JP2014232842A - Electromagnetic shield member, electromagnetic shield and electromagnetic shield method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an electromagnetic shield member that shields an electromagnetic wave of predetermined frequency, an electromagnetic shield that is composed of the electromagnetic shield member and shields an electromagnetic wave of predetermined frequency according to an object to be shielded, and an electromagnetic shield method.SOLUTION: Recessed and projecting parts 110, which fragmentize eddy current Ec generated by the incidence of an electromagnetic wave Ew, are formed on a conductive plate Pc, thus configuring an electromagnetic shield plate 100. Additionally, the recessed and projecting parts 110 are formed according to the predetermined frequency of an electromagnetic wave to be shielded.

Description

  The present invention relates to, for example, an electromagnetic shield that is disposed so as to cover a shield object that shields electromagnetic waves, an electromagnetic shield member that constitutes the electromagnetic shield, and an electromagnetic shield method.

  With diversification and versatility, electronic devices have increased in output, and the influence of generated electromagnetic waves on peripheral devices has increased. On the other hand, with the increase in accuracy of electronic devices, there is an increased risk of malfunction due to irradiated electromagnetic waves. Under such circumstances, there is an increasing need for an electromagnetic shield that irradiates or shields an electromagnetic wave that is irradiated, and various electromagnetic shields have been proposed.

For example, Patent Document 1 proposes a magnetic shield panel in which corrugated electromagnetic steel sheets are crossed and stacked.
Since this magnetic shield panel crosses and corrugates the corrugated electromagnetic steel sheets, it is said that it can secure mechanical strength and secure shielding properties.

  However, it was not possible to obtain a reliable shielding property against electromagnetic waves of various frequencies even when radiating, that is, when shielding the emitted electromagnetic waves, or when shielding the irradiated electromagnetic waves. .

JP-A-9-199884

  Accordingly, the present invention provides an electromagnetic shield member that shields electromagnetic waves having a desired frequency, an electromagnetic shield that is configured with the electromagnetic shield members, and shields electromagnetic waves having a desired frequency according to a shield object, and an electromagnetic shielding method. For the purpose.

  According to the present invention, a conductive plate having conductivity is formed by forming a concave / convex shape that subdivides eddy currents generated by the incidence of a magnetic field, and the concave / convex shape is formed in accordance with a desired frequency of the electromagnetic wave to be shielded. It is an electromagnetic shielding member or an electromagnetic shielding method.

  The concavo-convex shape that subdivides the eddy current generated by the incidence of the magnetic field described above is a plurality of concavo-convex shapes formed on the conductive plate material, and changes with the same shape or predetermined regularity with respect to the plate material, or changes randomly Embossed shape, corrugated shape, etc.

  The conductive plate may be a porous conductive plate provided with a plurality of small through-holes and concave holes as a whole, only in the concave portion, or in the convex portion, and further, an electromagnetic shielding component such as a conductive material. The electroconductive board | plate material which apply | coated the electromagnetic wave shielding coating material containing this may be sufficient. Furthermore, the electroconductive board | plate material which affixed electromagnetic wave absorptive sheet materials, such as a carbon sheet, may be sufficient.

  According to the present invention, electromagnetic waves having a desired frequency can be shielded. More specifically, the eddy current formed in the conductive plate due to the incidence of the magnetic field does not straddle the cross-sectional change portion and is formed in a portion having a uniform cross section in the conductive plate. Can be subdivided into a plurality of small eddy currents. Therefore, the shielding effect by the cancellation effect of the electromagnetic wave by the reflected wave generated by the subdivided eddy current can be improved as compared with the case where the eddy current not subdivided is generated. In addition, since the irregular shape is formed according to the desired frequency of the electromagnetic wave to be shielded, for example, the electromagnetic wave having the desired frequency is effectively shielded, for example, the electromagnetic wave having a large influence is shielded against the shield object. Can do.

  In addition, since the deformability of the electromagnetic shield member can be improved by providing an uneven shape having a shape corresponding to a desired frequency, for example, the shield member can be easily formed into a shape corresponding to the shape of the shield object. In addition, an electromagnetic shield having a high shielding effect can be configured.

In addition, when the uneven | corrugated shape of multiple types according to a desired frequency is formed, a high shielding property can be obtained with respect to electromagnetic waves of multiple types of frequencies, that is, a wide range of frequencies.
Furthermore, when using a porous conductive plate with a plurality of small through-holes or concave holes, or a conductive plate coated with electromagnetic wave shielding paint, or affixing an electromagnetic wave absorbing sheet material such as a carbon sheet. When the attached conductive plate material is used, in addition to the uneven shape of the shape corresponding to the desired frequency, it can be applied to electromagnetic waves with different frequencies depending on the small through-holes and concave holes, or electromagnetic shielding paint, and the attached sheet material. Shielding properties can be obtained.

As an aspect of the present invention, the concavo-convex shape can be provided with a folded portion that folds at least in the thickness direction.
According to the present invention, the shielding effect can be improved. More specifically, by providing at least a folded shape portion that folds back in the thickness direction, the reflected wave reflected by the surface of the conductive plate is again incident on the folded shape portion to form an eddy current. Further shielding effect can be obtained. In addition, if a shield member is configured by laminating a conductive plate material and another plate material, the laminated plate materials can be assembled with each other by providing a folded portion in the concavo-convex shape, and other fixing members, etc. It can be integrated without using.
Moreover, the deformability of the electromagnetic wave shielding member can be further improved by the expansion and contraction of the folded shape portion.

  As an aspect of the present invention, the conductive plate material and a magnetic material alloy plate material having a high magnetic permeability can be laminated. A porous magnetic material-based alloy plate provided with a plurality of small through-holes and concave holes as a whole, only in the concave portions, or in the convex portions may be used. It is necessary to arrange so that they do not communicate with each other.

  According to the present invention, a high frequency electromagnetic wave is shielded by a conductive plate material provided with uneven shapes according to a desired frequency, that is, by subdivided eddy currents, and a low frequency electromagnetic wave is shielded by a laminated magnetic material alloy plate material. Therefore, electromagnetic waves with a wide range of frequencies can be efficiently shielded.

  The conductive plate material and the magnetic material alloy plate material are laminated with a conductive plate material having an uneven shape and a flat magnetic material alloy plate material, and the conductive plate material and the magnetic material alloy plate material. It is possible to form a concavo-convex shape formed by laminating layers, or a laminate of a conductive plate material provided with a concavo-convex shape and a magnetic material alloy plate material provided with a concavo-convex shape. Furthermore, the conductive plate material and the magnetic material-based alloy plate material may be laminated via an insulating material. Furthermore, the conductive plate material and the magnetic material-based alloy plate material may be laminated via an electromagnetic wave absorbing sheet material such as a carbon sheet.

As an aspect of the present invention, the conductive plate material can be composed of an aluminum-based plate material, and the magnetic material-based alloy plate material can be composed of an iron-aluminum alloy plate material.
According to the present invention, an electromagnetic shielding member having high deformability and shielding properties can be configured. In detail, because the aluminum-based plate material with high deformation workability and conductivity and the iron-aluminum alloy plate material with high deformability although laminated with a low permeability compared to permalloy, the deformation workability is high and a wide range of An electromagnetic shielding member capable of efficiently shielding electromagnetic waves having a frequency can be configured.

Moreover, this invention is an electromagnetic shield which has arrange | positioned the above-mentioned electromagnetic shielding member so that the shield target object which shields electromagnetic waves may be covered.
Shielding object that shields electromagnetic waves as described above is used to shield the incidence of electromagnetic waves from the outside, such as electrical equipment that shields the incidence of influential electromagnetic waves, or electrical equipment that irradiates itself, that is, shields the generated electromagnetic waves. It can be set as a shield object including not only the case where the generated electromagnetic wave is shielded.
According to the present invention, it is possible to shield an electromagnetic wave having a desired frequency, for example, shielding an electromagnetic wave having a frequency that has a large influence on a shield object.

  Furthermore, this invention arrange | positions the above-mentioned electromagnetic shielding member so that the shield target object which shields electromagnetic waves may be covered, and the said electroconductive board | plate material of the said magnetic-material type alloy board | plate material and the said electroconductive board | plate material laminated | stacked is said electromagnetic wave. It is the electromagnetic shield arrange | positioned toward the electromagnetic wave generation side which produces | generates.

The electromagnetic wave generation side is the side far from the shield object when shielding the incident of the electromagnetic wave from the outside to the shield object, that is, the outside, and when shielding the diffusion of the generated electromagnetic wave, the shield object side, That is, inside.
According to the present invention, it is possible to obtain a high shielding property as compared with the case where the conductive plate member is disposed toward the side opposite to the electromagnetic wave generating side.

  According to the present invention, there are provided an electromagnetic shield member that shields an electromagnetic wave having a desired frequency, an electromagnetic shield that is composed of the electromagnetic shield member and shields an electromagnetic wave having a desired frequency according to a shield object, and an electromagnetic shielding method. be able to.

The perspective view of an electromagnetic shielding plate. The partial expansion perspective view of an electromagnetic shielding plate. Explanatory drawing by the enlarged end elevation of an electromagnetic shielding plate. Explanatory drawing about the manufacturing method of an electromagnetic shielding plate. Explanatory drawing about the shielding effect in an electromagnetic shielding plate. The partial expansion perspective view of the electromagnetic shielding plate of another embodiment. Explanatory drawing about the manufacturing method of the electromagnetic shielding plate of another embodiment. Explanatory drawing by the enlarged end elevation of the electromagnetic shielding plate of another embodiment. The perspective view of an electromagnetic shielding cover. The expanded sectional view of an electromagnetic shielding cover. Explanatory drawing by the enlarged end elevation of the electromagnetic shielding plate of another embodiment. The partial expansion perspective view of a porous electromagnetic shielding plate. Explanatory drawing about the manufacturing method of a porous electromagnetic shielding plate. Explanatory drawing by the enlarged end elevation of a porous electromagnetic shielding plate.

An embodiment for carrying out the present invention will be described below with reference to the drawings.
FIG. 1 shows a perspective view of the electromagnetic shield plate 100, FIG. 2 shows a partially enlarged perspective view of the electromagnetic shield plate 100, FIG. 3 shows an explanatory view with an enlarged end view of the electromagnetic shield plate 100, and FIG. FIG. 5 is an explanatory view showing a manufacturing method of the shield plate 100, and FIG. 5 is an explanatory view showing a shielding effect in the electromagnetic shield plate 100. 3A is an enlarged end view of the electromagnetic shield plate 100 in the width direction w, and FIG. 3B is an enlarged end view of the electromagnetic shield plate 100 in the depth direction d.

  6 shows a partially enlarged perspective view of the electromagnetic shield plate 100 of another embodiment, FIG. 7 shows an explanatory view of a method for manufacturing the electromagnetic shield plate 100 of another embodiment, and FIG. Explanatory drawing by the enlarged end elevation of the electromagnetic shielding plate 100 of embodiment is shown.

  Further, FIG. 9 shows a perspective view of the electromagnetic shield cover 10 constituted by the electromagnetic shield plate 100, FIG. 10 shows an enlarged sectional view of the electromagnetic shield cover 10, and FIG. 11 shows an electromagnetic shield plate 100 of another embodiment. The explanatory view by an enlarged end view is shown.

The electromagnetic shield plate 100 is formed by laminating a ferromagnetic plate Pp, which is a plate material having a high magnetic permeability, and a conductive plate Pc, which is a plate material having high conductivity, and forming an uneven shape.
In this embodiment, an iron-aluminum alloy plate having a thickness of 0.04 mm is used as the ferromagnetic plate Pp, and an aluminum plate having a thickness of 0.02 mm is used as the conductive plate Pc. However, the present invention is not limited to this. A plate material or a foil material having an appropriate thickness may be used. For example, a permalloy plate material may be used as the ferromagnetic plate Pp, and an aluminum alloy plate material may be used as the conductive plate Pc.

  As described above, the electromagnetic shield plate 100 is formed by laminating the conductive plate Pc made of an aluminum plate material and the ferromagnetic plate Pp made of an iron-aluminum alloy plate material, and the uneven portion 110 by an appropriate forming method. Forming.

  As shown in FIG. 3 and the like, the concavo-convex portion 110 is formed in a substantially square shape and a convex shape (or a concave shape) in plan view by a folded portion 111 that is folded back in the thickness direction h of the electromagnetic shield plate 100. However, it may be arranged in a zigzag shape, and not only in a substantially square shape in plan view, but also in a substantially rectangular shape in plan view, a substantially polygonal shape in plan view, a substantially circular shape in plan view, or a plan view You may form in various shapes, such as substantially elliptical shape.

  The folded portion 111 is formed in both the width direction w and the depth direction d of the electromagnetic shield plate 100. However, the folded portion 111 may be formed only in one of the width direction w and the depth direction d. May not be formed in both the width direction w and the depth direction d, and may be the concavo-convex portion 110 without the folded portion 111. 3 shows the conductive plate Pc on the upper side and the ferromagnetic plate Pp on the lower side, either one may be on the upper side, and the shape of the concavo-convex portion 110 formed in FIG. The up and down direction, that is, the front and back direction is not related.

  As shown in FIG. 4, the electromagnetic shield plate 100 having the concavo-convex portion 110 having the folded portion 111 as described above is formed by laminating the conductive plate Pc and the ferromagnetic plate Pp, and then, for example, rolls from multiple directions. It is formed by applying an appropriate forming method such as processing.

The size of the concavo-convex portion 110 formed on the electromagnetic shield plate 100 is set according to a desired frequency in the electromagnetic wave shielded by the electromagnetic shield plate 100.
More specifically, as shown in FIG. 5, when the electromagnetic wave Ew is incident on the electromagnetic shield plate 100, a part of the electromagnetic wave Ew is reflected in multiple directions on the surface of the electromagnetic shield plate 100, and the electromagnetic wave Ew that has not reflected is reflected as a downward magnetic field. When incident, an eddy current Ec is formed in the electromagnetic shield plate 100. Furthermore, a magnetic field Mf in the opposite direction to the electromagnetic wave Ew is formed by the eddy current Ec formed by the incidence of the electromagnetic wave Ew. The magnetic field Mf formed by the eddy current Ec cancels the incident electromagnetic wave Ew and reduces the electromagnetic wave Ew transmitted through the electromagnetic shield plate 100, that is, the incident electromagnetic wave Ew can be shielded.

  However, in the flat electromagnetic shield plate 200 as shown in FIG. 5B, adjacent eddy currents Ec act to form a large eddy current Ec1, and a magnetic field Mf1 is formed by the large eddy current Ec1. On the other hand, as shown in FIG. 5C, the eddy current Ec formed by the electromagnetic wave Ew changes the shape of the concavo-convex portion 110, that is, the folded portion 111 which is a cross-sectional change portion of the concavo-convex portion 110. Since there is no crossing, a small eddy current Ec due to the electromagnetic wave Ew is formed in each uneven portion 110, and a magnetic field Mf 2 due to the small eddy current Ec 2 is formed in the uneven portion 110.

  In this way, the frequency of the electromagnetic wave Ew to be canceled differs depending on the magnitude of the magnetic field Mf generated by the eddy currents Ec having different magnitudes. Therefore, the size of the concavo-convex portion 110, that is, the size of the region of the concavo-convex portion 110 where the cross-section does not change, or the fold-back of the concavo-convex portion 110 so that the magnetic field Mf cancels a desired frequency to be shielded among the incident electromagnetic waves Ew. The amount, that is, the wrap amount in the planar view direction of the concave and convex portion 110 and the convex and concave portion 110, or the folding angle of the folded portion 111 is adjusted.

  As described above, the shielding property of the magnetic field Mf generated by the eddy current Ec formed by the incident electromagnetic wave Ew is highly effective in the high frequency region of the electromagnetic wave Ew. On the contrary, the electromagnetic wave Ew on the low frequency side passes through the ferromagnetic plate Pp by passing through the conductive plate Pc constituting the electromagnetic shield plate 100 and entering the ferromagnetic plate Pp having a high magnetic permeability. That is, since the ferromagnetic plate Pp constitutes a magnetic shield, it is possible to prevent the electromagnetic wave Ew incident on the ferromagnetic plate Pp from being transmitted.

  That is, the electromagnetic wave on the high frequency side of the electromagnetic wave Ew is shielded by canceling with the magnetic field Mf due to the eddy current Ec formed on the uneven portion 110, and the electromagnetic wave on the low frequency side passes through the ferromagnetic plate Pp. Therefore, it is possible to obtain a high shielding property against electromagnetic waves Ew having a wide range of frequencies.

  In the above description, the electromagnetic wave Ew on the low frequency side passes through the ferromagnetic plate Pp, and the shielding effect by the magnetic field Mf of the eddy current Ec has been described for the electromagnetic wave Ew on the high frequency side. Only the case is specially mentioned. Actually, the eddy current Ec is reflected by the surface of the concavo-convex portion 110, passes through the inside of the conductive plate Pc, or is formed by the electromagnetic waves Ew of various frequencies. A further effect can be obtained than the shield effect specially mentioned.

  Further, since the electromagnetic shield plate 100 is formed with the concavo-convex portion 110 having the folded portion 111 after laminating the ferromagnetic plate Pp and the conductive plate Pc, the ferromagnetic plate Pp and the conductive plate Pc are The ferromagnetic plate Pp and the conductive plate Pc can be integrated with each other by using the uneven portion 110 having the folded portion 111 and without using another fixing jig or the like.

  In addition, if it integrates by another attachment jig or attachment operation, as shown to FIGS. 6 thru | or 8, as shown in FIG. 6 thru | or 8, the conductive plate Pc in which the uneven | corrugated | grooved part 110 was formed, and the flat ferromagnetic plate Pp The electromagnetic shield plate 120 may be formed by stacking and integrating. Unlike the electromagnetic shield plate 100 in which the conductive plate Pc and the ferromagnetic plate Pp are stacked and the uneven portion 110 is formed regardless of the front and back, the electromagnetic shield plate 120 is a conductive plate Pc on which the eddy current Ec is formed. The concavo-convex portion 110 is formed on the ferromagnetic plate Pp that allows the electromagnetic wave Ew to pass therethrough.

  As described above, the electromagnetic shield plate 120 formed by overlapping the conductive plate Pc having the concavo-convex portion 110 and the flat ferromagnetic plate Pp has the same shielding property as the electromagnetic shield plate 100 as described above. Can be obtained.

  As shown in FIGS. 9 and 10, the electromagnetic shield cover 10 using the electromagnetic shield plates 100 and 120 configured as described above is formed in a shape corresponding to the shape of the shield target T to be shielded from the electromagnetic wave Ew. Shielding performance can be obtained.

  Note that the shield target T for which the influence of the electromagnetic wave Ew from the outside is to be blocked is, for example, an electronic component such as a CPU. On the contrary, the shield target T that generates the electromagnetic wave Ew by itself and wants to block the radiation of the electromagnetic wave Ew to the surroundings is, for example, an electric drive device such as a high-power motor.

  9 and 10, for example, a state in which an electronic component is used as the shield target T is illustrated. Thus, even if the electromagnetic shielding plate 100 (120) in which the uneven part 110 having the folded part 111 is formed has a complicated shape corresponding to the shield object T, the folded part 111 of the uneven part 110 expands and contracts. Thus, the limit drawing ratio (LDR) of the electromagnetic shield plate 100 is increased, and the electromagnetic shield cover 10 having a complicated shape along the external shape of the shield target T can be formed.

  Therefore, the electromagnetic shielding cover 10 formed in a complicated shape along the appearance shape of the shield target T can provide a high shielding effect for a wide range of frequencies as described above.

  The electromagnetic shield cover 10 using the electromagnetic shield plate 100 (120) configured by superposing the conductive plate Pc and the ferromagnetic plate Pp is configured to prevent the electromagnetic wave Ew from being incident on the side where the electromagnetic wave Ew is generated. In the case of the electromagnetic shield cover 10 to be prevented, the conductive plate Pc is on the outside, and conversely, in the case of the electromagnetic shield cover 10 to prevent the radiation of the electromagnetic wave Ew generated from the shield target T, the conductive plate Pc is on the inside. To place.

  Thereby, the electromagnetic wave Ew having a desired frequency on the high frequency side is shielded by the magnetic field Mf of the eddy current Ec formed by the electromagnetic wave Ew at the uneven portion 110 of the conductive plate Pc on the side close to the source of the electromagnetic wave Ew, Of the electromagnetic wave Ew that has passed through the conductive plate Pc, the electromagnetic wave Ew on the low frequency side can pass through the ferromagnetic plate Pp, and the electromagnetic wave Ew reaching the shield target T can be shielded.

  The electromagnetic shield cover 10 may be arranged so that the conductive plate Pc is opposite to the side that generates the electromagnetic wave Ew, but the electromagnetic shield cover 10 is set so that the conductive plate Pc is the side that generates the electromagnetic wave Ew. Since the electromagnetic shield cover 10 can be shielded in advance by the eddy current Ec generated by the electromagnetic wave Ew having a desired frequency at the concave and convex portion 110 by arranging the electromagnetic shield cover 10, the electromagnetic wave Ew incident on the opposite side is first strong when arranged on the opposite side. Shielding performance is improved as compared with the case where the electromagnetic wave Ew having a desired frequency is shielded by the conductive plate Pc constituting the concavo-convex portion 110 among the electromagnetic waves Ew transmitted through the magnetic plate Pp and then transmitted through the ferromagnetic plate Pp. can do.

  In the above description, the conductive plate Pc and the ferromagnetic plate Pp are laminated, and the electromagnetic shield cover 10 is formed so as to be the conductive plate Pc on the transmission source side of the electromagnetic wave Ew. In addition to the ferromagnetic plate Pp, as shown in FIG. 11A, a conductive plate Pc is further laminated on the opposite side of the ferromagnetic plate Pp, that is, the conductive plate Pc, the ferromagnetic plate Pp, and the conductive plate. The electromagnetic shield cover 10 may be composed of the electromagnetic shield plates 100 stacked in this order of the plates Pc. In this case, even if the oscillation source of the electromagnetic wave Ew is arranged either inside or outside the electromagnetic shield cover 10, the above-described effect can be obtained and further shielding performance by the electromagnetic shield plate 100 having three layers can be obtained.

  In the above description, the uneven portion 110 having a uniform shape is formed on the electromagnetic shield plate 100. For example, as shown in FIG. 11B, the uneven portion 110 having various sizes is set to a predetermined rule. It may be formed along or at random. Thereby, it can shield more effectively with respect to multiple types of frequencies.

  Furthermore, as shown in FIG. 11C, the uneven portion 110 formed on the laminated ferromagnetic plate Pp or conductive plate Pc is formed on the uneven portion 110 and conductive plate Pc formed on the ferromagnetic plate Pp. The size of the uneven portion 110 may be different.

  Moreover, as shown in FIG.11 (d), the uneven | corrugated | grooved part 110 provided with the multi-step folding | returning part 111 in the thickness direction h may be comprised, and even if it is the uneven | corrugated | grooved part 110 of the same shape, FIG. ), The electromagnetic shield plate 100 may be configured by laminating and integrating the ferromagnetic plate Pp and the conductive plate Pc on which the concavo-convex portion 110 is formed in advance.

  Note that the ferromagnetic plate Pp on which the concavo-convex portion 110 is formed and the conductive plate Pc may be laminated, but as shown in FIG. 11E, the concavo-convex portion is formed on both sides of the flat ferromagnetic plate Pp. A conductive plate Pc on which 110 is formed may be laminated.

  Furthermore, as shown in FIG. 11 (f), the conductive plates Pc disposed on both sides may be laminated such that the direction of the concavo-convex portion 110 is opposite in the thickness direction h. Of course, at this time, the conductive plate Pc on which the concavo-convex part 110 is formed and the ferromagnetic plate Pp on which the concavo-convex part 110 is formed are laminated so that the direction of the concavo-convex part 110 is opposite in the thickness direction h. The shield plate 100 may be configured. Even in these cases, it is possible to more effectively shield against a plurality of types of frequencies.

  Thus, the uneven part 110 which subdivides the eddy current Ec generated by the incidence of the electromagnetic wave Ew is formed on the conductive plate Pc having conductivity to constitute the electromagnetic shield plate 100, and the uneven part 110 is shielded. By forming according to the desired frequency of the electromagnetic wave, the electromagnetic wave of the desired frequency can be shielded.

  More specifically, the eddy current Ec formed in the conductive plate Pc by the incidence of the electromagnetic wave Ew does not straddle the cross-sectional change portion, and is formed in a portion having a uniform cross section in the conductive plate Pc. 110 allows the eddy current Ec2 to be subdivided into a plurality of smaller sizes than the eddy current Ec1 formed in the flat electromagnetic shield plate 200.

  Therefore, the shielding effect by the cancellation effect of the electromagnetic wave by the reflected wave generated by the subdivided eddy current Ec can be improved as compared with the case where the eddy current Ec1 not subdivided is generated.

  Further, since the uneven portion 110 is formed according to the desired frequency of the electromagnetic wave to be shielded, the electromagnetic wave having the desired frequency is effectively shielded, for example, by shielding the electromagnetic wave having a large influence on the shield target T. can do.

  Moreover, since the deformability of the electromagnetic shield plate 100 can be improved by providing the uneven portion 110 having a shape corresponding to a desired frequency, for example, the shield member is shaped according to the shape of the shield target T. It can be formed easily.

  Further, since the folded portion 111 is provided in the uneven portion 110 so as to be folded back in the thickness direction h, the shielding effect can be improved. More specifically, by providing the concavo-convex portion 110 with the folded portion 111 that is folded back in the thickness direction h, the reflected wave reflected by the electromagnetic wave on the surface of the conductive plate Pc is incident on the folded portion 111 again to form the eddy current Ec. The shield effect described above can be further obtained.

Further, the electromagnetic shield plate 100 formed by laminating the conductive plate Pc and the ferromagnetic plate Pp, which is another plate material, is provided with a folded portion 111 in the concavo-convex portion 110, so that the laminated conductive plate Pc and the ferromagnetic plate Pp are ferromagnetic. The plate Pp can be assembled and can be integrated without using other fixing members.
Further, the deformability can be further improved by the folded portion 111.

  In addition, since the electromagnetic shield plate 100 is configured by laminating the conductive plate Pc and the ferromagnetic plate Pp having a high magnetic permeability, the conductive plate Pc provided with the concavo-convex portion 110 corresponding to a desired frequency That is, high frequency electromagnetic waves can be shielded by the subdivided eddy currents Ec, and low frequency electromagnetic waves can be shielded by the laminated ferromagnetic plate Pp, so that electromagnetic waves of a wide range of frequencies can be efficiently shielded.

  Further, since the electromagnetic shield plate 100 is configured by using the aluminum plate for the conductive plate Pc and the iron-aluminum alloy plate for the ferromagnetic plate Pp, the electromagnetic shield plate 100 having high deformation workability and shielding property is provided. Can be configured.

  More specifically, a highly deformable and highly conductive aluminum plate is used for the conductive plate Pc, and a low deformability iron-aluminum alloy plate is used for the ferromagnetic plate Pp, although the permeability is lower than that of permalloy. Therefore, it is possible to configure the electromagnetic shield plate 100 that has high deformability and can efficiently shield electromagnetic waves in a wide range of frequencies.

  Moreover, since the uneven | corrugated | grooved part 110 is arrange | positioned so that the shield target T which shields electromagnetic waves may be covered, and the electromagnetic shield cover 10 is comprised, for example, shielding the electromagnetic waves of the frequency with a big influence on the shield target T It is possible to shield an electromagnetic wave having a frequency of.

  Furthermore, by arranging the conductive plate Pc of the ferromagnetic plate Pp and the conductive plate Pc constituting the electromagnetic shield cover 10 toward the electromagnetic wave generating side that generates the electromagnetic wave, the conductive plate Pc becomes the electromagnetic wave generating side. Compared with the case where it arrange | positions toward the opposite side, high shield property can be acquired.

Further, as shown in FIGS. 12 to 14, a porous electromagnetic shield plate 130 may be configured by laminating a porous conductive plate Pc1 having a plurality of through holes K and a porous ferromagnetic plate Pp1.
12 is a partially enlarged perspective view of the porous electromagnetic shield plate 130, FIG. 13 is an explanatory view of a method for manufacturing the porous electromagnetic shield plate 130, and FIG. 14 is an enlarged end view of the porous electromagnetic shield plate 130. An explanatory diagram is shown.

  The porous electromagnetic shield plate 130 includes a porous conductive plate Pc1 in which the through holes Kc are arranged in a lattice pattern and a porous ferromagnetic plate Pp1 in which the through holes Kp are arranged in a lattice shape, and an uneven portion having a folded portion 111. 110 is formed.

  The arrangement of the through holes Kc formed in the porous conductive plate Pc1 and the arrangement of the through holes Kp formed in the porous ferromagnetic plate Pp1 are determined when the porous conductive plate Pc1 and the porous ferromagnetic plate Pp1 are stacked. The through holes Kc and the through holes Kp are arranged so as not to overlap each other, that is, in a state where the porous conductive plate Pc1 and the porous ferromagnetic plate Pp1 are stacked.

  In addition to the effect of the electromagnetic shield plate 100 composed of the conductive plate Pc and the ferromagnetic plate Pp described above, the porous electromagnetic shield plate 130 configured in this way is one of the eddy currents Ec subdivided by the uneven portions 110. Since the part is further subdivided by the through hole K (Kc, Kp), the frequency of the electromagnetic wave Ew to be canceled differs depending on the magnetic field Mf due to the eddy current Ec having a different size depending on the through hole K. The electromagnetic wave Ew can be shielded.

  Therefore, the electromagnetic shield cover 10 constituted by the porous electromagnetic shield plate 130 also has the same effect as the electromagnetic shield cover 10 constituted by the electromagnetic shield plate 100, and also has the effect by the porous electromagnetic shield plate 130 as described above. be able to.

  In the above description, the through hole K (Kc, Kp) is configured as a through hole penetrating in the plate thickness direction. However, the through hole K (Kc, Kp) may be formed in a concave shape on the incident side of the electromagnetic wave Ew. Further, although the through holes K are arranged in a lattice pattern, they may be arranged in a zigzag pattern, and the through holes K may be arranged only on the concave portions of the concave and convex portions 110 or only on the convex portions, not on the entire surface of the plate material. It may be formed.

  Furthermore, although the porous electromagnetic shield plate 130 is formed by laminating the porous conductive plate Pc1 and the porous ferromagnetic plate Pp1, the ferromagnetic plate Pp that does not include the porous conductive plate Pc1 and the through hole Kp (FIG. 14 ( b)), or a porous electromagnetic shield plate 130 may be formed by laminating a conductive plate Pc not provided with a through hole Kc and a porous ferromagnetic plate Pp1 (see FIG. 14C).

In the correspondence between the configuration of the present invention and the above-described embodiment, the conductive plate member and the aluminum-based plate member correspond to the conductive plate Pc or the porous conductive plate Pc1,
Similarly,
The magnetic field corresponds to the electromagnetic wave Ew,
The eddy current corresponds to the eddy current Ec,
The uneven shape corresponds to the uneven portion 110,
The electromagnetic shield member corresponds to the electromagnetic shield plate 100, 120 or the porous electromagnetic shield plate 130,
The folded shape portion corresponds to the folded portion 111,
The magnetic material type alloy plate and the iron-aluminum alloy plate correspond to the ferromagnetic plate Pp or the porous ferromagnetic plate Pp1,
The shield object corresponds to the shield object T,
The electromagnetic shield corresponds to the electromagnetic shield cover 10,
The present invention is not limited only to the configuration of the above-described embodiment, and many embodiments can be obtained.
For example, a high voltage cable that generates electromagnetic waves may be covered with the electromagnetic shield cover 10 in the extending direction and shielded.

Further, the electromagnetic shield cover 10 may be constituted by only one or a plurality of laminated conductive plates Pc. Furthermore, the electromagnetic shield cover 10 may be formed by laminating the laminated conductive plates Pc and the ferromagnetic plates Pp. It may be configured.
Further, the electromagnetic shield cover 10 may be configured by laminating the conductive plate Pc and the ferromagnetic plate Pp via an insulating layer such as an insulating film.

  Moreover, you may comprise the electromagnetic shielding cover 10 using the electroconductive plate Pc and the ferromagnetic plate Pp which apply | coated the electromagnetic wave shielding coating material containing electromagnetic wave shielding components, such as a electrically conductive material, at least on one side.

  Furthermore, for example, the electromagnetic shield cover 10 may be configured by laminating the conductive plate Pc and the ferromagnetic plate Pp via a sheet having electromagnetic wave absorption such as a carbon sheet. The electromagnetic shield cover 10 may be configured by laminating a conductive plate Pc or a ferromagnetic plate Pp on which a sheet having a sheet is attached.

DESCRIPTION OF SYMBOLS 10 ... Electromagnetic shield cover 100, 120 ... Electromagnetic shield plate 130 ... Porous electromagnetic shield plate 110 ... Uneven part 111 ... Folded part Ew ... Electromagnetic wave Ec ... Eddy current Pc ... Conductive plate Pc1 ... Porous conductive plate Pp ... Ferromagnetic plate Pp1 ... perforated ferromagnetic plate T ... object to be shielded

Claims (10)

In the conductive plate material having conductivity, the concavo-convex shape that subdivides the eddy current generated by the incidence of the magnetic field is formed and configured,
The electromagnetic shielding member which forms the said uneven | corrugated shape according to the desired frequency of the electromagnetic waves to shield. The electromagnetic shielding member according to claim 1, wherein a fold-back shape portion that is folded back at least in the thickness direction is provided in the uneven shape. The electromagnetic shielding member according to claim 1, wherein the conductive plate material and a magnetic material alloy plate material having a high magnetic permeability are laminated. While configuring the conductive plate material with an aluminum-based plate material,
The electromagnetic shielding member according to claim 3, wherein the magnetic material-based alloy plate is made of an iron-aluminum alloy plate. The electromagnetic shield which has arrange | positioned the electromagnetic shielding member in any one of Claims 1 thru | or 4 so that the shield target object which shields electromagnetic waves may be covered. While disposing the electromagnetic shielding member according to claim 3 or 4 so as to cover a shield object that shields electromagnetic waves,
The electromagnetic shield which has arrange | positioned the said electroconductive board | plate material of the said magnetic material type alloy board | plate material and the said electroconductive board | plate laminated | stacked toward the electromagnetic wave generation side which generate | occur | produces the said electromagnetic wave. An electromagnetic shielding member formed by subtracting the concavo-convex shape for subdividing the eddy current generated by the incident magnetic field according to the desired frequency of the electromagnetic wave to be shielded is disposed on the conductive plate material having conductivity so as to cover the object to be shielded. ,
Electromagnetic shielding method. The electromagnetic shielding method according to claim 7, wherein a folded shape portion that is folded at least in the thickness direction is formed in the uneven shape. The electromagnetic shielding member,
While laminating the conductive plate and a magnetic material alloy plate with a high magnetic permeability,
The electromagnetic shielding method according to claim 7 or 8, wherein the laminated magnetic material-based alloy plate and the conductive plate of the conductive plate are arranged toward an electromagnetic wave generation side that generates the electromagnetic wave. While configuring the conductive plate material with an aluminum-based plate material,
The electromagnetic shielding method according to claim 9, wherein the magnetic material alloy plate is made of an iron-aluminum alloy plate.

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