STRUCTURE MANAGEMENT SYSTEM

Abstract

A structure is made of a metal such as a steel material and is buried in the ground. A first wiring is connected to the structure. A second wiring is connected to an electrode. A switch turns on and off a conduction state between the first wiring and the second wiring. In a state where the switch is turned on, the electrode is in a higher potential state as compared to the structure. The electrode can be made of a metal having an ionization tendency lower than that of the metal included in the structure.

Claims

1.-4. (canceled)

5. A structure management system comprising: a first wiring connected to a structure that is buried underground, wherein the structure comprises a first metal; a second wiring connected to an electrode that is buried underground within a predetermined distance of the structure, wherein the electrode comprises a second metal, and wherein the predetermined distance between the structure and the electrode is a distance within a range in which electrons generated during ionization of the first metal of the structure are capable of reaching the electrode; and a switch connected to the first wiring and the second wiring, wherein the switch is configured to turn on and off a conduction state between the first wiring and the second wiring, and wherein, in a state in which the switch is turned on, the electrode is in a higher potential state as compared to the structure.

6. The structure management system according to claim 5, wherein the second metal of the electrode has an ionization tendency that is lower than an ionization tendency of the first metal of the structure.

7. The structure management system according to claim 5, wherein the structure and the electrode are buried underground in soil.

8. The structure management system according to claim 7, further comprising a DC power supply comprising a negative electrode connected to the electrode in the state where the switch is turned on and a positive electrode connected to the structure in the state where the switch is turned on, wherein in the state where the switch is turned on, a current is configured to flow from the structure toward the electrode via the soil.

9. The structure management system according to claim 5, further comprising a voltmeter, an ammeter, or a coulomb meter connected to the first wiring or the second wiring.

10. The structure management system according to claim 5, wherein the electrode comprises a plurality electrodes, wherein the plurality of electrodes is buried underground surrounding the structure.

11. A method of operating a structure management system comprising: connecting a first end of a first wiring to a structure, the structure comprising a first metal; burying the structure underground, wherein a second end of the first wiring extends above a ground surface; connecting a first end of a second wiring to an electrode, the electrode comprising a second metal; burying the electrode underground within a predetermined distance of the structure, wherein the predetermined distance between the structure and the electrode is a distance within a range in which electrons generated during ionization of the first metal of the structure are capable of reaching the electrode, and wherein a second end of the second wiring extends above the ground surface; and connecting a switch to the second end of the first wiring and to the second end of the second wiring, wherein the switch turns on and off a conduction state between the first wiring and the second wiring, and wherein, in a state in which the switch is turned on, the electrode is in a higher potential state as compared to the structure.

12. The method according to claim 11, wherein the second metal of the electrode has an ionization tendency that is lower than an ionization tendency of the first metal of the structure.

13. The method according to claim 11, wherein the structure and the electrode are buried underground in soil.

14. The method according to claim 13, further comprising connecting a DC power supply to the switch, wherein, in the state in which the switch is turned on, the DC power supply comprises a negative electrode connected to the electrode and a positive electrode connected to the structure, and a current from the structure toward the electrode flows via the soil.

15. The method according to claim 11, further comprising connecting a voltmeter, an ammeter, or a coulomb meter to the first wiring or the second wiring.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0014] FIG. 1 is a configuration diagram illustrating a configuration of a structure management system according to a first embodiment of the present invention.

[0015] FIG. 2 is a configuration diagram illustrating a configuration of a structure management system according to a second embodiment of the present invention.

DETAILED DESCRIPTION OF ILLUSTRATIVE EMBODIMENTS

[0016] Hereinafter, a structure management system according to embodiments of the present invention will be described.

First Embodiment

[0017] First, a structure management system according to a first embodiment of the present invention will be described with reference to FIG. 1. The structure management system includes a structure 101, a first wiring 102, an electrode 103, a second wiring 104, and a switch 105.

[0018] The structure 101 is made of a metal such as a steel material and is buried in the ground. The structure 101 is, for example, a metal pipe, is made of, for example, steel or brass, and has high strength required as a structure 101 used for a building or the like. Further, the structure 101 is inexpensive, generally corrodes due to oxidation, and eventually returns to so-called soil.

[0019] The first wiring 102 is connected to the structure 101. The first wiring 102 can be a coated conductive wire. The electrode 103 is made of metal and is buried in the ground in which the structure 101 is buried. The second wiring 104 is connected to the electrode 103. The second wiring 104 can be a coated conductive wire. The switch 105 turns on and off a conduction state between the first wiring 102 and the second wiring 104. In this example, the structure 101 and the electrode 103 are buried in the soil 110.

[0020] In addition, in a state where the switch 105 is turned on, the electrode 103 is in a higher potential state as compared to the structure 101. In the first embodiment, the electrode 103 is made of a metal having an ionization tendency lower than that of the metal included in the structure 101. For example, in a case where the structure 101 is made of a steel material, the electrode 103 can be made of nickel, copper, tin, silver, gold, platinum, or an alloy including these materials. In addition, a metal structurally including these metals can be used as the metal used for the electrode 103. With this configuration, when the switch 105 is turned on, the electrode 103 is brought in a higher potential state as compared to the structure 101. In addition, a distance between the structure 101 and the electrode 103 is within a range in which electrons generated when the metal of the structure 101 is ionized can reach the electrode 103.

[0021] Next, a structure management method using the structure management system according to the first embodiment will be described. First, one end of the first wiring 102 is electrically connected to the structure 101, and the structure 101 is buried in the soil 110. The other end of the first wiring 102 is exposed on a ground surface 11. Further, one end of the second wiring 104 is electrically connected to the electrode 103, and the electrode 103 is buried in the soil 110. The other end of the second wiring 104 is exposed on the ground surface 111. The other end of the first wiring 102 exposed on the ground surface in and the other end of the second wiring 104 are connected to the switch 105. In the soil 110, the distance between the structure 101 and the electrode 103 is within a range in which electrons generated when the metal of the structure 101 is ionized can reach the electrode 103.

[0022] During a period for which the structure 101 is used, the switch 105 is turned off. In this state, the structure 101 deteriorates at a normal soil corrosion rate. After the structure 101 is used for a predetermined period, the switch 105 is turned on in a stage where the structure 101 is renewed.

[0023] In this state, the structure 101 and the electrode 103 are electrically connected to each other via the first wiring 102 and the second wiring 104. The structure 101 serves as a negative electrode, and the electrode 103 serves as a positive electrode. Thereby, the soil 110 between the structure 101 and the electrode 103 configures a chemical battery that functions as an electrolyte and a separator. For this reason, corrosion (oxidation) of the structure 101 progresses faster than a normal corrosion (oxidation) rate of the soil 110.

[0024] As described above, according to the first embodiment, by turning on the switch 105, even in a case where the structure 101 to be renewed is left buried in the soil 110, the structure 101 can be corroded in a short period of time. Thus, a problem in environment and safety and a cost can be reduced.

[0025] Note that a shape of the structure 101 is not particularly limited. Similarly, a shape of the electrode 103 is not particularly limited. In addition, the electrode 103 has a shape that is easily driven into the soil 110, for example, a net shape, a stake shape, or a plate shape. Thus, the electrode 103 is easily buried in the soil 110. In addition, since the electrode 103 has the shape, the electrode 103 can be easily collected. Further, a plurality of electrodes 103 can be buried so as to surround the periphery of the structure 101. This configuration is preferable because the progress of corrosion described above is stabilized.

Second Embodiment

[0026] Next, a structure management system according to a second embodiment of the present invention will be described with reference to FIG. 2. The structure management system includes a structure 101, a first wiring 102, an electrode 103a, a second wiring 104, a switch 105, and a DC power supply 106. In a state where the switch 105 is turned on, a negative electrode of the DC power supply 106 is connected to the electrode 103a, and a positive electrode of the DC power supply 106 is connected to the structure 101.

[0027] In the second embodiment, when the switch 105 is turned on by the DC power supply 106, the structure 101 is polarized at a potential lower than a potential of the electrode 103a. In a case where the switch 105 is turned on, an output voltage of the DC power supply 106 is adjusted such that a current flows from the structure 101 toward the electrode 103a via the soil 110. In the second embodiment, the electrode 103a can be made of a metal having the same ionization tendency as the metal of the structure 101.

[0028] The DC power supply 106 can be a chemical battery or a solar battery. Further, as the DC power supply 106, for example, renewable energy such as solar power generation or wind power generation can be used. Further, in a case where the renewable energy is AC, a rectifier is used to generate DC. Further, the renewable energy can be used by being stored in a storage battery. Other configurations are similar to the configurations of the first embodiment described above.

[0029] Also in the second embodiment, first, one end of the first wiring 102 is electrically connected to the structure 101, and the structure 101 is buried in the soil 110. The other end of the first wiring 102 is exposed on a ground surface 11. Further, one end of the second wiring 104 is electrically connected to the electrode 103a, and the electrode 103a is buried in the soil 110. The other end of the second wiring 104 is exposed on the ground surface 111. The other end of the first wiring 102 exposed on the ground surface in and the other end of the second wiring 104 are connected to the switch 105 and the DC power supply 106. In the soil 110, the distance between the structure 101 and the electrode 103a is within a range in which electrons generated when the metal of the structure 101 is ionized can reach the electrode 103a.

[0030] During a period for which the structure 101 is used, the switch 105 is turned off. In this state, the structure 101 deteriorates at a normal soil corrosion rate. After the structure 101 is used for a predetermined period, the switch 105 is turned on in a stage where the structure 101 is renewed.

[0031] In this state, the structure 101 and the electrode 103a are connected to the DC power supply 106 via the first wiring 102 and the second wiring 104, and a current flows from the structure 101 toward the electrode 103a via the soil 110. For this reason, corrosion (oxidation) of the structure 101 progresses faster than a normal corrosion (oxidation) rate of the soil 110.

[0032] As described above, also in the second embodiment, by turning on the switch 105, even in a case where the structure 101 to be renewed is left buried in the soil 110, the structure 101 can be corroded in a short period of time. Thus, a problem in environment and safety and a cost can be reduced.

[0033] In addition, the structure management system according to the second embodiment can include any one of a voltmeter, an ammeter, and a coulomb meter connected to the first wiring 102 or the second wiring 104. With this configuration, in a corrosion period after the structure 101 becomes unnecessary, it is possible to estimate a corrosion state, a corrosion rate, a corrosion end period, and the like of the structure 101.

[0034] Further, in the second embodiment, the electrode 103a can be made of a new structure for renewing the structure 101. The new structure is the same as the structure 101. With this configuration, in a case where the structure 101 is used for a certain period and it is time to renew the structure 101, a new structure is buried in the soil 110 at a place different from the place at which the structure 101 is provided. Next, in a state where it is assumed that the newly-buried structure is to be the electrode 103a, the structure 101 to be renewed and the new structure are connected as described with reference to FIG. 2, and the switch 105 is turned on.

[0035] As a result, the corrosion rate of the structure 101 to be renewed is increased, and the corrosion period is shortened.

[0036] Further, at the same time, the newly-buried structure can be prevented from being corroded by an anticorrosion current flowing from the structure 101.

[0037] As described above, according to embodiments of the present invention, the electrode is buried around the metal structure which is buried in the ground and the electrode is caused to be in a higher potential state as compared to the structure. Thereby, the metal structure which is buried in the ground can be more quickly returned to the soil.

[0038] Note that the present invention is not limited to the embodiments described above, and it is obvious that many modifications and combinations can be implemented by those skilled in the art within a technical scope of the present invention.

REFERENCE SIGNS LIST

[0039]

TABLE-US-00001 101 structure 102 first wiring 103 electrode 103a electrode 104 second wiring 105 switch 106 DC power supply 110 soil 111 ground surface