the supply gas (or mixed gas containing a combustible medium gas described later) containing the sealant (or sealing compound) is 1 kPa or more (for example, 1.2 to 35 kPa), preferably 1. It may be about 5 to 30 kPa (for example, 1.5 to 25 kPa), more preferably about 2 to 20 kPa. The reason why the pressure of the gas flow affects the sealing performance of the leaking part is not clear, but it seems that the absorption rate of the sealing compound increases rapidly once the residual sealing agent absorbs the sealing compound.

  The form of supplying the sealing agent from the supply site is not particularly limited, and the sealing agent may be supplied alone, but the sealing agent can be uniformly diffused and distributed with high mobility. In view of this, the sealing agent may be supplied as a mixture with another medium (for example, a gaseous medium, a medium gas, etc.).

Although it does not restrict | limit especially as said other medium (especially intermediary gas), Since it distribute | circulates with a sealing agent and supply gas, it is combustible gas (combustion which can be burned (especially complete combustion) with a sealing agent and / or supply gas) Sex mediating gas). That is, the mediating gas may be a compound mainly composed of air; carbon atoms and hydrogen atoms (oxygen atoms and / or nitrogen atoms as necessary). Typically, the representative medium gas is usually a hydrocarbon (especially C _1-5 alkane such as methane, ethane, propane, butane, etc.). These mediator gases may be used alone or in combination of two or more. The medium gas and the supply gas may be different from each other, but the medium gas and the supply gas may be the same type in order to suppress (or prevent) the fluctuation of the supply amount of the supply gas and the decrease in energy efficiency. preferable. The supply gas is usually a combustible gas such as city gas (for example, methane).

  The form (or means) of mixing the medium gas and the sealing agent and supplying the mixture (or mixed gas) into the pipe is not particularly limited as long as the mixture (or mixed gas) can be supplied into the pipe. For example, a form (or mixed gas) prepared in advance (or in an independent system) may be supplied from a supply site, and the mixture (or means) using an apparatus (or means) disposed at the supply site may be used. The gas may be generated and supplied into the pipe. As the device (or means), for example, as illustrated above, a device (or a flow path) including a combination of the bubbling device 7 and the gas cylinder 12 and a combination of the bubbling device 7 and the blower 16 are provided. A device (or a flow path).

  Moreover, as another form which supplies the mixture (or mixed gas) produced | generated using the said apparatus (or means) in piping, for example, the form diffused in piping using the vapor pressure of a sealing agent Etc. Specifically, for example, the sealing agent (and the medium gas) is filled in a container (particularly a container that can be opened and closed such as a valve-equipped container) connected to the supply site, and diffused using vapor pressure, A form of the medium gas [for example, air, supply gas (especially air), etc.] may be generated and supplied to the pipe.

  In addition, when supplying the mixture (or mixed gas) into the pipe, the mixture (or mixed gas) is heated and / or agitated by heating and / or stirring the sealing agent (and the medium gas) in order to efficiently close the leakage portion. (Gas) generation may be promoted.

  The mixed gas is supplied from the supply site to the pipe, mixed with the supply gas, and further diffused, reaches each property (or a leaked portion thereof), and closes the leaked portion (or leaked portion).

  The supply amount (or flow rate) of the mixed gas to the pipe does not need to be controlled, but is preferably controlled from the viewpoint of energy efficiency, economy, and the like. The means (flow rate control means) for controlling the supply amount (or flow rate) of the mixed gas is not limited to the exemplified flow rate control valve, and other means such as a flow rate control pump may be used.

  By using the flow rate control means, the supply amount (or flow rate) of the mixed gas (or sealing agent) supplied to the pipe can be easily adjusted. In particular, when a mixed gas (especially a sealing agent) in the saturated state (or saturated vapor pressure) is used, the concentration of the sealing agent in the mixed gas is constant (or almost constant), and thus the supply amount can be further simplified. (Or flow rate) can be adjusted. For example, the supply amount (or flow rate) of the mixed gas (or sealing agent) may be adjusted according to the flow rate of the supply gas, or may be adjusted according to the number of leaking portions (or leakage locations) of the piping. Also good. Specifically, for example, in the sealing method shown in FIGS. 1 to 3, the supply amount (or flow rate) of the supply gas is measured using the flow meter 4, and the flow control valve 10 according to the supply amount. Further, the supply amount of the mixed gas (or sealant) may be adjusted using the flow meter 11a (or the flow pressure gauge 11b). Further, the supply amount (or flow rate) of the supply gas measured by the commercial gas meter 2 is signal-processed, and the flow control valve 10 and the flow meter 11a (or the flow pressure gauge 11b) are used according to the supply amount. The supply amount of the mixed gas (or sealing agent) may be adjusted. Furthermore, the supply amount of the mixed gas (or sealant) may be adjusted by using the flow control valve 10 and the flow meter 11a (or the flow pressure gauge 11b) according to the number of leaking parts (or leaking points). . More practically, for example, when the sealing agent is supplied in a time zone in which the amount of gas used is small (or a time zone in which the supply amount of the supply gas is small), the amount of the sealing agent required Can be reduced. Moreover, even when there are many leaking parts (or leaking points) or when an emergency is required, the supply amount of the sealing agent can be easily increased, and an immediate response can be made.

  The supply of the sealing agent (or mixed gas) is performed constantly (or continuously) over a predetermined period (for example, 6 hours to 50 days, particularly about 10 hours to 2 weeks) to the piping. It may also be performed intermittently or intermittently.

  The reasons why it is preferable to supply the sealing agent intermittently or intermittently will be exemplified below. For example, the sealing agent (or sealing compound) is absorbed and accumulated in the residual sealing agent and acts as a repair agent for the leaking part (or for the residual sealing agent in the leaking part). In some cases, the residual sealant circulates with the gas without being absorbed. In addition, as described above, the sealing compound is not only a residual sealant, but also a rubber material that is usually used in a pipe or its surroundings (a rubber material that constitutes an O-ring used in a pipe (for example, acrylonitrile). -Butadiene rubber (NBR) etc.) etc.) and the rubber material may expand or swell. Therefore, it is effective to supply the sealing agent at a low concentration in order to suppress the absorption of the sealing agent with respect to the rubber material or the like (or the expansion of the rubber material), but a sufficient sealing compound is used for the remaining sealing agent. It may take a long time to accumulate and close the leak.

  Therefore, the sealant may be supplied intermittently (or divided into a plurality of times) instead of once. That is, although the sealing compound is absorbed by the rubber material but does not accumulate, when the supply of the sealing agent is stopped, it gradually desorbs and restores its original state. On the other hand, the sealant (sealing compound) absorbed by the remaining sealant accumulates in the remaining sealant without being desorbed (or released) even when the supply of the sealant is stopped. For this reason, in the present invention, the sealing agent is intermittently supplied by repeatedly supplying and stopping the sealing agent with respect to the supply gas flow, and the sealing compound absorbed by the rubber material or the like is desorbed while remaining in the sealing agent. The leakage portion may be reliably sealed by accumulating the sealing compound. In addition, the sealing agent (sealing compound) is usually more easily absorbed by the remaining sealing agent than by rubber materials and the like, and therefore, more selectively by supplying the sealing agent intermittently. The remaining sealing agent can be absorbed, and the leakage portion can be efficiently blocked while reducing the amount of the sealing agent absorbed by the rubber material or the like.

  In addition, when supplying the said sealing agent intermittently, the frequency | count of supplying or adding a sealing compound or an absorption promoter to a gas flow (or frequency | count of stopping supply or addition) is 2 times or more (for example, 2-2). 100 times), preferably 2 to 50 times (for example, 2 to 30 times), more preferably about 3 to 15 times (for example, 4 to 10 times). For the sealing compound and the absorption promoter, the ratio between the supply time and the stop time (the period for supplying the sealant at the nth time and the period for stopping the supply of the sealant at the nth time) is, for example, The former / the latter = 90/10 to 10/90, preferably 80/20 to 20/80, more preferably about 70/30 to 30/70 (for example, 60/40 to 40/60).

  In addition, as needed, you may distribute | circulate the said sealing compound, heating or heating piping. The pipe can be heated or heated by a conventional method, and may be heated from outside the pipe by a heating means (heater, heating medium, etc.), or heated gas (heating medium such as heated air, heated steam, etc.) The pipe may be heated or heated by being introduced into the pipe.

  In the sealing method of the present invention, the sealing agent is used for pressure detection for managing (detecting) the pressure of a specific part (for example, the pressure in the pipe line in a lump) formed in the downstream area of the large business gas meter connected to the pipe. Since the sealing agent is supplied into the pipe from the pressure detection hole), the leaking portion (or the leaked portion) of the pipe can be closed without adversely affecting the large-sized commercial gas meter. Furthermore, when the specific part (for example, a pressure detection hole) is used, the flow path from the sealant supply part to the leaking part is short, and even if the supply amount of the sealant is small, it is effectively provided in the pipe. The concentration of the sealing agent can be increased, and even when there are many leaking parts (or leaking parts) or when an emergency is required, it is possible to respond immediately.

  Moreover, since the sealing method of this invention distribute | circulates a sealing agent with supply gas and obstruct | occludes the said leakage part, even if it is a gas leak which is hard to find, such as a trace amount gas leak, it can suppress efficiently. Furthermore, the method is effective for sealing a leaking part (such as a gas leaking part) without stopping the supply gas, and can save labor for repairing the leaking part.

  The method of the present invention can be applied to various pipes (or pipes) for circulating gas, particularly gas pipes such as city gas, and the pipes are not limited to one flow path but are branch pipes having a plurality of flow paths. There may be. The kind of piping is not specifically limited, It can apply effectively to various piping or pipe lines (for example, a pipe body with an average internal diameter of about 15-100 mm). In particular, pipes that are likely to have a gap with the sealant, such as a joint part of a branch pipe branched from the main pipe (for example, a threaded joint part that easily causes minute gas leakage) as shown in FIG. The present invention can be effectively applied to a pipe body or a pipe line, and gas leakage can be effectively suppressed or prevented. Note that the sealing method of the present invention is effective even if the leaking portion is a leaking portion formed in a pipe inside the property (or building) or a leaking portion formed in the piping outside the property (or building). It is.

  The sealing method of the present invention can suppress or prevent gas leakage without adversely affecting a commercial large gas meter. Therefore, the sealing method of the present invention is useful for various gas pipes, for example, city gas or fuel gas pipes (particularly pipes for large-scale properties that are desired to be easily maintained).

  Further, in the present invention, since it is possible to close the leakage portion of the piping while suppressing the fluctuation of the supply amount of the supply gas, the property (for example, glass work, industrial furnace, etc.) that requires a stable supply of gas is required. It can also be applied to pipes (tubes or pipes) in the upstream area of a property that makes heavy use of direct fire.

  Hereinafter, the present invention will be described in more detail based on examples, but the present invention is not limited to these examples.

Example 1
As shown in FIG. 3, a simulated pipe (pipe unit) in which a joint portion 18 was formed on each of four branch pipes (pipes branched from the main pipe) having gas-related devices 5 connected to the ends thereof was produced. In addition, the connection between the pressure detection hole 3 and the first flow path 9 is performed by attaching the first flow path 9 to the female screw provided in the pressure detection hole 3 using a screw joint. went. The joint portion 18 was formed with a leak portion 6 (a leak portion that caused a gas leak of about 3 to 7 mL / min from the screw joint portion when the supply gas was circulated at a flow rate of 6 m ³ / hr). Using bubbling device 7, cyclohexene oxide (1,2-epoxycyclohexane) as a sealing agent (or sealing compound) is circulated at a flow rate of 2.5 kPa and a flow rate of 1 to 6 m ³ / hr together with a supply gas. It was. The concentration of the sealing agent (cyclohexene oxide) was 2500 ppm on a volume basis with respect to the entire feed gas stream. When the amount of gas leaking from the joint 18 was observed, no gas leak was detected in 10 days. When the gas leak stopped, the inside of the large commercial gas meter was observed, and no contamination with the sealing agent was observed.

(Comparative Example 1)
In the sealing method shown in FIG. 3, a governor (not shown) connected to the upstream region of the commercial gas meter 2 without supplying the sealing agent from the pressure detection hole 3 using the blower 16 and the bubbling device 7. The leakage part 6 was sealed in the same manner as in Example 1 except that the sealing agent was supplied from When the amount of gas leaking from the joint portion 18 was observed, no gas leak was detected in 10 days, but when the gas leak from the leaking portion 6 stopped, the inside of the commercial large gas meter was observed, Sealing agent had adhered inside.

FIG. 1 is a schematic diagram showing an example of the sealing method of the present invention. FIG. 2 is a schematic diagram showing another example of the sealing method of the present invention. FIG. 3 is a schematic diagram showing still another example of the sealing method of the present invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Piping 2 ... Large gas meter for business use 3 ... Pressure detection hole 4 ... Flow meter 5 ... Gas related equipment 6 ... Leakage part 7 ... Bubbling device 8 ... Sealing agent 9 ... 1st flow path 10 ... Flow control valve 11a ... Flow rate Total 11b: Flow pressure gauge 12 ... Gas cylinder 13, 17 ... Second flow path 14 ... Pressure control valve 15 ... Third flow path 16 ... Blower 18 ... Joint part

Claims (5)

  A sealing method for closing a leaking portion of a pipe with a supply gas from an upstream area of the leaking portion with respect to a supply gas flow, and closing the leaking portion, and connected to the pipe The sealing method which supplies the said sealing agent from the supply site | part which is formed in the downstream area of a large-sized gas meter and can supply the said sealing agent to piping.   The sealing method according to claim 1, wherein the supply site is a pressure detection hole.   The sealing method according to claim 1 or 2, wherein the sealing agent is supplied as a mixed gas with a combustible medium gas for diffusing the sealing agent.   In the flow path connected to the supply site, the sealant and the combustible medium gas for diffusing the sealant are mixed and supplied to the pipe using the flow rate control means provided in the flow path. The sealing method according to claim 1, wherein the amount of the sealing agent is adjusted.   The sealing method according to claim 3 or 4, wherein the combustible medium gas is the same kind as the supply gas.

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