TW201704743A - Magnetic electrode for monitoring degradation of coating of steel sheet and system of the same - Google Patents

Magnetic electrode for monitoring degradation of coating of steel sheet and system of the same Download PDF

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TW201704743A
TW201704743A TW104124405A TW104124405A TW201704743A TW 201704743 A TW201704743 A TW 201704743A TW 104124405 A TW104124405 A TW 104124405A TW 104124405 A TW104124405 A TW 104124405A TW 201704743 A TW201704743 A TW 201704743A
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coating
wire
magnet
steel sheet
electrode
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TW104124405A
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TWI585399B (en
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陳國銘
許瑞憲
吳進福
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中國鋼鐵股份有限公司
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Abstract

The present invention provides a magnetic electrode for monitoring degradation of a coating of a steel sheet. The magnetic electrode includes a metal element, at least one magnet, a first wire, and an embedding material. The metal element has a first portion with a hole and a second portion with an outer surface and an inner surface, in which the first portion is interconnected to the second portion. The first wire passes through the hole, and an angle between the first portion and the inner surface of the second portion is greater than 45 degree to less than 180 degree. The magnet is disposed on the inner surface of the second portion. The embedding material covers the first portion of the metal element, the magnet and a part of the first wire, while at least the outer surface of the second portion is exposed.

Description

用於監測鋼板塗層劣化之磁吸式電極及系統 Magnetic electrode and system for monitoring deterioration of steel coating

本發明是提供一種磁吸式電極,且特別是提供一種用於監測鋼板塗層劣化之磁吸式電極。 The present invention provides a magnetic electrode and, in particular, a magnetic electrode for monitoring deterioration of a steel sheet coating.

離岸風機或鑽油平台等設於海洋環境(例如潮間帶)中的鋼結構物,容易因為海水的強腐蝕性,使上述之結構物被腐蝕而失效。為避免腐蝕的發生,常以塗層覆於上述結構物之表面作為保護,塗層係將鋼結構物與海水中的腐蝕介質隔離,腐蝕介質如:水、離子或氧氣等。雖然塗層可減緩腐蝕的狀況,但隨時間經過,塗層仍會受到海水或紫外線等的影響而發生降解、起泡或剝離等劣化現象,而失去塗層原本的保護效能,進而使前述之鋼結構物被腐蝕而失效。 Steel structures such as offshore wind turbines or oil rigs that are located in marine environments (such as intertidal zones) are prone to corrosion and failure of the above structures due to the strong corrosive nature of seawater. In order to avoid the occurrence of corrosion, the coating is often applied to the surface of the above structure as a protection. The coating separates the steel structure from the corrosive medium in the seawater, such as water, ions or oxygen. Although the coating can alleviate the corrosion condition, the coating will still be degraded, foamed or peeled off due to the influence of sea water or ultraviolet rays, and the original protective performance of the coating will be lost, thereby making the foregoing The steel structure is corroded and fails.

因此,監測塗層腐蝕或劣化的狀態,以及早處理劣化的塗層,藉此避免發生鋼結構物失效的情況。當塗層劣化或被腐蝕時,其隔絕離子或電子之導電能力下降,因此所量測之導電度會上升(或是阻抗值會下降),因此一般以電 化學的方法監測塗層劣化的狀況。常見的電化學方法包括電化學交流阻抗譜(EIS)、局部電化學交流阻抗譜(LEIS)、掃描開爾文探針(SKP)或電化學雜訊(EN)等,其中又以電化學交流阻抗譜(EIS)最被廣泛使用。 Therefore, the state of corrosion or deterioration of the coating is monitored, and the deteriorated coating is treated early, thereby avoiding the occurrence of failure of the steel structure. When the coating is degraded or corroded, its conductivity to isolate ions or electrons decreases, so the measured conductivity will rise (or the impedance value will decrease), so it is generally A chemical method monitors the condition of coating degradation. Common electrochemical methods include electrochemical impedance spectroscopy (EIS), local electrochemical impedance spectroscopy (LEIS), scanning Kelvin probe (SKP) or electrochemical noise (EN), among which electrochemical impedance spectroscopy (EIS) is the most widely used.

電化學交流阻抗譜(EIS)係在待測體系上施加一個振幅很小的(一般為5mV至20mV)的交流電壓,經由量測其回應,得到塗層、溶液電阻、電容以及介面雙電層電容等有關塗層性能和失效過程中的訊息。 Electrochemical AC impedance spectroscopy (EIS) applies an AC voltage with a small amplitude (typically 5mV to 20mV) on the system to be tested. By measuring the response, the coating, solution resistance, capacitance and interface double layer are obtained. Capacitors and other information about coating properties and failure processes.

塗層在初期使用時為良好的隔絕層,具有極高的阻抗值,也延緩鋼結構物的腐蝕。但經由海水和紫外線的作用後,塗層阻抗值漸小。一般而言,良好完整的塗層之阻抗值高達108Ω,當塗層阻抗值降低至106Ω時,則可認為塗層已劣化(例如:腐蝕),阻抗值越低代表塗層的劣化越嚴重。 The coating is a good barrier layer in the initial use, has a very high resistance value, and also delays the corrosion of the steel structure. However, after the action of seawater and ultraviolet rays, the coating resistance value is gradually reduced. In general, a good and complete coating has an impedance value of up to 10 8 Ω. When the coating resistance value is reduced to 10 6 Ω, the coating is considered to be degraded (eg, corrosion), and the lower the impedance value, the coating The more serious the deterioration.

使用電化學交流阻抗譜進行阻抗值量測時,可使用三極式(工作電極、對電極和參考電極)或兩極式(工作電極和對電極)之阻抗分析儀進行測量。工作電極係電性連接至待測基材,對電極可連接至任一導體以形成電流流通的通路,且工作電極與對電極應浸泡於水溶液中以導電。 When measuring the impedance using an electrochemical impedance spectroscopy, measurements can be made using a three-pole (working electrode, counter and reference electrode) or two-pole (working and counter) impedance analyzers. The working electrode is electrically connected to the substrate to be tested, and the counter electrode can be connected to any conductor to form a path for current circulation, and the working electrode and the counter electrode should be immersed in the aqueous solution to conduct electricity.

習知之鋼板塗層劣化監測系統係使用黏貼式的導電金屬膠帶將作為電極之金屬薄片,黏貼於待測基材(例如前述之具有塗層的鋼結構物)的表面上,再藉由電化學阻抗分析儀量測塗層之阻抗值。其中,所使用之金屬薄片之材質可為鋁箔或銅箔。然而,上述之方法容易因潮間帶或飛沫 帶等長年潮濕的環境而造成黏貼式的導電金屬膠帶脫落,而使監測系統失效,且金屬薄片在海洋環境中也容易被腐蝕。 The conventional steel plate coating degradation monitoring system uses a sticky conductive metal tape to adhere a metal foil as an electrode to the surface of a substrate to be tested (for example, the aforementioned coated steel structure), and then electrochemically The impedance analyzer measures the impedance of the coating. The material of the metal foil used may be aluminum foil or copper foil. However, the above method is easy due to intertidal zone or droplets. With a long-term wet environment, the adhesive conductive metal tape is detached, which makes the monitoring system fail, and the metal foil is easily corroded in the marine environment.

另一種鋼板塗層劣化監測系統係使用導電金屬粉或之塗料或是墨水,直接塗覆於待測基材的表面上,以作為量測阻抗值時的電極。但是,在刷塗塗料前必須徹底清洗待測基材的表面,並待其乾燥後才能進行刷塗,工序較繁雜費時。此外,對待測基材表面進行清洗時,所使用的溶劑可能對待測基材本身帶來損傷。再者,含金屬粉之塗料或墨水並無法抵抗海水之腐蝕,且也不容易變換監測位置。 Another steel sheet coating degradation monitoring system is applied directly to the surface of the substrate to be tested using conductive metal powder or a coating or ink as an electrode for measuring the impedance value. However, the surface of the substrate to be tested must be thoroughly cleaned before the coating is applied, and the coating can be performed after it is dried, which is complicated and time consuming. In addition, when the surface of the substrate to be tested is cleaned, the solvent used may cause damage to the substrate itself to be tested. Furthermore, coatings or inks containing metal powder are not resistant to corrosion by seawater and it is not easy to change the monitoring position.

鑒於上述之種種缺點,目前亟需發展出一種用於監測鋼板塗層劣化之電極,以及使用此電極之鋼板塗層劣化監測系統,以改善前述缺點。 In view of the above disadvantages, there is an urgent need to develop an electrode for monitoring deterioration of a steel sheet coating, and a steel sheet coating deterioration monitoring system using the same to improve the aforementioned drawbacks.

因此,本發明之一態樣是提供一種用於監測鋼板塗層劣化之磁吸式電極,其包含特定材質之L型金屬部件並設置有磁石,可抗海水腐蝕並提供磁吸式的設置方式。 Therefore, an aspect of the present invention provides a magnetic electrode for monitoring degradation of a steel sheet coating, which comprises an L-shaped metal member of a specific material and provided with a magnet, which is resistant to seawater corrosion and provides a magnetic arrangement. .

本發明之另一態樣是提供一種鋼板塗層劣化監測系統,其係使用上述之磁吸式電極,以磁吸的方式固定於待測基材上,並監測鋼板塗層的劣化情形。 Another aspect of the present invention provides a steel sheet coating deterioration monitoring system which is magnetically fixed to a substrate to be tested using the above-described magnetic electrode and monitors deterioration of the steel sheet coating.

根據本發明之上述態樣,提出一種用於監測鋼板塗層劣化之磁吸式電極。在一實施例中,磁吸式電極包含L型金屬部件、至少一磁石、第一導線以及包覆材。L型金屬部件具有互相連接之第一部分和第二部分,第一部分具有 孔洞,第二部分具有內表面以及相對於內表面之外表面,且第一部分與第二部分之內表面形成大於45度至小於180度之夾角。至少一磁石係設置於第二部分的內表面上。第一導線係穿設於上述孔洞中,且第一導線係與L型金屬部件電性連接。上述之包覆材係包覆L型金屬部件之第一部分、磁石和部分的第一導線,且至少露出第二部分之外表面。 According to the above aspect of the invention, a magnetic electrode for monitoring deterioration of a steel sheet coating is proposed. In an embodiment, the magnetic electrode comprises an L-shaped metal component, at least one magnet, a first wire, and a cladding material. The L-shaped metal member has a first portion and a second portion connected to each other, the first portion having The second portion has an inner surface and an outer surface opposite the inner surface, and the first portion forms an included angle with the inner surface of the second portion that is greater than 45 degrees to less than 180 degrees. At least one magnet is disposed on an inner surface of the second portion. The first wire is threaded through the hole, and the first wire is electrically connected to the L-shaped metal component. The cladding material described above covers the first portion of the L-shaped metal member, the magnet and a portion of the first wire, and at least exposes the outer surface of the second portion.

依據本發明之一實施例,L型金屬部件可包含鈦合金、鎳基合金或不鏽鋼材。 According to an embodiment of the present invention, the L-shaped metal member may comprise a titanium alloy, a nickel-based alloy or a stainless steel material.

依據本發明之一實施例,磁石可為永久磁石。 According to an embodiment of the invention, the magnet may be a permanent magnet.

依據本發明之一實施例,包覆材可包含聚脲酯、聚氨酯或含氟樹脂。 According to an embodiment of the invention, the cladding material may comprise a polyurea ester, a polyurethane or a fluororesin.

依據本發明之一實施例,磁石與第二部分間更包含黏著層,以固定磁石於第二部分上。 According to an embodiment of the invention, the magnet and the second portion further comprise an adhesive layer to fix the magnet on the second portion.

根據本發明之另一態樣,提供一種鋼板塗層劣化監測系統。在一實施例中,上述之鋼板塗層劣化監測系統包含待測基材、磁吸式電極、阻抗分析儀和第二導線。其中,待測基材包含基材層和包覆部分基材層的塗層,且基材層可為具磁性之金屬板材。磁吸式電極係磁吸地設置於待測基材的塗層上,且磁吸式電極包含L型金屬部件、至少一磁石、第一導線以及包覆材。L型金屬部件具有互相連接之第一部分和第二部分,第一部分具有孔洞,第二部分具有內表面以及相對於內表面之外表面,且第一部分與第二部分之內表面形成大於45度至小於180度之夾角。至少一磁石係設置於第二部分的內表面上。第一導線係穿設於上述孔洞中,且第一 導線係與L型金屬部件電性連接。上述之包覆材係包覆L型金屬部件之第一部分、磁石和部分的第一導線,且至少露出第二部分之外表面。在鋼板塗層劣化監測系統中,第一導線電性連接磁吸式電極和阻抗分析儀,而第二導線電性連接未被塗層包覆之剩餘部分的基材層與阻抗分析儀。 According to another aspect of the present invention, a steel sheet coating degradation monitoring system is provided. In one embodiment, the steel sheet coating degradation monitoring system described above includes a substrate to be tested, a magnetic electrode, an impedance analyzer, and a second wire. Wherein, the substrate to be tested comprises a substrate layer and a coating layer covering a part of the substrate layer, and the substrate layer may be a magnetic metal plate. The magnetic electrode is magnetically disposed on the coating of the substrate to be tested, and the magnetic electrode comprises an L-shaped metal member, at least one magnet, a first wire, and a cladding material. The L-shaped metal member has a first portion and a second portion that are interconnected, the first portion having a hole, the second portion having an inner surface and an outer surface opposite the inner surface, and the first portion and the inner surface of the second portion forming greater than 45 degrees to Less than 180 degrees. At least one magnet is disposed on an inner surface of the second portion. The first wire is threaded through the hole and is first The wire is electrically connected to the L-shaped metal component. The cladding material described above covers the first portion of the L-shaped metal member, the magnet and a portion of the first wire, and at least exposes the outer surface of the second portion. In the steel sheet coating degradation monitoring system, the first wire is electrically connected to the magnetic electrode and the impedance analyzer, and the second wire is electrically connected to the substrate layer and the impedance analyzer of the remaining portion not covered by the coating.

依據本發明之一實施例,鋼板塗層劣化監測系統更包含第三導線,電性連接磁吸式電極和阻抗分析儀。在鋼板塗層劣化監測系統中,第一導線係連接至阻抗分析儀之對電極端,第二導線係連接至阻抗分析儀之工作電極端,且第三導線係連接至阻抗分析儀之參考電極端。 According to an embodiment of the invention, the steel sheet coating degradation monitoring system further comprises a third wire electrically connected to the magnetic electrode and the impedance analyzer. In the steel sheet coating degradation monitoring system, the first wire is connected to the opposite electrode end of the impedance analyzer, the second wire is connected to the working electrode end of the impedance analyzer, and the third wire is connected to the reference electrode of the impedance analyzer. extreme.

依據本發明之一實施例,磁吸式電極之外表面磁吸地設置於待測基材的塗層上。 According to an embodiment of the invention, the outer surface of the magnetic electrode is magnetically disposed on the coating of the substrate to be tested.

依據本發明之一實施例,上述之阻抗分析儀為交流阻抗分析儀或塗層監測儀。 According to an embodiment of the invention, the impedance analyzer is an AC impedance analyzer or a coating monitor.

應用本發明之用於監測鋼板塗層劣化之磁吸式電極和鋼板塗層劣化監測系統,可有效克服習知黏貼式電極,因長時間浸泡於海水中而造成電極腐蝕損壞,或是黏貼層脫落,以致於無法及時得知塗層缺陷的缺點。此外,磁吸式電極可為可攜式電極,以方便改變監測位置。 The magnetic electrode and the steel plate coating degradation monitoring system for monitoring the deterioration of the steel plate coating of the present invention can effectively overcome the conventional adhesive electrode, which is caused by corrosion of the electrode due to immersion in seawater for a long time, or an adhesive layer. Falling off, so that the shortcomings of coating defects cannot be known in time. In addition, the magnetic electrode can be a portable electrode to facilitate changing the monitoring position.

100‧‧‧磁吸式電極 100‧‧‧Magnetic electrode

110‧‧‧L型金屬部件 110‧‧‧L type metal parts

111‧‧‧第一部分 111‧‧‧Part 1

113‧‧‧第二部分 113‧‧‧Part II

113a‧‧‧內表面 113a‧‧‧ inner surface

113b‧‧‧外表面 113b‧‧‧ outer surface

115‧‧‧孔洞 115‧‧‧ holes

120‧‧‧磁石 120‧‧‧ Magnet

130‧‧‧第一導線 130‧‧‧First wire

140‧‧‧包覆材 140‧‧‧Covering material

150‧‧‧黏著層 150‧‧‧Adhesive layer

200‧‧‧鋼板塗層劣化監測系統 200‧‧‧Steel coating degradation monitoring system

210‧‧‧待測基材 210‧‧‧Substrate to be tested

211‧‧‧基材層 211‧‧‧ substrate layer

213‧‧‧塗層 213‧‧‧Coating

220‧‧‧磁吸式電極 220‧‧‧Magnetic electrode

221‧‧‧第一導線 221‧‧‧First wire

223‧‧‧第三導線 223‧‧‧ Third wire

230‧‧‧阻抗分析儀 230‧‧‧ Impedance Analyzer

231‧‧‧對電極端 231‧‧‧electrode end

233‧‧‧工作電極端 233‧‧‧Working electrode end

235‧‧‧參考電極端 235‧‧‧ reference electrode end

240‧‧‧第二導線 240‧‧‧second wire

301、305‧‧‧阻抗值之對數值 301, 305‧‧‧ the logarithm of the impedance value

303、307‧‧‧相位角 303, 307‧‧‧ phase angle

T‧‧‧厚度 T‧‧‧ thickness

W‧‧‧寬度 W‧‧‧Width

L1‧‧‧第一長度 L 1 ‧‧‧First length

L2‧‧‧第二長度 L 2 ‧‧‧second length

θ‧‧‧夾角 Θ‧‧‧ angle

為讓本發明之上述和其他目的、特徵、優點與實施例能更明顯易懂,所附圖式之詳細說明如下: [圖1]係繪示根據本發明之一實施例所述之用於監測鋼板塗層劣化之磁吸式電極的示意圖;[圖2]係繪示根據本發明之一實施例所述之鋼板塗層劣化監測系統的示意圖;[圖3A]係繪示根據本發明之一實施例之阻抗值的波德圖(Bode Plot);[圖3B]係繪示根據本發明之一比較例之阻抗值的波德圖(Bode Plot)。 The above and other objects, features, advantages and embodiments of the present invention will become more apparent and understood. 1 is a schematic view showing a magnetic electrode for monitoring deterioration of a steel sheet coating according to an embodiment of the present invention; [FIG. 2] showing a steel sheet according to an embodiment of the present invention. A schematic diagram of a coating degradation monitoring system; [Fig. 3A] shows a Bode Plot of impedance values according to an embodiment of the present invention; [Fig. 3B] shows an impedance according to a comparative example of the present invention. The value of the Bode Plot.

以下提供了許多不同實施例或例子,以實施本發明之不同特徵。以下所描述之構件與安排的特定例子係用以簡化本發明。當然這些僅為例子,並非用以做為限制。舉例而言,於描述中,第一特徵形成於第二特徵上方或上,可能包含第一特徵與第二特徵以直接接觸的方式形成的實施例,亦可包含額外特徵可能形成在第一特徵與第二特徵之間的實施例,如此第一特徵與第二特徵可能不會直接接觸。此外,本發明可能會在各例子中重複元件符號和/或字母。這樣的重複係基於簡化與清楚之目的,以其本身而言並非用以指定所討論之各實施例及/或配置之間的關係。 Many different embodiments or examples are provided below to implement various features of the invention. Specific examples of the components and arrangements described below are used to simplify the invention. Of course, these are only examples and are not intended to be limiting. For example, in the description, the first feature is formed on or over the second feature, and may include an embodiment in which the first feature and the second feature are formed in direct contact, and may also include additional features that may be formed in the first feature. With the embodiment between the second feature, such first feature and second feature may not be in direct contact. Furthermore, the invention may repeat the component symbols and/or letters in the various examples. Such repetitions are based on the simplification and clarity of the invention and are not intended to define the relationship between the various embodiments and/or configurations discussed.

本發明此處所稱之鋼板塗層劣化係指包覆鋼板(或稱基材)之塗層,因長時間浸泡於腐蝕性較高的海水或其他溶液中、經紫外線照射或其他原因等外在因素,所造成的包覆鋼板之塗層有破損或劣化的狀況。 The term "deterioration of the steel sheet coating" as used herein means a coating of a coated steel sheet (or a substrate), which is externally immersed in a highly corrosive seawater or other solution, irradiated by ultraviolet rays or the like. Factor, the coating of the coated steel sheet is damaged or deteriorated.

首先,請先參照圖1。圖1係繪示依據本發明之一實施例之用於監測鋼板塗層劣化之磁吸式電極。磁吸式電極100包含L型金屬部件110、磁石120、第一導線130和包覆材140。L型金屬部件110具有相互連接之第一部分111和第二部分113,第一部分111具有孔洞115,第二部分113具有內表面113a及相對於內表面113a之外表面113b,且第一部分111與第二部分113之內表面113a形成大於45度至小於180度之夾角θ。在一實施例中,夾角θ可例如為90度。L型金屬部件110可由金屬薄片一體成型或由二部份銲接而成。當L型金屬部件110由金屬薄片一體成型時,可將金屬薄片的一部分彎折以形成第一部分111,而金屬薄片之未彎折部分則為第二部分113。 First, please refer to Figure 1 first. BRIEF DESCRIPTION OF THE DRAWINGS Figure 1 is a diagram showing a magnetic electrode for monitoring deterioration of a steel sheet coating according to an embodiment of the present invention. The magnetic electrode 100 includes an L-shaped metal member 110, a magnet 120, a first wire 130, and a covering member 140. The L-shaped metal member 110 has a first portion 111 and a second portion 113 connected to each other, the first portion 111 has a hole 115, the second portion 113 has an inner surface 113a and an outer surface 113b with respect to the inner surface 113a, and the first portion 111 and the first portion The inner surface 113a of the two portions 113 forms an included angle θ of more than 45 degrees to less than 180 degrees. In an embodiment, the included angle θ may be, for example, 90 degrees. The L-shaped metal member 110 may be integrally formed from a metal foil or welded by two parts. When the L-shaped metal member 110 is integrally molded from a metal foil, a portion of the metal foil may be bent to form the first portion 111, and the unbent portion of the metal foil is the second portion 113.

如圖1所示,磁石120係設置於第二部分113的內表面113a上。第一導線130係穿設於孔洞115中,並與L型金屬部件110電性連接。在一實施例中,第一導線130可以螺栓固定於孔洞115中。而包覆材140係包覆L型金屬部件110之第一部分111、磁石120和部分之第一導線130,且至少露出第二部分113之外表面113b。 As shown in FIG. 1, the magnet 120 is disposed on the inner surface 113a of the second portion 113. The first wire 130 is inserted through the hole 115 and electrically connected to the L-shaped metal member 110. In an embodiment, the first wire 130 may be bolted to the hole 115. The cladding material 140 covers the first portion 111 of the L-shaped metal member 110, the magnet 120 and a portion of the first wire 130, and at least exposes the outer surface 113b of the second portion 113.

在一實施例中,磁石120可利用包覆材140固定於L型金屬部件110之第二部分113上。在另一實施例中,磁石120和第二部分113間可包含黏著層150,以將磁石120黏著固定於第二部分113上。黏著層150可為瞬間接著劑或任何習知之黏著劑,此處並無特別限制。 In one embodiment, the magnet 120 can be secured to the second portion 113 of the L-shaped metal component 110 using a cladding material 140. In another embodiment, an adhesive layer 150 may be included between the magnet 120 and the second portion 113 to adhere the magnet 120 to the second portion 113. The adhesive layer 150 may be an instant adhesive or any conventional adhesive, and is not particularly limited herein.

在如圖1所示之實施例中,僅使用兩個磁石 120,然磁石120的數量可隨L型金屬部件110的大小進行調整,例如可為1個、3個、4個或者更多。 In the embodiment shown in Figure 1, only two magnets are used. 120. The number of magnets 120 may be adjusted according to the size of the L-shaped metal member 110, and may be, for example, one, three, four or more.

在一實施例中,磁吸式電極100為可攜式電極。若將L型金屬部件110攤平(意即使第一部分111和第二部分113間的夾角θ呈180度),L型金屬部件110可具有0.2毫米至2毫米之厚度T以及2公分至10公分之寬度W。而第一部分111可具有1公分至2公分之第一長度L1,第二部分113可具有10公分至20公分之第二長度L2,且第一長度L1與第二長度L2的和即為攤平後之L型金屬部件110長邊的長度。然而,L型金屬部件110之大小可隨設計需求調整,此處所揭示之數值僅為說明而非用以限制本發明之範圍。 In an embodiment, the magnetic electrode 100 is a portable electrode. If the L-shaped metal member 110 is flattened (meaning that even if the angle θ between the first portion 111 and the second portion 113 is 180 degrees), the L-shaped metal member 110 may have a thickness T of 0.2 mm to 2 mm and 2 cm to 10 cm. The width W. Whereas the first portion 111 may have a first length L 1 of 1 cm to 2 cm, and the second portion 113 may have a second length L 2 of 10 cm to 20 cm, and the sum of the first length L 1 and the second length L 2 That is, the length of the long side of the flattened L-shaped metal member 110. However, the size of the L-shaped metal component 110 can be adjusted to the design requirements, and the values disclosed herein are illustrative only and are not intended to limit the scope of the invention.

L型金屬部件110之材質可包含鈦合金、鎳基合金或不鏽鋼材。上述之不鏽鋼材的具體例子可為AL-6XN、254SMO、654SMO或其他類似的材料。使用上述材質所製得之L型金屬部件110,可具有較佳地抗腐蝕性,因此所製得之磁吸式電極不易因長期浸泡於海水中而損壞。 The material of the L-shaped metal member 110 may include a titanium alloy, a nickel-based alloy, or a stainless steel material. Specific examples of the above stainless steel material may be AL-6XN, 254SMO, 654SMO or the like. The L-shaped metal member 110 obtained by using the above material can have better corrosion resistance, so that the magnetic electrode obtained is not easily damaged by long-term immersion in seawater.

磁石120可為永久磁石,具體可例如為釹鐵硼磁石或釤鈷磁鐵等稀土元素磁鐵、鐵氧體磁鐵或鋁鎳鈷合金磁鐵等,然以釹鐵硼磁石為較佳。 The magnet 120 may be a permanent magnet, and specifically, for example, a rare earth element magnet such as a neodymium iron boron magnet or a samarium cobalt magnet, a ferrite magnet, or an alnico magnet, etc., and a neodymium iron boron magnet is preferable.

而包覆材之材質可包含聚脲酯、聚氨酯或含氟樹脂。含氟樹脂之具體例子可例如為鐵氟龍、聚三氟氯乙烯(PCTFE)、聚偏氟乙烯(PVDF)、乙烯-四氟乙烯共聚物(ETFE)、乙烯-三氟氯乙烯共聚物(ECTFE)、聚氟乙烯(PVF)、四氟乙烯-全氟烷基乙烯基醚共聚物(或稱可熔性聚 四氟乙烯;PFA)、四氟乙烯-六氟丙烯共聚物(或稱氟塑料46;FEP)、四氟乙烯-六氟丙烯-全氟烷基乙烯基醚共聚物等。 The material of the covering material may comprise polyurea ester, polyurethane or fluorine resin. Specific examples of the fluorine-containing resin may, for example, be Teflon, polychlorotrifluoroethylene (PCTFE), polyvinylidene fluoride (PVDF), ethylene-tetrafluoroethylene copolymer (ETFE), and ethylene-chlorotrifluoroethylene copolymer ( ECTFE), polyvinyl fluoride (PVF), tetrafluoroethylene-perfluoroalkyl vinyl ether copolymer (or fusible polymer) Tetrafluoroethylene; PFA), tetrafluoroethylene-hexafluoropropylene copolymer (or fluoroplastic 46; FEP), tetrafluoroethylene-hexafluoropropylene-perfluoroalkyl vinyl ether copolymer, and the like.

接下來請參照圖2。圖2係繪示本發明之一實施例之鋼板塗層劣化監測系統。鋼板塗層劣化監測系統200包含待測基材210、磁吸式電極220、阻抗分析儀230和第二導線240。待測基材210包含基材層211與包覆基材層211之塗層213,其中基材層211部分地被塗層213包覆。磁吸式電極220係磁吸地設置於待測基材210。在鋼板塗層劣化監測系統200中,第一導線221係電性連接磁吸式電極220和阻抗分析儀230,且第二導線240係電性連接待測基材210之未被塗層213包覆之基材層211和阻抗分析儀230。 Next, please refer to Figure 2. 2 is a diagram showing a steel sheet coating degradation monitoring system according to an embodiment of the present invention. The steel sheet coating degradation monitoring system 200 includes a substrate to be tested 210, a magnetic electrode 220, an impedance analyzer 230, and a second wire 240. The substrate to be tested 210 includes a substrate layer 211 and a coating layer 213 covering the substrate layer 211, wherein the substrate layer 211 is partially covered by the coating layer 213. The magnetic electrode 220 is magnetically disposed on the substrate 210 to be tested. In the steel plate coating degradation monitoring system 200, the first wire 221 is electrically connected to the magnetic electrode 220 and the impedance analyzer 230, and the second wire 240 is electrically connected to the uncoated 213 package of the substrate 210 to be tested. The substrate layer 211 and the impedance analyzer 230 are covered.

補充說明的是,如圖2所示之磁吸式電極220具有與如圖1所示之磁吸式電極100相同之結構,其中磁吸式電極100之第一導線130可與磁吸式電極220之第一導線221對應,故此處不另贅述。 It is to be noted that the magnetic electrode 220 shown in FIG. 2 has the same structure as the magnetic electrode 100 shown in FIG. 1, wherein the first wire 130 of the magnetic electrode 100 can be combined with the magnetic electrode. The first wire 221 of 220 corresponds to each other, so it will not be described here.

磁吸設置於待測基材210上的磁吸式電極220,可以其L型金屬部件的外表面(如圖1所示之外表面113b)或包覆材(如圖1所示之包覆材140)的一側接觸並磁吸設置於待測基材210上。在此實施例中,以L型金屬部件的外表面磁吸設置於待測基材210上。 The magnetic attraction electrode 220 disposed on the substrate 210 to be tested may be magnetically coated on the outer surface of the L-shaped metal member (the outer surface 113b as shown in FIG. 1) or the cladding material (coated as shown in FIG. 1). One side of the material 140) is contacted and magnetically placed on the substrate 210 to be tested. In this embodiment, the outer surface of the L-shaped metal member is magnetically placed on the substrate to be tested 210.

待測基材210的基材層211和塗層213並未特別限定,可使用習知任何用於海洋鋼結構物之基材和抗腐蝕塗層。但特別說明的是,為使本發明之磁吸式電極220可以 磁吸方式設置於待測基材210上,待測基材210之材質須具有磁性。 The base material layer 211 and the coating layer 213 of the substrate 210 to be tested are not particularly limited, and any substrate and corrosion-resistant coating for marine steel structures can be used. However, it is specifically stated that in order to make the magnetic electrode 220 of the present invention The magnetic attraction mode is set on the substrate 210 to be tested, and the material of the substrate to be tested 210 must be magnetic.

在一實施例中,鋼板塗層劣化監測系統200可更包含第三導線223,且其係電性連接磁吸式電極220和阻抗分析儀230。此外,在鋼板塗層劣化監測系統200中,第一導線221係連接至阻抗分析儀230之對電極端231,第二導線240係連接至阻抗分析儀230之工作電極端233,而第三導線223係連接至阻抗分析儀230之參考電極端235。 In an embodiment, the steel sheet coating degradation monitoring system 200 may further include a third wire 223 electrically connected to the magnetic electrode 220 and the impedance analyzer 230. Further, in the steel sheet coating degradation monitoring system 200, the first wire 221 is connected to the counter electrode end 231 of the impedance analyzer 230, the second wire 240 is connected to the working electrode terminal 233 of the impedance analyzer 230, and the third wire is connected. The 223 is connected to the reference electrode terminal 235 of the impedance analyzer 230.

阻抗分析儀230可為交流阻抗分析儀或塗層監測儀。因此,本發明之鋼板塗層劣化監測系統可利用電化學阻抗法(Electrochemical Impedance Spectrum;EIS)進行。電化學阻抗法之原理及進行方式應為本技術領域具有通常知識者熟知,故此處不另贅述。 The impedance analyzer 230 can be an AC impedance analyzer or a coating monitor. Therefore, the steel sheet coating deterioration monitoring system of the present invention can be performed by Electrochemical Impedance Spectrum (EIS). The principle and the manner of carrying out the electrochemical impedance method should be well known to those of ordinary skill in the art, and therefore will not be further described herein.

在一實施例中,前述之交流阻抗分析儀可為三極式(即包含工作電極、對電極和參考電極),可偵測掃描頻率範圍(例如:1mHz至10kHz)之阻抗值並繪示為波德圖(Bode Plot),其所得結果較精確但無法簡易安裝於現場(例如海洋環境中)。此外,此處所稱之交流阻抗分析儀較靈敏,因此也可於導電度較低的溶液(如自來水或雨水等)中進行阻抗值之監測。 In an embodiment, the foregoing AC impedance analyzer can be a three-pole type (ie, including a working electrode, a counter electrode, and a reference electrode), and can detect an impedance value of a scanning frequency range (for example, 1 mHz to 10 kHz) and Bode Plot, the results obtained are more accurate but cannot be easily installed on site (such as in the marine environment). In addition, the AC impedance analyzer referred to here is more sensitive, so it is also possible to monitor the impedance value in a solution with low conductivity (such as tap water or rain water).

在另一實施例中,前述之塗層監測儀可為任何市售之塗層監測儀,其可為二極式(僅包含工作電極和對電極),由於體積較小方便安裝於現場,然僅可偵測特定之頻率(例如:0.2Hz、0.5Hz或0.9Hz)。因此,當阻抗分析儀 230為塗層監測儀時,可以不包含參考電極端235和第三導線223(圖未繪示)。 In another embodiment, the foregoing coating monitor can be any commercially available coating monitor, which can be a two-pole type (only working electrode and counter electrode), and is convenient to be installed on site due to its small size. Only specific frequencies can be detected (eg 0.2Hz, 0.5Hz or 0.9Hz). Therefore, when the impedance analyzer When 230 is a coating monitor, the reference electrode end 235 and the third wire 223 (not shown) may not be included.

此外,本發明之鋼板塗層劣化監測系統係使用磁吸式電極作為對電極及參考電極,其係直接磁吸地設置於待測基材上,並以週遭溶液(例如:海水)為電解液,故不額外設置溶液槽承裝電解溶液以及電極,因此也不設置用以密封溶液槽的任何元件。 In addition, the steel plate coating degradation monitoring system of the present invention uses a magnetic electrode as a counter electrode and a reference electrode, which is directly magnetically placed on the substrate to be tested, and uses a surrounding solution (for example, seawater) as an electrolyte. Therefore, the solution tank is not additionally provided to carry the electrolytic solution and the electrode, and therefore no component for sealing the solution tank is provided.

以下利用實施例以說明本發明之應用,然其並非用以限定本發明,於本發明所屬技術領域中具有通常知識者,在不脫離本發明之精神與範圍內,當可作各種更動與潤飾。 The following examples are used to illustrate the application of the present invention, and are not intended to limit the present invention. Those skilled in the art can make various changes and modifications without departing from the spirit and scope of the present invention. .

設置鋼板塗層劣化監測系統Set steel plate coating degradation monitoring system

實施例Example

本發明之實施例係先對長22公分、寬16公分以及厚4毫米之鋼板進行表面噴砂處理至瑞典標準協會SIS-05-5900除鏽度之Sa21/2。接著,對表面噴砂處理後之鋼板的全六面進行噴塗步驟,以在鋼板的六面皆覆上厚度約84微米的環氧樹脂塗層。之後再進行固化作用以製得所需的待測基材。 In the embodiment of the present invention, the steel plate having a length of 22 cm, a width of 16 cm and a thickness of 4 mm is sandblasted to the Sa2 1/2 of the Swedish Standards Association SIS-05-5900. Next, a spray coating step was applied to all six sides of the surface blasted steel sheet to coat the six sides of the steel sheet with an epoxy resin coating having a thickness of about 84 μm. Curing is then carried out to produce the desired substrate to be tested.

接下來,將待測基材之一角的塗層磨除,以露出鋼板,並使用導線將露出的鋼板電性連接至塗層監測儀(Coating Health Monitor,由ElectraWatch公司製造)的工作電極端。然後,將本發明之磁吸式電極磁吸地設置於待 測基材的表面上,並以另一導線將磁吸式電極電性連接至塗層監測儀之對電極端。之後,將待測基材、磁吸式電極和部分導線斜放入3升的玻璃槽內,並加入3.5重量%之氯化鈉溶液至待測基材的一半高度,使磁吸式電極浸泡於氯化鈉溶液中。 Next, the coating of one corner of the substrate to be tested was abraded to expose the steel sheet, and the exposed steel sheet was electrically connected to the working electrode end of a coating monitor (Coating Health Monitor, manufactured by ElectraWatch Co., Ltd.) using a wire. Then, the magnetic electrode of the present invention is magnetically placed on the The surface of the substrate is measured, and the magnetic electrode is electrically connected to the opposite electrode end of the coating monitor by another wire. After that, the substrate to be tested, the magnetic electrode and a part of the wire are obliquely placed in a 3 liter glass tank, and a 3.5% by weight sodium chloride solution is added to a half height of the substrate to be tested to soak the magnetic electrode. In sodium chloride solution.

上述之鋼板塗層劣化監測系統係以下述之評價方式進行評價。 The steel sheet coating deterioration monitoring system described above was evaluated in the following evaluation manner.

比較例Comparative example

比較例之鋼板塗層劣化監測系統係使用與實施例相同之設置方式,不同的是,比較例係將磁吸式電極置換為市售之導電鋁箔(3M公司製造),並以黏貼的方式將導電鋁箔設置於待測基材上。 The steel sheet coating deterioration monitoring system of the comparative example uses the same arrangement as the embodiment, except that the comparative example replaces the magnetic electrode with a commercially available conductive aluminum foil (manufactured by 3M Company) and pastes it. The conductive aluminum foil is disposed on the substrate to be tested.

評價方式Evaluation method 1.待測基材之阻抗值1. Impedance value of the substrate to be tested

本發明所稱之待測基材的阻抗值係先設定上述實施例和比較例之塗層監測儀,以進行每天一次的量測。持續進行量測達7天後,從待測基材底部距離磁吸式電極或導電鋁箔約10公分處,以刀片割開塗層,再繼續進行監測。若割開後之待測基材的阻抗值小於割開前之待測基材的阻抗值,表示磁吸式電極或導電鋁箔可有效地監測塗層之破損。待測基材之阻抗值之評價結果悉如表1所示。 The impedance value of the substrate to be tested referred to in the present invention is first set by the coating monitors of the above embodiments and comparative examples to perform measurement once a day. After continuous measurement for 7 days, the coating was cut by a blade from the bottom of the substrate to be tested about 10 cm away from the magnetic electrode or the conductive aluminum foil, and monitoring was continued. If the impedance value of the substrate to be tested after cutting is smaller than the impedance value of the substrate to be tested before cutting, it means that the magnetic electrode or the conductive aluminum foil can effectively monitor the damage of the coating. The evaluation results of the impedance values of the substrates to be tested are shown in Table 1.

2.電極外觀2. Electrode appearance

本發明所稱之電極外觀係觀察經長時間浸泡於氯化鈉溶液中的磁吸式電極或導電鋁箔有無被腐蝕或破損之情況,電極外觀之狀況以下列方式評價: The appearance of the electrode referred to in the present invention is a condition in which the magnetic electrode or the conductive aluminum foil immersed in the sodium chloride solution for a long time is corroded or damaged, and the appearance of the electrode is evaluated in the following manner:

○:無腐蝕且未從待測基材上脫落 ○: no corrosion and no peeling off from the substrate to be tested

×:腐蝕且從待測基材上有局部脫落 ×: corroded and partially peeled off from the substrate to be tested

電極外觀之評價結果悉如表1所示。 The evaluation results of the appearance of the electrodes are shown in Table 1.

3.待測基材之低頻區阻抗值3. Low-frequency zone impedance value of the substrate to be tested

將完成前述阻抗值評價之實施例與比較例的鋼板塗層劣化監測系統之塗層監測儀取代為交流阻抗分析儀(BioLogic公司;VSP),以監測待測基材之低頻區阻抗值。其中待測基材係以導線電性連接至交流阻抗分析儀之工作電極端,磁吸式電極或導電鋁箔係以另外兩條導線分別電性連接至交流阻抗分析儀之對電極端和參考電極端,並以自來水作為電解質溶液。交流阻抗分析儀所施加的電壓為10mV,掃描電流頻率為1mHz至10kHz,並觀察低頻區阻抗值的變化,其中又以1Hz以下為低頻區。當低頻區之阻抗值的對數值低於6時,表示塗層有破損。評價結果悉如圖3A和圖3B所示。 The coating monitor of the steel sheet coating degradation monitoring system of the examples of the foregoing impedance evaluation and the comparative example was replaced with an AC impedance analyzer (BioLogic; VSP) to monitor the low frequency region impedance value of the substrate to be tested. The substrate to be tested is electrically connected to the working electrode end of the AC impedance analyzer, and the magnetic electrode or the conductive aluminum foil is electrically connected to the opposite electrode end of the AC impedance analyzer and the reference electrode. Extremely, and use tap water as an electrolyte solution. The voltage applied by the AC impedance analyzer is 10 mV, the scanning current frequency is 1 mHz to 10 kHz, and the change of the impedance value in the low frequency region is observed, wherein the low frequency region is below 1 Hz. When the logarithm of the impedance value of the low frequency region is less than 6, it indicates that the coating is damaged. The evaluation results are shown in Fig. 3A and Fig. 3B.

首先,請參照表1。本發明之實施例和比較例之鋼板塗層劣化監測系統在未割開之待測基材所量測到的阻抗值皆為5×108Ω,而在割開之待測基材所量測到的阻抗值 分別為3×103Ω至5×103Ω和2×103Ω至4×103Ω。顯示本發明之本發明之實施例和比較例之鋼板塗層劣化監測系統皆能有效監測塗層的劣化狀況。然而,實施例的電極在經過長時間浸泡於氯化鈉溶液中後,外觀仍保持完整未被腐蝕,也未從待測基材上脫落。但比較例之導電鋁箔的外觀有被腐蝕的狀況,並局部從待測基材上脫落。 First, please refer to Table 1. Coil coating deterioration monitoring system according to examples and comparative examples of the present invention is not to be measured in the base of the cut to the measured impedance values are all 5 × 10 8 Ω, and the amount of cut in the substrate to be tested The measured impedance values were 3 × 10 3 Ω to 5 × 10 3 Ω and 2 × 10 3 Ω to 4 × 10 3 Ω, respectively. The steel sheet coating deterioration monitoring system of the embodiment of the present invention and the comparative example of the present invention can effectively monitor the deterioration state of the coating. However, after the electrode of the example was immersed in the sodium chloride solution for a long time, the appearance remained intact and was not corroded, nor dropped from the substrate to be tested. However, the appearance of the conductive aluminum foil of the comparative example was corroded and partially peeled off from the substrate to be tested.

根據表1的結果可知,應用本發明之實施例的磁吸式電極,可有效監測塗層破損的狀況,並在氯化鈉溶液中維持良好的外觀狀態。 According to the results of Table 1, the magnetic electrode to which the embodiment of the present invention is applied can effectively monitor the condition of the coating breakage and maintain a good appearance state in the sodium chloride solution.

接下來,請參照圖3A。圖3A係繪示根據本發明之一實施例之鋼板塗層劣化監測系統進行監測所得之波德圖,其中所使用之待測基材係割開後的破損待測基材。圖3A中,線段301代表阻抗值之對數值,而線段303代表相位角。一般對塗層劣化程度進行監測時,主要評估其在低頻區(1Hz以下)之阻抗值,通常以106Ω為標準,當低於106Ω(對數值為6)時代表塗層有劣化、破損或被腐蝕等現象。根據圖3A,使用本發明之實施例的鋼板塗層劣化監測系統所測得之阻抗值之對數值為4.4至4.6,可有效觀察塗層劣化的狀況。 Next, please refer to FIG. 3A. 3A is a diagram showing a Bode diagram obtained by monitoring a steel sheet coating degradation monitoring system according to an embodiment of the present invention, wherein the substrate to be tested used is a damaged substrate to be tested after being cut. In Fig. 3A, line segment 301 represents the logarithmic value of the impedance value, and line segment 303 represents the phase angle. Generally, when monitoring the degree of deterioration of the coating, the impedance value in the low frequency region (below 1 Hz) is mainly evaluated, usually 10 6 Ω as the standard, and when it is lower than 10 6 Ω (the logarithm is 6), the coating is degraded. , damaged or corroded. According to Fig. 3A, the logarithmic value of the impedance value measured by the steel sheet coating deterioration monitoring system using the embodiment of the present invention is 4.4 to 4.6, and the state of deterioration of the coating can be effectively observed.

另一方面,請參照圖3B。圖3B係繪示本發明之比較例之鋼板塗層劣化監測系統進行監測所得之波德圖,其中所使用之待測基材為割開後的破損之待測基材。在圖3B中,線段305代表阻抗值之對數值,線段307代表相位角。導電鋁箔的阻抗值的對數值為4.1至4.3,亦可有效觀察塗層 劣化的狀況。 On the other hand, please refer to FIG. 3B. FIG. 3B is a diagram showing the Bode diagram obtained by monitoring the steel sheet coating degradation monitoring system of the comparative example of the present invention, wherein the substrate to be tested used is a damaged substrate to be tested after cutting. In Figure 3B, line segment 305 represents the logarithmic value of the impedance value and line segment 307 represents the phase angle. The resistance value of the conductive aluminum foil is 4.1 to 4.3, and the coating can be effectively observed. Deteriorating condition.

綜合上述,本發明之實施例可與市售電極具有相同的功效,但本發明之磁吸式電極可長時間浸泡於海水中而不被腐蝕,磁吸式的設置方式使得電極不易從待測基材上脫落,此外,磁吸式電極的另一優點是可輕易變更監測位置,即所製得之磁吸式電極為可攜式電極。 In summary, the embodiments of the present invention can have the same efficacy as commercially available electrodes, but the magnetic electrode of the present invention can be immersed in seawater for a long time without being corroded, and the magnetic arrangement makes the electrode difficult to be tested. The substrate is detached. In addition, another advantage of the magnetic electrode is that the monitoring position can be easily changed, that is, the magnetic electrode produced is a portable electrode.

雖然本發明已以數個實施例揭露如上,然其並非用以限定本發明,在本發明所屬技術領域中任何具有通常知識者,在不脫離本發明之精神和範圍內,當可作各種之更動與潤飾,因此本發明之保護範圍當視後附之申請專利範圍所界定者為準。 While the invention has been described above in terms of several embodiments, it is not intended to limit the scope of the invention, and the invention may be practiced in various embodiments without departing from the spirit and scope of the invention. The scope of protection of the present invention is defined by the scope of the appended claims.

100‧‧‧磁吸式電極 100‧‧‧Magnetic electrode

110‧‧‧L型金屬部件 110‧‧‧L type metal parts

111‧‧‧第一部分 111‧‧‧Part 1

113‧‧‧第二部分 113‧‧‧Part II

113a‧‧‧內表面 113a‧‧‧ inner surface

113b‧‧‧外表面 113b‧‧‧ outer surface

115‧‧‧孔洞 115‧‧‧ holes

120‧‧‧磁石 120‧‧‧ Magnet

130‧‧‧第一導線 130‧‧‧First wire

140‧‧‧包覆材 140‧‧‧Covering material

150‧‧‧黏著層 150‧‧‧Adhesive layer

T‧‧‧厚度 T‧‧‧ thickness

W‧‧‧寬度 W‧‧‧Width

L1‧‧‧第一長度 L 1 ‧‧‧First length

L2‧‧‧第二長度 L 2 ‧‧‧second length

θ‧‧‧夾角 Θ‧‧‧ angle

Claims (9)

一種用於監測鋼板塗層劣化之磁吸式電極,包含:一L型金屬部件,其中該L型金屬部件具有互相連接之一第一部分和一第二部分,該第一部分具有一孔洞,該第二部分具有一內表面以及相對於該內表面之一外表面,且該第一部分與該第二部分之該內表面形成大於45度至小於180度之一夾角;至少一磁石,設置於該第二部分之該內表面上;一第一導線,穿設於該孔洞中,其中該第一導線係與該L型金屬部件電性連接;以及一包覆材,包覆該L型金屬部件之該第一部分、該磁石和部分之該第一導線,且至少露出該第二部分之該外表面。 A magnetic electrode for monitoring degradation of a steel sheet coating, comprising: an L-shaped metal member, wherein the L-shaped metal member has a first portion and a second portion interconnected, the first portion having a hole, the first portion The two portions have an inner surface and an outer surface opposite to the inner surface, and the first portion forms an angle with the inner surface of the second portion that is greater than 45 degrees to less than 180 degrees; at least one magnet is disposed on the first portion a first wire disposed in the hole, wherein the first wire is electrically connected to the L-shaped metal member; and a cladding material covering the L-shaped metal member The first portion, the magnet and the portion of the first wire, and at least the outer surface of the second portion. 如申請專利範圍第1項所述之用於監測鋼板塗層劣化之磁吸式電極,其中該L型金屬部件之材質包含鈦合金、鎳基合金或一不鏽鋼材。 The magnetic electrode for monitoring degradation of a steel sheet coating according to the first aspect of the invention, wherein the material of the L-shaped metal member comprises a titanium alloy, a nickel-based alloy or a stainless steel. 如申請專利範圍第1項所述之用於監測鋼板塗層劣化之磁吸式電極,其中該磁石為一永久磁石。 A magnetic electrode for monitoring deterioration of a steel sheet coating as described in claim 1, wherein the magnet is a permanent magnet. 如申請專利範圍第1項所述之用於監測鋼板塗層劣化之磁吸式電極,其中該包覆材之材質包含聚脲酯、聚氨酯或含氟樹脂。 The magnetic electrode for monitoring degradation of a steel sheet coating according to the first aspect of the invention, wherein the material of the cladding material comprises polyurea ester, polyurethane or fluorine-containing resin. 如申請專利範圍第1項所述之用於監測鋼板塗層劣化之磁吸式電極,其中該磁石與該第二部分間更包含一黏著層,以固定該至少一磁石於該第二部分。 The magnetic electrode for monitoring degradation of a steel sheet coating according to claim 1, wherein the magnet further includes an adhesive layer between the magnet and the second portion to fix the at least one magnet to the second portion. 一種鋼板塗層劣化監測系統,包含:一待測基材,包含一基材層與包覆該基材層的一部份之一塗層,其中該基材層係具磁性之一金屬板材;一磁吸式電極,包含:一L型金屬部件,其中該L型金屬部件具有互相連接之一第一部分和一第二部分,該第一部分具有一孔洞,該第二部分具有一內表面以及相對於該內表面之一外表面,且該第一部分與該第二部分之該內表面形成大於45度至小於180度之一夾角;至少一磁石,設置於該第二部分之該內表面上;一第一導線,穿設於該孔洞中,其中該第一導線係與該L型金屬部件電性連接;以及一包覆材,包覆該L型金屬部件之該第一部分、該磁石和部分之該第一導線,且至少露出該第二部分之該外表面,其中該磁吸式電極係磁吸地設置於該待測基材之該塗層上;一阻抗分析儀;以及一第二導線,其中該第一導線電性連接該磁吸式電極和該阻抗分析 儀,且該第二導線係電性連接未被該塗層包覆之剩餘部分的該基材層與該阻抗分析儀。 A steel plate coating degradation monitoring system comprises: a substrate to be tested, comprising a substrate layer and a coating layer covering a portion of the substrate layer, wherein the substrate layer is magnetic one metal plate; A magnetic electrode comprising: an L-shaped metal member, wherein the L-shaped metal member has a first portion and a second portion interconnected, the first portion having a hole, the second portion having an inner surface and opposite An outer surface of the inner surface, and the first portion and the inner surface of the second portion form an angle of more than 45 degrees to less than 180 degrees; at least one magnet is disposed on the inner surface of the second portion; a first wire disposed in the hole, wherein the first wire is electrically connected to the L-shaped metal member; and a cladding material covering the first portion of the L-shaped metal member, the magnet and the portion The first wire, and at least the outer surface of the second portion is exposed, wherein the magnetic electrode is magnetically disposed on the coating of the substrate to be tested; an impedance analyzer; and a second a wire, wherein the first wire is electrically connected The magnetic electrode and the impedance analysis And the second wire is electrically connected to the substrate layer of the remaining portion not covered by the coating and the impedance analyzer. 如申請專利範圍第6項所述之鋼板塗層劣化監測系統,更包含一第三導線,電性連接該磁吸式電極與該阻抗分析儀,其中該第一導線係連接至該阻抗分析儀之一對電極端,該第二導線係連接至該阻抗分析儀之一工作電極端,且該第三導線係連接至該阻抗分析儀之一參考電極端。 The steel plate coating degradation monitoring system of claim 6, further comprising a third wire electrically connected to the magnetic electrode and the impedance analyzer, wherein the first wire is connected to the impedance analyzer One of the pair of electrode ends is connected to one of the working electrode terminals of the impedance analyzer, and the third wire is connected to one of the reference electrode terminals of the impedance analyzer. 如申請專利範圍第6項所述之鋼板塗層劣化監測系統,其中該磁吸式電極之該外表面磁吸地設置於該待測基材之該塗層上。 The steel sheet coating deterioration monitoring system according to claim 6, wherein the outer surface of the magnetic electrode is magnetically disposed on the coating of the substrate to be tested. 如申請專利範圍第6項所述之鋼板塗層劣化監測系統,其中該阻抗分析儀為一交流阻抗分析儀或一塗層監測儀。 The steel sheet coating degradation monitoring system according to claim 6, wherein the impedance analyzer is an AC impedance analyzer or a coating monitor.
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TWI684758B (en) * 2018-12-14 2020-02-11 財團法人船舶暨海洋產業研發中心 A coating monitoring system of wind turbines and operating method thereof
TWI806876B (en) * 2017-06-20 2023-07-01 美商應用材料股份有限公司 Apparatus for measuring amount of material, semiconductor processing system, and method of determining amount of material

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JP4576220B2 (en) * 2004-12-06 2010-11-04 株式会社竹中工務店 Corrosion detection device and corrosion detection method
JP4745811B2 (en) * 2005-12-14 2011-08-10 太平洋セメント株式会社 Corrosion detection member and corrosion sensor
CN202351159U (en) * 2011-10-26 2012-07-25 中国船舶重工集团公司第七二五研究所 Testing pool device for field monitoring of corrosion resistance of ship body coating

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TWI806876B (en) * 2017-06-20 2023-07-01 美商應用材料股份有限公司 Apparatus for measuring amount of material, semiconductor processing system, and method of determining amount of material
TWI684758B (en) * 2018-12-14 2020-02-11 財團法人船舶暨海洋產業研發中心 A coating monitoring system of wind turbines and operating method thereof

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