JP2002120919A - Conveyor belt using stainless steel detectable by metal detector and belt conveyor device combined with these conveyor belt and metal detector - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a conveyor belt and a belt conveyor device capable of detecting metal on a stainless steel broken piece mixed in a carrying object and brought about from a conveyor and composed of stainless steel having a high magnetic rate. SOLUTION: This conveyor belt is composed of the stainless steel having pitting corrosion generating electric potential in accordance with JIS G0577, 3.5% NaClaqAr deaeration of 30 deg.C, a scanning speed not less than 160 mV in 20 mV/min, magnetic permeability not less than 100 μ-1 and magnetism detectable by a metal detector, and the belt conveyor device is combined with these conveyor belt and metal detector.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention makes it possible to easily detect fragments by passing through a metal detector when a part of the belt is damaged for some reason and fragments or the like are mixed as foreign matter into a conveyed object. The present invention relates to a belt conveyor device combining a belt conveyor and a metal detector.

[0002]

2. Description of the Related Art Belt conveyors are used in various fields including the industrial field, and are also widely used in the field of transport and processing of food and sanitary goods. The belt of the belt conveyor includes a combination of metal parts and synthetic resin parts, a belt woven by a synthetic resin monofilament, and a resin-coated belt. In the transportation and processing of food, a metal belt that withstands high temperatures and has a large opening and strength has been suitably used because it may run in a high-temperature atmosphere and sometimes cool or dry foods and the like. . However, conveyor belts made of iron or some stainless steels have a problem of rusting. Therefore, as a rust preventive measure, austenitic stainless steel which is hard to corrode, especially SUS304 or SUS31 is used.
6 etc. have been widely used. However, although these stainless steels have excellent corrosion resistance, they have a drawback that they are hardly detected by a metal detector because they have almost no magnetism. Metal detectors are devices that detect metallic foreign substances in the conveyed objects while they are being conveyed.In recent years, metal detectors are frequently used in places where safety and hygiene are important such as food, sanitary goods, and processed materials. It has become However, the metal detector has a drawback that it is easy to detect a magnetic metal such as iron, but it is difficult to detect a metal having almost no magnetism such as stainless steel. In other words, if fragments of the conveyor belt, etc. are mixed into the conveyed object as foreign matter, non-magnetic stainless steel is difficult to detect with a metal detector, and is conveyed as it is with the conveyed object, causing a serious problem. was there.

[0003]

The conveyor belt according to the present invention is used for conveying and processing products in which safety and hygiene are emphasized. The use of a metal detector makes it easy to remove the belt fragments mixed in the conveyed object. The present invention is to provide a conveyor belt which can detect rust in a long time, and is extremely free of rust even in long-term use.

[0004]

Means for Solving the Problems The present invention provides: "1. The pitting corrosion potential is not less than 160 mV at a scanning speed of 20 mV / min at a scanning speed of 20 mV / min according to JIS G0577: 3.5% NaClaqAr deaeration 30 ° C A conveyor belt made of stainless steel having a magnetic susceptibility of 100 μ ⁻¹ or more and having magnetism that can be detected by a metal detector 2. The weight of the stainless steel constituting the conveyor belt is% by weight
Contains 2.5 to 8% of Ni, 18 to 30% of Cr, 3.5% or less of Mo, 0 to 0.2% of N, and Cu, T
A stainless steel which is a duplex stainless steel having a magnetic permeability of 100 μ ⁻¹ or more containing 1 or 2 or more selected from i and Nb in total of 0 to 1%, which can be detected by the metal detector described in 1 above. Conveyor belt composed by. 3. The weight of the stainless steel constituting the conveyor belt is% by weight.
Where Cr is 17% or more, Mo is 0 to 3%, and C ≦ 0.02.
%, N ≦ 0.02% and C + N ≦ 0.05%, and contains C and N, and optionally contains 1 or 2 or more selected from Cu, Ti and Nb in a total of 0 to 1% Is a ferritic stainless steel having a magnetic permeability of 100 μ ⁻¹ or more.
A conveyor belt made of stainless steel that can be detected by the metal detector according to claim 1. 4. A belt conveyor device comprising a metal detector disposed behind a belt conveyor configured by the conveyor belt according to any one of Items 1 to 3. About.

[0005]

DESCRIPTION OF THE PREFERRED EMBODIMENTS Particularly in the processing of foods and the production of nonwoven fabrics used for sanitary goods, a belt conveyor not only transports products but also cools and dries them. In other applications, the vehicle may travel in severe temperature conditions such as a high or low temperature atmosphere. A conveyor belt used for such an application is preferably a metal belt that withstands high temperatures and has a large opening suitable for cooling and drying, and a stainless steel having corrosion resistance is used as a material of the conveyor belt. However, although this stainless steel is excellent in corrosion resistance, it has a drawback that it is difficult to be detected by a metal detector. That is, if broken pieces of conveyor belt are mixed into a conveyed object due to any cause, the belt debris is conveyed as it is with the conveyed object, which may cause a serious problem. Therefore, the present inventor has configured a conveyor belt with a material that is easily detected by a metal detector, installed a metal detector behind the belt conveyor using the belt, and combined the belt conveyor and the metal detector with a belt conveyor device. By using, we succeeded in preventing metal foreign matter from being mixed. Of course, the conveyor belt must be a material excellent in corrosion resistance, stress resistance, workability, etc., in addition to being easily detected by the metal detector, but the conveyor belt of the present invention is as described above. It is made of special stainless steel which has excellent suitability for conveyor belts.

[0006] The conveyor belt of the present invention is formed of stainless steel that satisfies both corrosion resistance and properties detected by a metal detector. Pitting corrosion potential is JIS G057
According to 7: 3.5% NaClaqAr deaeration at 30 ° C. At a scanning speed of 20 mV / min and below 160 mV, the corrosion resistance is lower than SUS 304, which is widely used as a rust preventive measure, and rust occurs during use. In some cases, damage occurs. If the magnetic permeability is 100 μ ⁻¹ or less, small fragments and the like are hard to be detected by the metal detector. In the magnetic material, the permeability μ = the ratio of the magnetic induction B to the magnetic field strength H =
B / H, which has a relationship of μ = 1 + 4πκ with the magnetic susceptibility κ. If the strength of the magnetic field is constant, the higher the magnetic permeability, that is, the more easily magnetic induction occurs, the more the magnetic field changes, and the metal detector detects the change in the magnetic field to detect the inclusion of foreign metal. Can be. Since the metal detector has a constant magnetic field generation condition during use, a substance having a higher magnetic induction is easier to detect. In the present invention, the stainless steel constituting the conveyor belt is roughly classified into two types, a duplex stainless steel and a ferritic stainless steel.

[0007] Duplex stainless steel is mainly composed of Cr, Ni, Mo.
And contains Mo and a lot of Cr, so that it has excellent corrosion resistance against pitting corrosion and local corrosion such as crevice corrosion. In particular, the pitting potential is used as an index of the susceptibility to corrosion, and S, which has been often used in the past, has been used.
US304 is 160 mV, but the duplex stainless steel used for the belt of the present invention has a pitting potential of 600 mV.
(According to JIS G0577: 3.5% NaClaq
Ar deaeration 30 ° C. traveling speed 20 mV / min) or more, for example, 630 mV, and the pitting potential is much higher than ferritic stainless steel such as SUS430. Since the higher the pitting potential, the higher the corrosion resistance, the stainless steel used in the present invention has excellent corrosion resistance. Since the duplex stainless steel used for the belt of the present invention is very excellent in corrosion resistance,
Suitable for use in corrosive environments. The magnetic permeability is 160 μ ⁻¹ and can be detected by a metal detector. The other ferritic stainless steel has a pitting corrosion potential of 160 mV or more (according to JIS G0577: 3.5% NaClaqAr deaeration 30 ° C.
0 mV / min), and the composition is very low in the contents of C and N as compared with ordinary ferritic stainless steel. For example, the C content of SUS430 of ferritic stainless steel is about 0.12% or less, and rust occurs in a short time when used in an environment where seawater, salt, or the like is easily corroded. However, the C content of the stainless steel constituting the conveyor belt of the present invention is 0.02% or less. By reducing the contents of C and N in this way, corrosion resistance, weldability, and workability are improved. The permeability is 365μ.
^-1 and can be detected by a metal detector.

[0008] The conveyor belt of the present invention made of such stainless steel has high magnetism, and has a feature that even if the belt fragments are mixed in the conveyed object, it can be detected by a metal detector. In addition, in the transportation of foods and the like, there is a problem in that a metal detector has a large noise in a transported object having a high salt concentration, making it difficult to detect a metal. The duplex stainless steel and ferritic stainless steel used for the belt of the present invention have corrosion resistance of SUS 304 or more to salt and have a permeability several tens of times that of SUS 304, so that they can be used in food production lines. Is very effective. Most austenitic stainless steels that have been used in the past and have excellent corrosion resistance have no magnetism. On the other hand, the magnetic permeability of the stainless steel used for the conveyor belt of the present invention is as high as 350 or more assuming that the austenitic stainless steel is 1, indicating that the stainless steel has much higher magnetism. There is an advantage that such a highly magnetic metal is easily detected by a metal detector. Therefore, if fragments of the conveyor belt that have been damaged for some reason during transportation of the conveyed material are mixed into the conveyed material as foreign matter, it is difficult to detect with stainless steel, which has almost no magnetism, with a metal detector However, if the stainless steel has high magnetism such as the stainless steel used in the present invention, even small fragments can be sufficiently detected. Further, the stainless steel having high magnetism described in this specification means a stainless steel having higher magnetism than SUS 304 and 316.

A well-known high magnetic stainless steel is a ferritic stainless steel.
US430 and the like are also high magnetic stainless steels. However, this has a defect that corrosion resistance is poor compared with austenitic stainless steel and rust occurs in a short time. Further, it had a drawback that elongation was lower than that of austenitic stainless steel. Although high Cr ferritic stainless steel with excellent corrosion resistance and high magnetism is also provided in some parts, the content of C and N is low, as in the special ferritic stainless steel used for the conveyor belt material of the present invention. The fact is that it is difficult to process because it is not a small amount, and it is hardly practically used because of the high manufacturing cost. The ferritic stainless steel used in the present invention has a very low content of C and N unlike conventional ferritic stainless steels, so it has good workability and can be easily processed into a linear material often used as a material for forming a conveyor belt. Can be done. Another major feature is that since it is ferrite, its magnetic permeability is very high.

The belt may be formed into a net formed by processing the stainless steel into a linear body and weaving the stainless steel into warp and weft threads. The linear body may also be a single wire or a stranded wire. . Also, a linear body is processed into a spiral shape and combined, a spiral wire rod and a rod are combined, a U-shaped plate is connected with a rod, a single wire is bent and There is no limitation, for example, a combination or a rod having both ends connected to form an endless rod. In addition, the conveyor belt may be formed by processing the stainless steel material of the present invention as a conveyor belt constituent material and combining them sequentially. In particular, an endless belt using a spiral coil is effective because it has a structure capable of driving a sprocket and not requiring a large-scale driving device. As the spiral coil, a coil having a flat cross section, an elliptical coil, or the like can be used in addition to a coil having a circular cross section. Of course, it is also possible to run the belt by hanging it between two rolls and applying tension to rotate the rolls, and other driving methods may be used.

Further, the stainless steel of the present invention may be used for other components of the belt conveyor device, for example, screws and the like that may be separated from the device by vibration and mixed into a conveyed material. Absent. A metal detector for detecting metal foreign matter such as a conveyor belt fragment is installed behind the belt conveyor of the present invention, and detects metal foreign matter mixed in a conveyed object. In order to check for the presence of foreign metal, it is easy to pass a conveyed object from a belt conveyor through a metal detector. Usually, a metal detector is composed of a detection head and a belt conveyor.The detection head detects magnetism, and the belt conveyor carries conveyed objects to the detection head in order to detect metal objects efficiently. is there. Any metal detector may be used as long as it can detect a change in magnetism and magnetic field to detect a metallic foreign substance. In addition, the belt of the metal detector belt conveyor is usually a belt coated with resin, a belt combining parts molded with synthetic resin, a belt woven with synthetic resin yarn, a belt with many small-diameter rolls, etc. A belt made of a material that is hardly damaged without magnetism is used, and such a metal detector can detect a magnetic metal such as iron or nickel, and detects the magnetism that constitutes the conveyor belt of the present invention. It can also detect stainless steel belt fragments and the like.

[0012]

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a block diagram showing an embodiment of the present invention. FIG. 1 is a diagram showing an embodiment of the present invention. FIG. 1 shows a belt conveyor constituted by using the conveyor belt of the present invention. A metal detector shown in FIG. 2 is installed behind the belt conveyor to form a series of belt conveyor devices. FIG. 3 is a front view of the conveyor belt of the present invention. 1
Is a belt conveyor that can be driven by a sprocket.
Is a spiral belt formed by combining stainless steel having magnetism. The conveyor belt 2 is rotated by sprockets 4, and the conveyed article 3 is conveyed by running the belt. Thereafter, an inspection is performed using the metal detector 5 shown in FIG. 2 to determine whether or not metal contaminants such as conveyor belt fragments are mixed in the conveyed object. The metal detector 5 is composed of a conveyor belt obtained by applying a resin coating to a woven fabric woven by synthetic resin yarns and a detection head 7 and has been conveyed from the conveyor belt 1 in FIG. The metal foreign matter is detected by receiving the transported object 3 and passing the object 3 through the detection head. Conveyed object 3
In the case where the belt fragments 8 damaged due to the deterioration of the belt or the like are mixed in, the detection head 7 detects the broken pieces and removes the foreign matter or removes the product.

FIG. 3 is a front view of the conveyor belt used in FIG. A stainless steel having corrosion resistance and high magnetic permeability was worked into a spiral shape, and a connecting rod 10 was inserted into a common hole formed by engaging two spirals 9 to form an endless spiral belt. This belt has a feature that it can be driven by a sprocket, and has advantages such as simplification of the device. Next, a comparative test was performed on the stainless steel of the present invention and the conventional stainless steel for corrosion resistance and ease of detection with a metal detector. The stainless steels used were Example 1, which is a duplex stainless steel, Example 2, which is a ferritic stainless steel, Comparative Example 1, which used SUS304, and Comparative Example 2, which used SUS430. Is shown in Table 1. Also,
Table 2 shows the pitting potential and the evaluation for the results of Comparative Test 1.
Table 3 shows the magnetic permeability, and Table 4 shows the results of the comparative test.

[0014]

[Table 1]

[0015]

[Table 2]

[Evaluation method] Excellent corrosion resistance ◎> ○ ＞ △ ＞ ×
Poor corrosion resistance is not practical.

[0017]

[Table 3]

[Evaluation method] Stainless steel piece detection excellent ◎>
○> ×× cannot be put to practical use.

Comparative test Corrosion resistance test Each stainless steel was made into a belt as shown in FIG. A wire having a wire diameter of 1.2 mm was processed into a spiral spiral, and a spiral rod was formed by combining the linear rod and the spiral. This was made into a square having a side of 10 cm, the ends were waterproofed, and a salt spray test (spraying with a 5% aqueous sodium chloride solution at 35 ° C.) for 1000 hours was performed, and the rusting conditions after that were compared. (Results and Discussion) Rust generation was observed in the order of Comparative Example 2, Comparative Example 1, Example 2, and Example 1 in the order of decreasing pitting potential. In addition, the rusting points tend to be near the spiral bent portion and the contact point of the bent portion. In Comparative Example 2, rusting started near the contact point immediately after the test started,
At the end of the test, the whole was discolored due to rust. on the other hand,
Even under the same conditions, no rust was generated in this example, particularly in Example 1, indicating that the corrosion resistance was very excellent. 2. Magnetic test A comparative test was performed assuming that the conveyor belt was damaged and mixed into the nonwoven fabric. Each linear stainless steel having a wire diameter of 1.2 mm was cut into 2 mm and 4 mm, mixed into a 10 cm square nonwoven fabric, and compared by the number of times that each metal detector could be detected 100 times. Since the detection accuracy varies with the detection sensitivity of the detection head of the metal detector and the speed, temperature, humidity, etc. of the conveyor belt, a SUS of 4 mm in length
The number of detections of 304 was set to such an extent that it could be detected about 25 times out of 100 times. (Results and discussion)

[0020]

[Table 4]

The higher the magnetic permeability, the easier it is for the metal detector to detect it. However, Example 2 has the same degree of magnetism as Comparative Example 2 having high magnetism. In No. 2, all the foreign substances mixed in could be detected. In rare cases, it may not be detected depending on the direction in which the metal fragments are placed, but it has been found that the effect is superior to that of a conventional non-magnetic metal such as SUS304. As a countermeasure for completely detecting the metal foreign matter, it is possible to increase the sensitivity of the metal detector or to decrease the traveling speed of the conveyor belt of the metal detector. In particular, if the environment is not easily corroded, the conveyor belt formed of the stainless steel of Example 2 is effective.

[0022]

According to the present invention, a conveyor belt made of stainless steel having high corrosion resistance and high magnetism has an effect of hardly rusting even when used in an environment where salt water or the like is apt to rust. By combining a belt conveyor with a belt and a metal detector, even if a part of the belt is damaged for some reason and belt fragments etc. are mixed into the conveyed material as foreign matter, it can be passed through the metal detector. An excellent effect of easily detecting belt fragments and the like is achieved.

[Brief description of the drawings]

FIG. 1 is a sectional view of a belt conveyor device in which a belt conveyor of the present invention and a metal detector are combined.

FIG. 2 is an explanatory diagram of a metal detector.

FIG. 3 is a part of a spiral belt which is the conveyor belt of the present invention.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Belt conveyor 2 Conveyor belt 3 Conveyed object 4 Sprocket 5 Metal detector 6 Conveying belt 7 Detection head 8 Belt fragments 9 Spiral 10 Connecting rod

──────────────────────────────────────────────────続 き Continued on the front page (51) Int.Cl. ⁷ Identification symbol FI Theme coat ゛ (Reference) C22C 38/48 C22C 38/48 (72) Inventor Takehiko Tatsuno 2220 Daimaru, Inagi-shi, Tokyo Nippon Filcon Co., Ltd. Tokyo office F term (reference) 3F024 AA00 CA02 EA03 4G068 AA01 AA07 AB21 AC01 AC02 AD29 AF25 AF40

Claims (4)

[Claims] 1. A pitting corrosion potential according to JIS G0577: 3.5% NaClaqAr deaeration 30 ° C. Scanning speed 20 mV / min, 160 mV or more at a scanning speed, and a magnetic permeability of 100 μ ⁻¹ or more, A conveyor belt made of stainless steel having magnetism that can be detected by a detector. 2. The stainless steel constituting the conveyor belt is 2.5% to 8% by weight of Ni and 18 to 30% by weight of Cr.
%, 3.5% of Mo or less, N and containing 0 to 0.2%, and Cu, Ti, permeability 100 microns ^-1 or more, containing 0 to 1% in total of one or more chosen from Nb A conveyor belt made of stainless steel that can be detected by the metal detector according to claim 1, which is a duplex stainless steel. 3. The stainless steel constituting the conveyor belt is in weight%, Cr is 17% or more, Mo is 0 to 3%, C ≦ C.
0.02%, N ≦ 0.02% and C + N ≦ 0.05
% Containing C and N satisfying the formula of
A stainless steel which can be detected by the metal detector according to claim 1, wherein the stainless steel is a ferrite stainless steel having a magnetic permeability of 100 μ ⁻¹ or more containing 1 or 2 or more selected from i and Nb in total of 0 to 1%. Conveyor belt composed of steel. 4. A belt conveyor device comprising a metal detector arranged behind a belt conveyor constituted by the conveyor belt according to claim 1.