WO2015174664A1 - Metal detection module and hiking stick having same - Google Patents

Abstract

The present invention provides a metal detection module comprising: a shield unit (110) having a closed one end and a cup-shaped structure; a probe core (120) standing upright in the center of the shield unit (110) therein; and a bobbin (130) for mounting a coil, which has a coil (140) wound and mounted on the exterior of the probe core (120), wherein the shield unit (110) comprises a tubular shield side part (111) and a shield bottom surface part (112) for sealing a lower end of the shield side part (111), and the probe core (120) comprises a rod-shaped lower core (121) coupled to the shield bottom surface part (112), and a rod-shaped upper core (122) connected to the lower core (121) and formed to have a thickness thinner than that of the lower core (121).

Description

Metal detection module and climbing stick with same

The present invention relates to a metal detection module and a climbing stick having the same, and more particularly, to improve the probe core structure and to adjust the installation position of the coil-mounted bobbin, thereby increasing magnetic flux and magnetic energy to fine metals. The present invention relates to a metal detection module and a climbing stick having the same so that the sensing capability and the sensing distance can be increased.

The applicant has proposed a detection module and a metal detector including the same through Patent Application No. 10-2013-0091303. In the above-described prior invention, the coil is wound around a rod-shaped magnetic core standing up at the shield bottom surface to form a detection module. However, in the structure in which the coil is wound around a rod-shaped magnetic core, there is a limitation in increasing magnetic flux or magnetic energy, which makes it difficult to increase the sensing ability or sensing distance of fine metal such as gold dust.

In addition, Japanese Patent Laid-Open No. 6-109861 discloses a structure in which a central shaft portion protrudes in a rod shape in a cylindrical portion, which also causes the same problem as the above-described invention.

Therefore, it is required to develop a structure of a metal detection module that can increase the sensing capability or sensing distance of fine metal through structural improvement.

The present invention improves the probe core structure and adjusts the installation position of the coil-mounted bobbin, thereby increasing the magnetic flux and magnetic energy to increase the sensing capability and sensing distance for the fine metal, and the same. It is to provide a climbing stick having.

An object of the present invention is a shield 110 of the cup-shaped structure is blocked one end; A probe core 120 standing upright in the center of the shield 110; And a coil mounting bobbin 130 on which the coil 140 is wound and mounted on the outside of the probe core 120, wherein the shielding part 110 is a tubular shielding side part 111 and the shielding side part ( And a shielding bottom surface 112 for sealing a lower end of the 111, and the probe core 120 extends to the lower core 121 and the lower core 121 formed by being coupled to the shielding bottom surface 112. It includes an upper core 122 is formed, at least a portion of the lower core 121 is achieved by a metal detection module, characterized in that it has a rod shape of increased thickness compared to the upper core 122.

The coil mounting bobbin 130 is mounted to the periphery of the probe core 120 by mounting a coil 140 on a cylindrical outer circumferential surface, and a partial region is disposed in the upper core 122 region of the probe core 120. The remaining area may be disposed in an area of the lower core 121 of the probe core 120 to form a space A.

An inner space of the shield 110 may further include a waterproof material filling layer 150 filled with a waterproof material.

The upper core 122 may further protrude beyond an upper end of the shield 110.

The metal detection module further includes a magnetic flux increasing coupling member 160 coupled to one end of the shield to increase magnetic flux, and the magnetic flux increasing coupling member 160 includes flanges 161 and 162 at both ends. The coil 140 may be wound around the body 162 connecting the flange part.

The metal detecting module may further include a cylindrical sensitivity adjusting member which is coupled to an outer surface of the case and moves forward and backward when the shield is accommodated in the case and adjusts the sensitivity of the probe core.

The probe core 120 may further include a magnetic distortion groove that is a hole penetrating the probe core 120.

In another aspect, the present invention is a climbing stick that is detachably coupled to the module assembly coupled to the metal detection module, the metal detection module, the shield portion 110 of the cup-shaped structure is blocked one end; A probe core 120 standing upright in the center of the shield 110; And a coil mounting bobbin 130 on which the coil 140 is wound and mounted on the outside of the probe core 120, wherein the shielding part 110 is a tubular shielding side part 111 and the shielding side part ( 111 is provided with a shielding bottom surface 112 for sealing the lower end, the probe core 120 is a rod-shaped lower core 121 and the lower core 121 is coupled to the shielding bottom surface 112 Climbing stick is provided, characterized in that it comprises a rod-shaped upper core 122 is formed to a thickness thinner than the lower core 121.

The module assembly may be provided with a module protective cover for preventing wear of the upper core 122 of the metal detection module.

The climbing stick may be provided with an on-off switch for operating the metal detection module.

According to the present invention, by improving the probe core structure and adjusting the installation position of the coil-mounted bobbin, there is an effect that the magnetic flux and magnetic energy can be increased to increase the sensing ability and sensing distance for the fine metal.

1 is a perspective view of a metal detection module according to an embodiment of the present invention,

FIG. 2 is a half sectional perspective view of FIG. 1;

3 is a cross-sectional view of FIG.

4 is a cross-sectional view of a metal detection module according to a second embodiment of the present invention;

5 is a cross-sectional view of a metal detection module according to a third embodiment of the present invention;

6 is a perspective view of a metal detection module according to a fourth embodiment of the present invention;

7 is a cross-sectional view of a metal detection module according to a fifth embodiment of the present invention;

8 is a view showing a hiking stick to which a metal detection module is applied according to an embodiment of the present invention.

FIG. 9 is a block diagram illustrating a configuration of detecting a metal in the climbing stick of FIG. 8.

<Description of the code>

100: metal detection module 110: shield

120: probe core 121: lower core

122: upper core 130: bobbin

140: coil 150: waterproof material filling layer

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

First, Figure 1 is a perspective view of a metal detection module according to an embodiment of the present invention, Figure 2 is a half sectional perspective view of Figure 1, Figure 3 is a cross-sectional view of FIG.

As shown in these figures, the metal detection module 100 according to an embodiment of the present invention is a probe core 120, a probe core (120) which is installed in the center of the shield 110 and the shield 110, The coil 140 includes a coil mounting bobbin 130 wound around the outside of the coil 140.

First, the shield 110 is made of a ferromagnetic material such as ferrite and has a cup-like structure with one end blocked. Accordingly, the shield 110 includes a shielding side surface portion 111 having a tubular shape and a shielding bottom surface portion 112 sealing the lower end of the shielding side surface portion 111. Since the shield 110 is provided, magnetic flux generated by the coil mounted therein may flow through the shield 110 and the probe core 120 therein to be provided to the metal detector in front of the metal detector module 100. Can be made and there is little leakage behind. In addition, it may be possible to selectively form a plurality of cutout grooves (not shown) in the shielding side portion 111 for the purpose of increasing the magnetic flux.

The probe core 120 is formed of a ferromagnetic material, such as ferrite, and is erected at an inner center of the shield 110, like the shield 110, and has a rod-shaped lower core 121 coupled to the shield bottom surface 112. And an upper core 122 connected to the lower core 121 and having a thinner thickness than the lower core 121, which also has a rod shape.

At least a portion of the lower core 121 has a rod shape having a thickness increased compared to that of the upper core 122, thereby increasing the cross-sectional area through which magnetic force lines can flow, thereby being generated by a coil mounted to the outside of the lower core 121. The magnetic flux can be increased.

Increasing the magnetic flux as a result of increasing the magnetic field, the effect of increasing the length of the upper core 122 is connected to the lower core 121 by the increase of the magnetic field. As the length of the upper core 122 is increased as described above, the upper core 122 may protrude longer than the upper portion of the shielding side portion 111, so that the detection radius is widened by the protruding upper core 122. By using the object to which the metal detection module according to the present invention is applied to the back, it is possible to increase the likelihood that the metal is detected.

The coil mounting bobbin 130 is installed around the probe core 120 by mounting the coil 140 on a cylindrical outer circumferential surface, and some areas are disposed in the area of the upper core 122 of the probe core 120, and the remaining areas. Is disposed in the region of the lower core 121 of the probe core 120. At this time, the coil 140 may be connected to the oscillation circuit. The oscillation circuit is configured to stop oscillation when the coil oscillates at a predetermined impedance time and the impedance is shifted beyond a predetermined impedance, that is, when there is no metal in the vicinity of the probe core 120 to which the coil is mounted, oscillation is performed. This circuit is set to be. Therefore, when the change in the oscillation state of the oscillation circuit is configured to output as an alarm sound, the metal detection module according to the present invention can be provided to the metal detection.

A portion of the bobbin 130 on which the coil 140 is mounted is disposed in the region of the upper core 122 of the probe core 120, thereby providing a gap between the bobbin 130 on which the coil 140 is mounted and the upper core 122. The spacing space A shown in FIG. 3 is created. This is because the thickness of the upper core 122 is formed relatively thin compared to the lower core 121, the diameter between the coil mounting bobbin 130 is formed to a diameter that can be inserted around the lower core 121 This is because of the difference.

The space A is interpreted to cause a kind of magnetic resonance resonance to increase the magnetic energy of the probe core 120 to increase the sensing ability of the probe core 120. That is, the lower core 121 of the probe core 120 has a relatively thicker thickness than the upper core 122, so that the cross-sectional area is increased, thereby increasing the number of magnetic force lines passing through the lower core 121, thereby increasing the magnetic flux. Since the magnetic flux is also generated in the inner region of the coil 140 wound around the bobbin 130, the magnetic flux flowing through the probe core 120 by resonating these two kinds of magnetic fluxes together in the space A. It is interpreted that by increasing the magnitude of energy, the ability to detect fine metals can be increased. Here, the coil mounting bobbin 130 may further have a coercive force.

Therefore, according to an embodiment of the present invention, the thickness of the lower core 121 is relatively thicker than that of the upper core 122, thereby increasing the length of the upper core 122 so that the probe core 120 may be advantageous for the probe role. Further, by resonating the magnetic flux generated by the spacing space A of the bobbin 130 and the upper core 122 wound around the coil 140 to enhance the magnetic energy of the probe core 120, the probe core The detection capability of 120 can be improved.

In addition, after the above components are installed, the inner space of the shield 110 is further formed with a waterproof material filling layer 150 filled with a waterproof material. Since the metal detection module according to the present invention can be used in water, such as a river or the beach, it is preferable that the coil 140 is provided to protect it from being exposed to the outside.

4 illustrates a metal detection module according to a second embodiment of the present invention, wherein the upper core 122 is installed in parallel with the upper end of the shield 110 without protruding beyond the upper end of the shield 110. The remaining components are the same as in the above-described embodiment.

5 illustrates a metal detection module according to a third embodiment of the present invention, and may further include a magnetic flux increasing coupling member 160 coupled to the lower end of the shield 110. The magnetic flux increasing coupling member 160 is formed of a ferromagnetic material such as ferrite, similar to the shield 110 and the probe core 120, and includes flange portions 161 and 162 at both ends, and flange portions 161 and 162 at both ends. Coil 140 is wound around the body 162 for connecting. The wound coil 140 is connected to the coil mounting bobbin 130 mounted on the probe core 120 through the shielding bottom surface 112. As the magnetic flux increasing coupling member 160 is further coupled as described above, it may be effective to increase the magnetic flux as necessary.

6 illustrates a metal detection module according to a fourth embodiment of the present invention. When the metal detection module 100 according to the first embodiment is accommodated and used inside the case C, the case C The outer surface, that is, the screw portion (S) is formed on a portion of the case (C) corresponding to the portion in which the metal detection module 100 is accommodated, the cylindrical sensitivity adjustment member 170 is also formed with a screw (not shown) inside ) May be further provided. Therefore, the sensitivity control member 170 is moved forward and backward along the screw portion (S) to attract the influence of the external magnetic field, it is possible to adjust the detection capability of the metal detection module (100). For example, when the sensitivity adjusting member 170 is moved forward to completely surround the screw portion S so that the screw portion S is not exposed to the outside, the sensing capability of the metal detecting module 100 is increased, and the sensitivity adjusting member 170 is increased. ) Is reversely moved so that the screw portion (S) is exposed to the outside, so that the sensing ability is reduced, even if the metal detection module 100 is accommodated in a protective member such as the case (C), the sensitivity control member 170 By adjusting), it is possible to adjust and adjust the detection ability that varies depending on the usage conditions, such as the use of external temperature, location, or seawater. At this time, the sensitivity adjusting member 170 is preferably formed of the same material.

7 illustrates a metal detection module according to a fifth embodiment of the present invention, in which modified embodiments of the detection core 120 are shown. FIG. 7A illustrates that the end shape of the upper core 122 may be formed in a straight line rather than a sharply tapered shape. Although not shown, the shape of the upper core 122 may be variously changed.

In addition, FIG. 7B illustrates that the magnetic distortion groove 120a may be penetrated inside the center of the probe core 120. The magnetic distortion groove 120a is interpreted to be able to widen the range of the region where the strength of the magnetic field is large due to the distortion of the magnetic field around the upper end of the probe core 120.

8 is a view showing a hiking stick to which a metal detection module is applied according to an embodiment of the present invention.

The module assembly 2 may be screwed to the lower end of the climbing stick 1, so that the module assembly 2 having the metal detection module is attached to the climbing stick 1, if necessary. Therefore, if metal detection is required during mountain climbing or leisure activities, the metal assembly can be carried out simply and easily by removing the bottom assembly of the climbing stick and using the combined module assembly (2).

In addition, the module assembly 2 accommodates the metal detection module 100, the lower end may be further provided with a module protective cover 10 to prevent wear of the metal detection module (100). In addition, a sensitivity control member 170 may be further provided inside the module protective cover 10 to control the sensitivity of the metal detection module 100. Therefore, the module protection cover 10 to be screwed away from the module assembly 2, and then forward and backward the sensitivity control member 170, the sensitivity of the metal detection module 100 can be adjusted to facilitate the use and also protect the module The cover 10 is screwed onto the module assembly 2 so that it can be replaced when worn. Module protective cover 10 is preferably formed of a plastic material that does not affect the detection capability of the metal detection module (100).

In addition, the upper handle portion of the climbing stick is provided with an on-off switch 500 may be turned on or off at the start or end of metal detection after the mounting of the module assembly (2).

The climbing stick 1 to which the metal detection module 100 is applied may include a component for metal detection together with the metal detection module 100, which will be described with reference to the block diagram of FIG. 9.

First, the on-off switch 500 is turned on while the module assembly 2 is mounted on the climbing stick 1. Then, the detection controller 200 detects this and causes the coil 140 wound on the metal detection module 100 to be oscillated through the oscillator 300. When there is metal close to the metal detection module 100, oscillation of the oscillator 300 is stopped by abnormal impedance, and when oscillation of the oscillator 300 is stopped, the detection controller 200 detects this and outputs the output unit 400. By causing an alarm to sound through, the metal can be detected. A power supply unit 600 for supplying power to each component is further provided, and each component is preferably miniaturized and embedded in the climbing stick 1.

As described above, if the metal detection module according to the present invention is applied to a stick for climbing, the metal detection module may be activated when necessary during mountain climbing or leisure activities to detect metal, so that a new leisure life may be enjoyed.

As described above, by improving the probe core structure and adjusting the installation position of the coil-mounted bobbin, the magnetic flux and magnetic energy can be increased to increase the sensing ability and the sensing distance of the fine metal.

 As described above, the present invention is not limited to the described embodiments, and various modifications and changes can be made without departing from the spirit and scope of the present invention, which will be apparent to those skilled in the art. Therefore, such modifications or variations will have to be belong to the claims of the present invention.

Claims (10)

1. A shield 110 having a cup-shaped structure with one end blocked;

   A probe core 120 standing upright in the center of the shield 110; And

   It includes a coil mounting bobbin 130, the coil 140 is wound and mounted on the outside of the probe core 120,

   The shielding unit 110 has a shielding side surface portion 111 of the tubular shape and a shielding bottom surface portion 112 for sealing the lower end of the shielding side surface portion 111,

   The probe core 120 includes a lower core 121 coupled to the shielding bottom portion 112 and an upper core 122 extending to the lower core 121, and the lower core 121. At least a portion of the metal detection module, characterized in that it has a rod shape of increased thickness compared to the upper core (122).
2. The method of claim 1,

   The coil mounting bobbin 130 is mounted to the periphery of the probe core 120 by mounting a coil 140 on a cylindrical outer circumferential surface, and a partial region is disposed in the upper core 122 region of the probe core 120. The remaining area is disposed in the lower core 121 region of the probe core 120 to form a space A spaced apart from the metal detection module.
3. The method of claim 1,

   Metal detection module, characterized in that the waterproofing material filling layer 150 is further formed in the inner space of the shielding portion 110 is filled with a waterproofing material.
4. The method of claim 1,

   The upper core 122 is a metal detection module, characterized in that further protrude beyond the top of the shield (110).
5. The method of claim 1,

   The metal detection module further includes a magnetic flux increasing coupling member 160 coupled to one end of the shield to increase magnetic flux.

   The magnetic flux increasing coupling member 160 has flanges 161 and 162 at both ends, and a coil 140 is wound around the body 162 connecting the flanges.
6. The method of claim 1,

   The metal detecting module further includes a cylindrical sensitivity adjusting member which is coupled to an outer surface of the case and moves forward and backward when the shield is accommodated in the case, and adjusts the sensitivity of the probe core. .
7. The method of claim 1,

   The metal detection module, characterized in that the probe core 120 is further formed with a magnetic distortion groove which is a hole passing through the probe core (120).
8. A climbing stick to which the module assembly coupled with the metal detection module is detachably coupled.

   The metal detection module,

   A shield 110 having a cup-shaped structure with one end blocked;

   A probe core 120 standing upright in the center of the shield 110; And

   It includes a coil mounting bobbin 130, the coil 140 is wound and mounted on the outside of the probe core 120,

   The shielding unit 110 has a shielding side surface portion 111 of the tubular shape and a shielding bottom surface portion 112 for sealing the lower end of the shielding side surface portion 111,

   The probe core 120 has a rod-shaped lower core 121 coupled to the shielding bottom surface 112 and a rod-shaped lower thickness 121 than the lower core 121 and connected to the lower core 121. Climbing stick, characterized in that it comprises an upper core (122).
9. The method of claim 8,

   The module assembly is a climbing stick, characterized in that the module protection cover is provided to prevent wear of the upper core (122) of the metal detection module.
10. The method of claim 8,

    The stick for climbing, characterized in that the on-off switch for operating the metal detection module is provided.

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