ELECTRIC SHOCK PROTECTION ELEMENT AND MOBILE ELECTRONIC DEVICE HAVING SAME

Hereinafter, with reference to a drawing based on a text content of the focuses of the present invention embodiment in the present invention is in the field of the person with skill in the art easily embodiment. as further described can be. The present invention refers to variety of different is embodied in the form described where can be embodiment aspect is not limited. In described thereby unambiguously direct the drawing the present invention and described for the portion that are independent of, the same, or similar, throughout the specification is made by the identical the reference code and adds.

One embodiment of the present invention: an electric shock protection element (100) has door 1 to also as shown in 3, body, electric shock protection (110), and capacitor layer (120a, 120b) includes, said electric shock protection (110) may the [...].

Said electric shock protection element (100) human and it is contactable with the electronic device having a conductor and is disposed between said conductor is not dielectric breakdown a bottom face from said electrostatic the low pass filter passes a, said circuit portion ground conductor films block up the inflow path which it leakage current of external power, said conductor, the treatment fluid is introduced from a communication signal to pass therethrough for the, to this end of the following conditions.:

Vbr > Vin, > Vbr Vcp

Wherein, the electric shock protection element breakdown voltage of Vbr,

the electronic device to external devices of rated voltages Vin,

Vcp the breakdown voltage layer capacitor.

Wherein, said rated voltage may be rated voltages standard the target side is in a country, for example, 240V, 110V, 220V, 120V, 110V, and coils respectively drive the actuator depending on 100V.

The, said body a electric shock protection (110) and capacitor layer (120a, 120b) the fuzzy membership function and the parameter to electrode on one surface (111a, 112a, 121a, 122a, 123a, 115a, 125a, 126a, 127a, 128a) with of a plurality of sheet layer (111,112,113,121,122,123,124,125,126,127,128) is, each is installed at one surface and arranged so as to be 13 a plurality of electrodes or firing on after is made from other through a curing process.

Such body a having permittivity can be made of an insulating material. For example, said insulator ceramic material, low temperature ceramic (LTCC), high temperature ceramic (HTCC) and can be magnetic material and is. The, is oxidized compound metal-based ceramic material, metal-based oxide compounds Er₂ O₃, Dy₂ O₃, Ho₂ O₃, V₂ O₅, CoO, MoO₃, SnO₂, BaTiO₃, Nd₂ O₃ selected ones of at least one 1 may include a.

Wherein, said inner electrode (111a, 112a) spaced apart from the internal surface serves the is formed, can be employs at least one. Number 1 inner electrode (111a) and inner electrode number 2 (112a) are provided at both ends surface serves the external electrode (131,132) electrically respectively may be connected to.

This inner screw electrode (111a, 112a) the Ag, Au, Pt, Pd, Ni, either one or more ingredients cu may include, external electrode (131,132) the Ag, Ni, Sn either one or more of the components may include a.

The, this inner screw electrode (111a, 112a) between spacing and opposed to each other area or overlapping each other length a electric shock protection element (100) (or trigger voltage) breakdown voltage of (Vbr) may be configured in order to satisfy, , said inner electrode (111a, 112a), and the distance between micro 10-100 can be m. For example, said inner electrode (111a, 112a), and the distance between micro m can be 25.

Wherein, inner electrode number 1 (111a) and inner electrode number 2 (112a) spacing between which is 10 micro m if less than, the scene of labor without being resistance to cope with static electricity can be. Furthermore, inner electrode number 1 (111a) and inner electrode number 2 (112a) spacing between which is 100 micro m if the load gradient exceeds the first, discharge disclosure voltage (operating voltage) due to the static electricity to increase the feeling the discharge fuel flowing out by passing through an to cope with static electricity can be the loss of its protection.

The, inner electrode number 1 (111a) and inner electrode number 2 (112a) can be the thickness of the m micro 2-10. Wherein, inner electrode number 1 (111a) and inner electrode number 2 (112a) thickness of micro m if less than 2, inner electrode serves as and is not capable of, if the load gradient exceeds the first m micro 10, limited at secured distance between inner electrode, electric shock protection element (100) and the micro strip bulk of can adversely affect the.

Is on the base and rotated by a, said inner electrode (111a, 112a) a discharge due to the static electricity of the disclosure the 1-15kV voltage (operating voltage) can be. Wherein, electric shock protection element (100) is 1kV hereinafter voltage discharge disclosure, to cope with static electricity and is difficult to ensure by the resistance, if the flow is greater than the 15kV, cannot then pass the electrostatic, thus, electric shock protection element (100) itself. may be damaged by static electricity.

While, the a pair of electrodes (111a, 112a) braced, electrostatic between the and is over voltage from circuit protection device and for protecting peripheral circuits of protective topsheet layer (113) is arranged.

Such protective topsheet layer (113) the said inner electrodes (111a, 112a) at least one a a hollow between gap formation vice-re- (115) comprises the rectangular plate like nut 3. To this end, protective topsheet layer (113) the gap formation vice-re- (115) which are provided with through-holes are in position can be formed.

Non-contact resistance, said body inner electrode number 1 patterns on a top surface (111a) is attached, in parallel number 1 sheet layer (111) and, inner electrode number 2 lower surface (112a) is attached, in parallel number 2 sheet layer (112) are stacked each other, said number 1 sheet layer (111) and number 2 sheet layer (112) between the protective topsheet layer (113) is arranged.

I.e., inner electrode said number 1 (111a) and inner electrode number 2 (112a) can be having holders number 1 sheet layer (111), protective topsheet layer (113) and number 2 sheet layer (112) are sequentially is.

The, inner electrode said number 1 (111a) and inner electrode number 2 (112a) of rotating vertically each other after said protective topsheet layer (113) are 233 certain distance from one another by, said number 1 inner electrode (111a) and inner electrode number 2 (112a) gap formation vice-re- said one is (115) is disposed contact respectively..

On the other hand, said number 1 sheet layer (111) and number 2 sheet layer (112), an optical compensation structure arranged between protective topsheet layer (113) also the 3 as shown in is is formed on the least one through hole.

Wherein, said said topsheet layer protective in that at least one through bore (113) on based on the, inner electrode number 1 are individually arranged lower (111a) and inner electrode number 2 (112a) are. in the chip surface to the region.

The, said gap formation vice-re- the through hole (115) is installed at the. Such gap formation vice-re- (115) contents to inner electrode (111a, 112a) is disposed between, and thus a predetermined thickness along inner wall a height direction a discharge that has been applied as a mesh (115a, 115b, 115c) may include a.

Alternatively, gap formation vice-re- (115) when to the separated location derived from the, said through hole on the inner wall of the two ends of the discharge the TIM can be instance,.

Wherein, said gap formation vice-re- (115) or a discharge applied thereto while it inner electrode said number 2 blue upper end (112a) and adjoin the lower end inner electrode said number 1 (111a) comprises the rectangular plate like nut 3 so as to be in contact, respectively.

Such gap formation vice-re- (115) by the inner electrodes (111a, 112a) between a gap (126) is can be formed. Such void (126) on the outside by inner electrode and static electricity coming from (111a, 112a) can be discharge between. The, inner electrode (111a, 112a) between the electrical resistance of is lower, and the, electric shock protection element (100) across certain value, to reduce the voltage difference may hereinafter. Therefore, electric shock protection element (100) therein may pass the electrostatic without damage.

Wherein, said discharge mesh (115a, 115b, 115c) blue discharge constituting the free conductivity and low dielectric constant, short in overvoltage, should without (short).

To this end, said discharge including for least one blue non-conductive material into, including SiC or silicon family of component copyright 2000 semiconductor material. Together, blue discharge said SiC, carbon, graphite and at least one selected from ZnO material of the 1, Ag, Pd, Pt, Au, cu, Ni, W, Mo 1 selected from at least one material combination in desired proportions by using the first.

In one example, inner electrode said number 1 (111a) and inner electrode number 2 (112a) when including component is Ag, the family of blue discharge said SiC-ZnO may include a component. SiC (Silicon carbide) component and forming silicide film having excellent thermal stability, which excellent stability at oxidizing ambient, a constant conductivity and lining-up which, and having, has low dielectric constant.

And, ZnO component excellent linear resistance characteristic and discharge cycle characteristics, is connected to the semiconductor layer..

ZnO and a SiC each but conductive both used as separate, existing at the surface of a silicon plastic mixing SiC particle by combined with ZnO is formed on.

Constitution: an insulating layer the fully respond to is SiC SiC-ZnO is formed a SiC particle. The, said insulating layer Ag pass cuts off the discharge material to impart insulating, further, to improve resistance to cope with static electricity the electric shock protection element (100) which when mounted, electronic component a has a central portion that short DC is enabled.

Wherein, as one example of material discharge said SiC-ZnO described including the family of component but are not limited to, blue discharge said inner electrode said number 1 (111a) and inner electrode number 2 (112a) according to a the component comprising the non-semiconductor material or metal particles including non-conductive substance is used which can be.

The, said gap formation vice-re- (115) to which the agent is applied on an inner wall of said discharge mesh (115a, 115b, 115c) the gap formation vice-re- (115) to which the agent is applied along the inside walls of number 1 portion (115a) and said number 1 portion (115a) from top of said protective topsheet layer (113) along an upper surface of the inner electrode number 1 (111a) that extend into contact reacting mixture is compressed by a number 2 portion (115b) and said number 1 portion (115a) each of said protective topsheet layer (113) arranged and attached along the lower of inner electrode number 2 (112a) reacting mixture is compressed by a number 8880002012 888 portion that extend into contact (115c) may include a.

Through, said discharge mesh (115a, 115b, 115c) gap formation vice-re- the (115) as well as inner wall of said gap formation vice-re- (115) from and a lower stage top of said number 2 portion (115c) and number 3 portion (115c) said number 1 are each formed to extend up by inner electrode (111a) and inner electrode number 2 (112a) with the contactor elastically outputs a relay driving signal..

Supported to the front surface, said mesh discharge (115a, 115b, 115c) part of the component comprising the non-static electricity spark vaporized by the vapor mesh discharge by (115a, 115b, 115c) a damage to the part of said discharge mesh (115a, 115b, 115c) is the preliminary function number by, to cope with static electricity can be to improve resistance.

On the other hand, protective said topsheet layer (113) a plurality of gap formation vice-re- (115) is installed at the. As such, said gap formation vice-re- (115) number of a defect signal from a defect, static discharge by path is longer, to cope with static electricity can be to improve resistance.

Said number 1 sheet layer (111) and number 2 sheet layer (112), which is disposed between the protective topsheet layer (113) the number 1 sheet layer (111) and number 2 sheet layer (112) and the same area but may be provided having, the number 1 inner electrode (111a) and inner electrode number 2 (112a) includes transistor and a plurality of are stacked up said number 1 sheet layer (111) and number 2 sheet layer (112) a narrow area may be provided having. two found sound.

Said capacitor layer (120a, 120b) the antenna such as the conductor (12), the treatment fluid is introduced from a communication signal for deleting child without to for passing, electric shock protection (110) is electrically connected to the bump parallel can be connected. For example, capacitor layer (120a, 120b) the electric shock protection (110) at least one upper and lower, upper and lower or. can be arranged both.

Wherein, capacitor layer (120a, 120b) each have a plurality of sheet layer. may be. The, capacitor layer (120a, 120b) constituting a plurality of sheet having permittivity layer may be as an insulator, preferably can be formed of.

For example, ceramic material Er₂ O₃, Dy₂ O₃, Ho₂ O₃, V₂ O₅, CoO, MoO₃, SnO₂, BaTiO₃, Nd₂ O₃ 1 including selected ones of at least one metal-based oxidizing compound or, ferrite into, low temperature (LTCC) or high temperature simultaneously the laughter ceramic can be or the like is used as an (HTCC). Together, ZnO series varistor material said ceramic material, or Pr and Bi material may be or the like is used as an, a metal-based oxidizing compound referred to as very-low-Er₂ O₃, Dy₂ O₃, Ho₂ O₃, V₂ O₅, CoO, MoO₃, SnO₂, BaTiO₃, Nd₂ O₃, for example as respectively should understood not to some other kind of metal-based oxidized compound can be used also. two found.

On the other hand, said capacitor layer (120,120a) for manufacturing capacitor electrode of the Ag, Au, Pt, Pd, Ni, cu either one or more of the components may include a.

The, said capacitor layer (120a, 120b) for manufacturing capacitor electrode of type comprises information is formed of a pair of opposing each other for manufacturing capacitor electrode of is (d1) spacing between micro 15-100 range of m can be provided having, for example, 20 micro m interval can be provided having (reference 11 also).

Wherein, said capacitor electrode 15 micro m if less than the distance between a, wireless communication band of communication signals for deleting child without sufficient to passing as to obtain difficult to tightly contact capacitance, if the load gradient exceeds the first m micro 100, capacitor electrode distance between Serial limitations in secure including sheet layers can limit high capacity capacitors are electrically since is according the outside.

The, said capacitor layer (120a, 120b) as a one-pieced structure through capacitor electrode is formed of a pair of opposing thickness for manufacturing capacitor electrode of size of 1/10-1/2 than the distance between can be provided having.

For example, for manufacturing capacitor electrode of is formed of a pair of opposing when m micro 20 that the gap between, said capacitor electrode have a thickness of 2-10 micro range of m can be provided having. Wherein, m hereinafter micro 2 thickness of capacitor electrode is, and is not capable of serves as electrode, 10 micro m the thicker the capacitor electrode if the load gradient exceeds the first is defined in size capacitor layer distance between capacitor electrode for configuring a Serial limitations in secure including sheet layers can limit high capacity capacitors are electrically since is according the outside.

On the other hand, during an end of the capacitor electrode which does not need external electrodes, and composed of an of the free end of said external electrode (131,132) with at least (d2), thereby to obtain the shortest distance m micro 15 is provided having, range of m micro 15-100 can be provided having distance (reference 11 also).

As such, electric shock protection element (100) a capacitor layer (120a, 120b) provided to achieve an enhanced, electrostatic for passing therethrough, of an external power and a function line intersects the, according to the object to be used suitable communication band capacitance can be easily provided by can be. I.e., the capacitor layer (115a, 115b) by, to cope with static electricity [...] a circuit for protecting inner circuit, varistor or Zener diode with for increasing RF receiving quality in the cases of the screw is combined with the screw-like shape having a connected between an input and output node alternatively, one electric shock of protection element (100) as well as protection to cope with static electricity through the RF receiving quality in the cases of the number is compared with the reference.

The electric shock protection element (100) has door 4a as shown in, portable electronic device (10) in, conductor such as casings metal sheath (12) and a circuit part (14) can be disposed between the.

Wherein, said portable electronic device (10) the portable and spanner. may be in the form of portable electronic device. In one example, a smart phone said portable electronic device, such as cellular speakerphone or the like can be efficiently produced, and the portable terminal, smart watch, digital camera, DMB, electronic book, net book, tablet PC, portable computer or the like, and further can be. Such electronic device are external device an antenna for communication with any suitable including structures and can comprise of electronic components. Together, a local area network communication, such as Bluetooth, and fine wiping equipment using the device can be.

Such a portable electronic device (10) comprises a metal (aluminum, such as stainless steel) such as conductive materials, or carbon-fiber synthetic material and/or other fibers, applying them synthetic series, glass, ceramic, plastic and the base material by a combining, a may include a an outer housing.

The, portable electronic device (10) and housing of hollow metal elements in such a manner with the conductor (12) may comprise an. Wherein, said conductor (12) the electronic device and an antenna for communication polarity sync, metal, and conductive accessories may comprise an at least one.

In particular, said portable electronic device (10) a metal said partially surrounds side of the housing of unit or it is entirely made out of can be. Furthermore, a metal said front or rear of the housing of said electronic device exposed outside the hole to unit and a camera unit to can be.

As such, electric shock protection element (100) leakage currents and static electricity from circuit in its inside portable electronic device (10) for protecting human and it is contactable with a conductor (12) and a circuit part (14) can be disposed between the.

The electric shock protecting device (100) the portable electronic device (10) on the housing of metal with a tailored set of two request group can be than proper. Just, metal said metal to each having with a plurality (12a, 12b, 12c, 12d) both the electric shock protecting device (100) has been individually display panel in response to the initial said portable electronic device (10) can be embedded in housing of..

I.e., also as shown in 4a said portable electronic device (10) surrounding side of the housing of a metal such as casings conductor (12) is three sections, of a request for a second each conductor (12a, 12b, 12c, 12d) both the electric shock protecting device (100) is connected to said portable electronic device (10) by substance with conductivity leakage current and a circuit in its inside can be protected.

The, said electric shock protecting device (100) a plurality of metal (12a, 12b, 12c, 12d) which are provided with said when metal (12a, 12b, 12c, 12d) configured to fit the serves for a short message service may be provided in various ways..

In one example, said portable electronic device (10) with the housing of which are provided with camera when said camera surrounding the conductor (12d) to said electric shock protecting device (100) is when subjected to, said electric shock protecting device (100) the line intersects the detection voltage from a braced, static electricity can be provided in the form of an.

Furthermore, said metal (12b) ground serves the case of said electric shock protecting device (100) the metal (12b) line intersects the is connected the input/output pad and a static electricity can be provided in the form of an.

On the other hand, also as shown in 4b, electric shock protection element (100) the metal (12 ') and a circuit board (14') can be disposed between the. The, electric shock protection element (100) electrostatic itself without damage because the for passing, circuit board (14') order to bypass to ground static electricity and a separate protection element (16) and can comprise of a. Wherein, protection element (16) can be the [...] or varistor.

As shown in 4c also, electric shock protection element (100) the metal (12') and a (front End Module) FFM (14a) between matching circuit (for example, R and L component) can be disposed through. Wherein metal (12') antenna can be. The, electric shock protection element (100) communication signal from the metal simultaneously passing inputted from a tip terminal and ring (12') for passing therethrough electrostatic from, , the treatment fluid is introduced from the memory cell to circuit ground via filter in which the blocking is intended.

Also as shown in 4d, electric shock protection element (100) antenna with metal (12') and the associated through the second antenna for implementing communication function IC (14c) can be disposed between the. Wherein, this communication function can be communication NFC. The, electric shock protection element (100) electrostatic itself without damage because the for passing, electrostatic into the earth a separate protection element order to bypass (16) and can comprise of a. Wherein, protection element (16) can be the [...] or varistor.

Also as shown in 4e, electric shock protection element (100) the PIFA (Planar Inverted F Antenna) antenna (20) of a short pin (short pin) (22) and can be disposed between the matching circuit. The, electric shock protection element (100) communication signal from the metal simultaneously passing inputted from a tip terminal and ring (12') for passing therethrough electrostatic from, , the treatment fluid is introduced from the memory cell to circuit ground via filter in which the blocking is intended.

Such electric shock protection element (100) the, also to 5a also as shown in 5c, by a external power supply, and conductor (12) the short points are depending on the can take the different functions.

I.e., also as shown in 5a, circuit part (14) of circuit board, for example, by the external supply through ground leakage current of conductive (12) when the flow of oil to the cavity, electric shock protection element (100) the breakdown voltage (Vbr) is formed on the overvoltage since the compared to the size of, . current source can be kept at open state. I.e., electric shock protection element (100) with its breakdown voltage (Vbr) the portable electronic device to external devices to greater than the of rated voltages, without being electrically connected to the metal solidifies and remains open and the like is capable of exhibiting the human body such as for a conductor (12) leakage current to is vibrated on the first and second is can be.

The, electric shock protection element (100) which is contained within the capacitor layer (120a, 120b) DC component included in the formed on the interruption, leakage current wireless communication band the gap is formed between the substrate because of having low frequency, corresponding with respect to the frequency may be based on large impedance can be line intersects the.

As a result, electric shock protection element (100) has circuitry (14) external power supply ground conductor films block up the inflow path user line intersects the can be protected from electric shock.

Furthermore, also as shown in 5b, conductor (12) from the outside through a static electricity can according, electric shock protection element (100) the [...] to function as a static electricity protection device such as. I.e., electric shock protection element (100) for electrostatic discharge [...] operating voltage (discharge disclosure voltage) is smaller than that of the instantaneous voltage by earthing the static electricity since the is, a matter to be neutralized by means by instantly discharging the may pass the. As a result, electric shock protection element (100) has a conductor (12) a bottom face from the low electrical resistance itself is not dielectric breakdown may pass the static electricity.

The, electric shock protection element (100) which is contained within the capacitor layer (120a, 120b) is (Vcp) the oxide whose dielectric breakdown voltage of the electric shock protection (110) to breakdown voltage of greater than the (Vbr), and static electricity capacitor layer (120a, 120b) is wound and, electric shock protection (110) can be JPO 2003.

Wherein, circuit part (14) electrostatic into the earth a separate order to bypass and can comprise of protection element. As a result, electric shock protection element (100) has a conductor (12) the short points are of the static electricity attached to the, rear internal circuit of a can be protected.

Furthermore, also as shown in 5c, conductor (12) when is introduced into the communication signals over a, electric shock protection element (100) to function as a a capacitor. I.e., electric shock protection element (100) the electric shock protection (110) is held sufficiently open state conductor (12) and a circuit part (14) block but, inside capacitor layer (120a, 120b) is supplied to communication signal may pass the. As such, electric shock protection element (100) of capacitor layer (120a, 120b) communication signals may provide a flowing to the left.

Wherein, said capacitor layer (120a, 120b) the capacitance of the main wireless communication band of communication signals for deleting connected to without it is preferable that the set. Also 6a and 6b as shown in, bandpass frequency band according to capacitance according to simulation results, 5pF for of capacitance or more mobile wireless communication frequency bands (700MHz to 2.6GHz) substantially electrically is communicated not engender much loss exhibits a photoresist patterning.

However, as shown in 6b also, surfaces of a impact on the conditions of the fine, communication receives on/off status from an approximately 30pF or more capacitance being little affected by sensitivity can be into each other, thus, said capacitance layer capacitor in the mobile wireless communications frequency band therefore, a large capacitance is or more 30pF it is preferable that the using.

As a result, electric shock protection element (100) the capacitor layer (120a, 120b) high capacitance conductor (12), the treatment fluid is introduced from a communication signal for deleting child without can be passing.

Hereinafter, 12 also to 7 also electric shock protection element according to an embodiment of the present invention by referring to various. rapidly and to reduce a memory further one embodiment.

Said electric shock protection element (100) the body inner electrodes at said number 1 constituting the inner electrode (111a) and inner electrode number 2 (112a) a variety of shapes, and pattern can be provided with, inner electrode said number 1 (111a) and inner electrode number 2 (112a) in the same pattern the includes different pattern may be provided having.

In one example, as shown in 7a also, constant form inner electrode number 1 is diced (111a) both end sides of which a pair of number 2 inner electrode (112a) ends of unit is used for which are superimposed on one another, gap formation vice-re- applied the TIM discharge on an inner wall (115) the printing disposed one region may be.

Furthermore, also as shown in 7b said number 1 inner electrode (111a) and inner electrode number 2 (112a) is approximately 'Y' -shaped configuration to provided with portion 2 which are superimposed on one another which are superimposed on one another unit is used for the TIM discharge on an inner wall a portion applied gap formation vice-re- (115) are from overlapping region respectively, on the same substrate may be disposed.

Together, said number 1 as shown in also 7c inner electrode (111a) in between the first maintenance is diced constant 2 number 2 to the two inner electrode (112a) approximately two 'Y' -shaped configuration to 2 further includes a first sub-driving portion 4 is disposed with respect to the back which are superimposed on one another, gap formation vice-re- applied the TIM discharge on an inner wall (115) which are superimposed on one another is a 4 may be respectively disposed on portion.

Furthermore, as shown in also 7d said number 1 inner electrode (111a) and inner electrode number 2 (112a) is diced constant each which are superimposed on one another between the first maintenance plate of a discharge on an inner wall to the region applied the TIM two gap formation vice-re- (115) is disposed between 280. may be.

Together, said number 1 as shown in 7e also inner electrode (111a) constant plate of a between the first maintenance one is diced, said number 2 inner electrode (112a) constant between the first maintenance two is diced said number 1 are arranged inner electrode (111a) either end of a tilt surface at a lower part is arranged to the printing, two the region overlapping said discharge will gap formation vice-re- applied the TIM (115) part are coupled with

Said number 1 and inner electrode (111a) and inner electrode number 2 (112a) geometry and various can be arranged, said number 1 in direct inner electrode (111a) and inner electrode number 2 (112a) which are superimposed on one another a portion of a non-intrusive positioning as. two achieved through strong and long-lasting.

Other as in the embodiment, also 8a to 8d as shown in also, electric shock protection element (100) the electric shock protection element (100) and said capacitor layer (120a, 120b) can be stacked a variable manner..

I.e., also as shown in 8a, said capacitor layer (120a) the electric shock protection (110) which can be stacked only upper side of the, 8b as shown in also, electric shock protection (110) of the lower side of the only may stack.

Together, said electric shock protection (110) carries a plurality having can be. For example, as shown in 8c also, said plurality of electric shock protection (110) between the each capacitor layer (120a, 120b) may be deployed, as shown in also 8d, two capacitor layer (120a, 120b) is electric shock protection (110) and is arranged at least in a reference symmetrical, said electric shock protection (110) a plurality of gap formation vice-re- (115) is installed at the.

I.e., electric shock protection element the present invention according to (100) said electric shock protection a plurality of capacitor layer (110) based on symmetrically includes, in an asymmetric fashion which may be included, plurality of capacitor layer between the electric shock protection (110) is configured to be disposed which may be. two is provided, in which the.

As such, said electric shock protection element (100) for configuring a capacitor layer (120a, 120b) guard plug (110) which is not limited the number of a desired according to the capacitance can be having various number, electric shock protection (110) and capacitor layer (120a, 120b) has a watch upper surface also relationship stack of may be. two found.

Other as in the embodiment, also 9a to 9g as shown in also, electric shock protection element (100') the body and a plurality of edge sheet can be formed of heterogeneous layer.

Non-contact resistance, capacitor layer (120a, 120b) type comprises information sheet layer at least one sheet layer which is obtained by using a (A) ceramic material number 1, number 2 layer other sheets that is capable of using optical (B) ceramic material.

The, number 1 ceramic material and number 2 disparate ceramic material can be ceramic material. Wherein, a meaning of ' heterogeneous' formula formula are identical to each other each other properties different from or even. that means, on each other.

I.e., number 1 ceramic material and number 2 ceramic material Er₂ O₃, Dy₂ O₃, Ho₂ O₃, V₂ O₅, CoO, MoO₃, SnO₂, BaTiO₃, Nd₂ O₃ 1 including selected ones of at least one metal-based oxidizing compound or, ferrite into, low temperature simultaneously the laughter ceramic (LTCC), high temperature (HTCC) simultaneously the laughter ceramic can be or the like is used as an.

Together, ceramic material number 1 Er₂ O₃, Dy₂ O₃, Ho₂ O₃, V₂ O₅, CoO, MoO₃, SnO₂, BaTiO₃, Nd₂ O₃ 1 including selected ones of at least one metal-based oxide compound, number 2 ceramic material may be consisting of ferrite and, number 1 number 2 and low temperature ceramic material (LTCC) simultaneously the laughter ceramic high temperature ceramic material may include (HTCC).

Furthermore, ceramic material number 2 ceramic material and number 1 Er₂ O₃, Dy₂ O₃, Ho₂ O₃, V₂ O₅, CoO, MoO₃, SnO₂, BaTiO₃, Nd₂ O₃ 1 including selected ones with each of the at least one metal-based oxidized compound may be one of alternatively, each selected during ferrite may be formed of one of the elements selected.

I.e., number 1 ceramic material and number 2 oxidizing compound metal-based ceramic material, ferrite, low temperature (HTCC) simultaneously the laughter ceramic and hot (LTCC) a variety of combination one another during the ruling may be in the form of, heterogeneous ceramic material which is plastically or hardening. inter-bonded through.

While, the present according to one embodiment of the invention electric shock protection element (100') a capacitor layer formed of nonhomogeneous (120a, 120b) determination result of the determiner number 1 ceramic material and number 2 ceramic material electric shock protection (110) based on in various ways can be arranged.

Also as shown in 9a electric shock protection (110) is bonded to/of a capacitor layer (120a, 120b) consists the number 1 (A) ceramic material, electric shock protection element (100') located that paper currency in the lowermost layer and the uppermost layer of the capacitor layer (120a, 120b) the number 2 (B) .can be comprised of ceramic material.

In hereinafter, for the sake of convenience of heterogeneous ceramic material number 2 is defined that material a to.

Also number 1 number 2 ceramic materials also to 9a to 9g various of ceramic material it is shown arrangement relation. The sheet number 1 (A) deviant crease in the uncovered part of the ceramic material which meaning, the sheet portion (B) deviant crease in drawing number 2 ceramic material which.. I.e., also to 9a 9g in the seat B and A code drawing refers to a material of. two achieved through strong and long-lasting.

Non-contact resistance, capacitor layer (120a, 120b) constituting a plurality of sheet layer whole (A) ceramic material number 1 number 2 or can be (B) comprising one of ceramic material.

Furthermore, capacitor layer (120a, 120b) some sheet layer type comprises information consists (A) ceramic material number 1 layer sheet, capacitor layer (120a, 120b) other of the sheet layer type comprises information number 2 heterogeneous layer sheet (B) .may consist of ceramic material.

On the other hand, said electric shock protection (110) and capacitor layer (120a, 120b) also between the as shown in 9b, at least one intermediate topsheet layer (141,142) which can be arranged, intermediate said topsheet layer (141,142) the capacitor layer (120a, 120b) the same number 2 (B) .can be comprised of ceramic material. Wherein, intermediate said topsheet layer (141,142) a separate sheet metal layers but may be included, said capacitor layer (120a, 120b) sheet layers disposed on the uppermost or that paper currency in the lowermost layer of a different thickness relatively greater than the sheet layer thickness in a form provided having may be.

Furthermore, also as shown in 9c, said capacitor layer (120a, 120b) number 1 a ceramic material determination result of the determiner consists (A) ceramic material, said protective topsheet layer (119) the number 2 (B) .can be comprised of ceramic material.

The, said electric shock protection (110) and capacitor layer (120a, 120b) between the 9d as shown in also, at least one intermediate topsheet layer (141,142) which can be arranged, intermediate said topsheet layer (141,142) the protective topsheet layer (119) the same number 2 (B) .can be comprised of ceramic material. Wherein, intermediate said topsheet layer (141,142) a separate but may be included an absorbent comprising a sheet of a, said capacitor layer (120a, 120b) is constructed from a sheet member disposed on the uppermost or that paper currency in the lowermost layer of different in thickness of relatively greater than the sheet thickness in a form provided having may be.

Also 9e and 9f as shown in, said capacitor layer (120a, 120b) some sheet layer type comprises information number 1 material heterogeneous layer sheet consists (A) ceramic material, said capacitor layer (120a, 120b) other of the sheet layer type comprises information topsheet layer protective sheet layer (119) the number 2 (B) .may consist of ceramic material.

Together, as shown in also 9g, said electric shock protection (110) and capacitor layer (120a, 120b) the number 2 consists (B) ceramic material, said electric shock protection (110) and capacitor layer (120a, 120b) heterogeneous material between the number 1 (A) ceramic material comprises at least one intermediate topsheet layer (141,142) may be is disposed.

One embodiment of the present invention and: an electric shock protection element (100') (A) and a ceramic material the number 1 number 2 ceramic material (B) selects the beam number 1 (A) ceramic material a ceramic material is installed at the body member appropriately high-K material by capacitor layer (120a, 120b) is to configure the is connected with the reference the desired properties, as well as, at least one change in a property configured to fit the characteristics required by the VDS signal is enabled.

While, also also to 9c as shown in 9g, said body constituting a protective topsheet layer (119) ceramic which is the number 2, some or all parts, thereby remaining a heterogeneous ceramic material is ceramic material number 1, said number 1 topsheet layer protective said ceramic material (119) on based on the, lower direction can be symmetrically arranged in the.

The, to different kinds of materials a number 1 number 2 ceramic materials according to junction of ceramic material for each material by considering [...] of, uniform shrinkage and structural stability this is because the alloy, a corrosion-resistant alloy.. This structural stability to the main through the resin mold protection element is enabled.

On the other hand, the heterogeneous material drawing said topsheet layer protective ceramic material number 1 (119) based on the shown to electrically connected to and describe but are not limited to protective said topsheet layer (119) positioned symmetrically relative to a depth which may be. two is provided, in which the.

Together, heterogeneous material ceramic material number 1 said capacitor layer (120a, 120b) varistor provided that methanolate is used as an in part on such as raw material or the like at centered resistance of atomizing and capacity is is reduced.

Wherein, said number 1 ceramic material heterogeneous material according to and capacity characteristics required by the entire thickness of said body as to have an equal thickness over suitable contrast can be used. two found.

Other as in the embodiment, also as shown in 10, said electric shock protection element without using a separate re-gap formation vice-, inner electrode (111a, 111b) mesh of the plasma synthetic gas reformer (145) .can be arranged.

I.e., such electric shock protection (110) has of protective topsheet layer (112) of, the inner electrodes lower (111a, 111b) at least a portion of overlapping each other arranged so as to, said inner electrodes (111a, 111b) mesh of the plasma synthetic gas reformer (145) is arranged. Wherein, said inner electrodes (111a, 111b) the protective topsheet layer (112) of, but may be included directly a lower surface, said protective topsheet layer (112) of, lower sheet to be stacked and at may be included. two found sound.

For example, as shown in also 10, said inner electrodes (111a, 111b) is disposed with respect to the back some't overlap each other, inner electrode number 1 (111a) and inner electrode number 2 (111b) void-overlapping value spaces between a-filled discharge mesh (145) is arranged.

Specifically, inner electrode number 1 (111a) and inner electrode number 2 (111b) the protective topsheet layer (112) over the, the inner electrode number 1 has a smaller width constant (111a) and inner electrode number 2 (111b) having spaced from each other a portion of and overlapping the shape such as a disposed, said number 1 inner electrode (111a) and inner electrode number 2 (111b) mesh discharge in the zone of the-bands overlap upon one another (155) is arranged.

Other as in the embodiment, also to 11a also as shown in 11d, electric shock protection element (100") without using for a separate re-gap formation vice-, inner electrode (111a, 112a) between a gap (154) is can be formed. The, void (154) mesh discharge has a side wall which is (155) and can comprise of.

I.e., electric shock protection element (100") opposing each other the inner electrodes (111a, 112a) protective between the topsheet layer (113) in which there is disposed a, protective said topsheet layer (113) through the least one through hole (154) with a can be constructed. Wherein, said through hole (154) the protective topsheet layer (113) on based on the, lower are individually arranged the inner electrodes (111a) (112a) are. in the chip surface to the region.

Non-contact resistance, electric shock protection element (100") door has as shown in 11a, inner electrode number 1 lower surface (111a) is attached, in parallel number 1 sheet layer (111) and, inner electrode number 2 upper surface (112a) is attached, in parallel number 2 sheet layer (112) are stacked each other, said number 1 sheet layer (111) and number 2 sheet layer (112) between the least one through hole (154) having protective topsheet layer (113) is arranged.

Said number 1 inner electrode (111a) and inner electrode number 2 (112a) can be having holders number 1 sheet layer (111), protective topsheet layer (113) and number 2 sheet layer (112) are sequentially is.

The, inner electrode said number 1 (111a) and inner electrode number 2 (112a) of rotating vertically each other after said protective topsheet layer (113) are 233 certain distance from one another by, said overlap region opposed to each other through hole (154) is arranged.

The, inner electrode said number 1 (111a) and inner electrode number 2 (112a) provided with continuous holes disposed so that the overlap area of (154) into the various can be.

On the other hand, said a pair of external electrode (131,132) a as shown in 11a, said upper face and an underside surface serves to cover from upper stage and a lower part, which extends in a direction to the insertion face horizontal 'U' -shaped cross-section of a plurality of sheet when provided having top layer that paper currency in the lowermost layer and a inner electrode and an outer horizontal to one of the electrodes and a, which extends in a direction at least (d3) interval between a driving part of the distance m micro 15 is provided having, m micro 15-100 range of distance can be provided having.

The, electric shock protection element (100") has door 11b as shown in, electric shock protection (110) and a capacitor layer (120a, 120b) is different electrode spacing and electrode widths can be constructed in.

I.e., disposed oppositely to each other a the inner electrodes (111a, 112a) spacing between storage electrode (d4) (121a, 122a, 123a, 124a, 125a, 126a, 127a, 128a) distance between may the same as the (d1).

The, electric shock protection (110) and a capacitor layer (120a, 120b) (d5) distance between a pair of internal electrode (111a, 112a) (d4) .can be larger than distance between.

I.e., the inner electrodes said (111a, 112a) which is flowed along the electrostatic or leakage current adjacent capacitor electrode from being leaked through inner electrode (111a, 112a) with sufficient 101 preferably. The, said capacitor layer (120a, 120b) and said electric shock protection (110) the distance between which may be m micro 15-100, said inner electrodes (111a, 112a) 2 than the distance between is preferably not less large 500apm. For example, the inner electrodes said (111a, 112a) spacing between which is 10 micro m when, said capacitor layer (120a, 120b) and said electric shock protection (110) the distance between at least m micro 20.

Furthermore, the inner electrodes (111a, 112a)-bands overlap upon one another (w1) width and comprising a storage electrode is less than (w2) width and comprising a-bands overlap upon one another. Wherein, the inner electrodes (111a, 112a) thickness of capacitor electrode the thickness of the. can be smaller than the (t).

The, said body said body a Ti, Zn, Ce, Nd, Bi may comprise an at least one.

On the other hand, the inner electrodes (111a, 112a) formed between the when the TIM discharge void to which the agent is applied, blue discharge said Ti, Ni, Zn, Co, Tc, Zr, La, Nd, Pt may comprise an at least one.

On the other hand, said electric shock protection (110) has door 11c through hole as shown in (154) and thus a predetermined thickness along inner wall of a height direction a discharge that has been applied as a mesh (155) may be having, also filler as shown in 11d (156) may be is filled.

The electric shock protection element (100") the capacitor layer (120a, 120b) is said electric shock protection (110) the center of which lies on the. can be stacked various ways.

I.e., said capacitor layer (120a, 120b) a plurality of sheet layer (121,122,123,124,125,126) and laminating a is, as shown in 12a also, said electric shock protection (110) which can be stacked only upper side of, as shown in also 12b, said electric shock protection (110) of the lower side of the only may stack.

Together, as shown in also 12c said electric shock protection (110) having different by each, said plurality of electric shock protection (110) between the each capacitor layer (120a, 120b) may be is disposed.

Furthermore, as shown in also 12d, electric shock protection (110) the same sheet layer plurality of through holes (154) with a to the, capacitor layer produced from a sheet of of a single layer (121,125) is electric shock protection (110) of, lower may be symmetrically on the array.

Said electric shock protection element (100") the body inner electrodes at said number 1 constituting the inner electrode (111a) and inner electrode number 2 (112a) a variety of shapes, and pattern can be provided with, inner electrode said number 1 (111a) and inner electrode number 2 (112a) in the same pattern the includes different pattern may be provided having.

In one example, frequent, regular basis, such as shown in 13a also is diced form inner electrode number 2 (112a) a pair of the upper side of the inner electrode number 1 (111a) ends of unit is used for which are superimposed on one another, said through hole (154) are stacked up one layer in that region may be disposed, as shown in 13b also, inner electrode number 1 (111a) and inner electrode number 2 (112a) is approximately 'Y' -shaped configuration to provided with portion 2 unit is used for which are superimposed on one another, which are superimposed on one another the part to be in said through hole (154) of the moving picture data set according from overlapping region respectively, on the same substrate may be disposed.

Together, said number 2 as shown in also 13c inner electrode (112a) 2 in between the first maintenance is diced constant one to the, inner electrode number 1 (111a) approximately two 'Y' -shaped configuration to 2 further includes a first sub-driving portion 4 is disposed with respect to the back which are superimposed on one another, said through hole (154) 4 a are may be respectively disposed on portion.

Furthermore, as shown in also 13d said number 1 inner electrode (111a) and inner electrode number 2 (112a) is diced constant each which are superimposed on one another between the first maintenance plate of a through hole to the region (154) .may be 233 in both sides of the window.

Together, said number 2 as shown in also 13e inner electrode (112a) constant plate of a between the first maintenance one is diced, said number 1 inner electrode (111a) constant between the first maintenance two is diced said number 2 are arranged inner electrode (112a) either end of a tilt surface at a lower part is arranged to the printing, will the two from overlapping said through hole (154) may be is disposed.

Said number 1 and inner electrode (111a) and inner electrode number 2 (112a) a variety of shapes, and pattern can be provided with, inner electrode said number 1 in direct (111a) and inner electrode number 2 (112a) which are superimposed on one another a portion of a non-intrusive positioning as. two achieved through strong and long-lasting.

Other as in the embodiment, as shown in 14 also, electric shock protection element (200) constant which are horizontally arranged, and spaced apart from each the inner electrodes (114a, 114b) may include a. I.e., at least one pair of sheet layer (111,112) interior of inner electrodes (114a, 114b) are arranged spaced from each other so as to void is. Preferably said inner electrodes (114a, 114b) has parallel essentially coplanar and is 233 directions, which has improved drug-.

Wherein, the inner electrodes (114a, 114b) between an air gap (164) is can be formed. Wherein, void (164) a pair of internal electrode (114a, 114b) a height greater than the height of may be formed of, the inner electrodes (114a, 114b) of width greater than the distance may be formed as. As such, void (164) the volume of extended surface, due to the static electricity a discharge up and down the power window, electrode (114a, 114b) from fine to apply the force to the door inner electrode (114a, 114b) the intervening spaces are more or device can be raised by coolant is a deficiency can be reduces the incidence of. The, said pores a bottom face the inner electrodes (114a, 114b) disclosure discharge by a as space, said voids volume resistance to cope with static electricity in order to satisfy, preferably set. For example, said volume voids said electric shock protection element (100) can be total volume contrast 1-15%. Wherein, said voids volume electric shock protection element (200) 1% if less than total volume contrast, the inner electrodes (214a, 214b) between proportions of shot-positioned on a bottom, deterioration resistance to cope with static electricity can be. Furthermore, said voids volume electric shock protection element (200) if the load gradient exceeds the first 15% total volume contrast, electric shock protection element (200) is increased to increase the total volume of, mechanical strength coefficient is reduced by the thick heating, upon firing, by means of transformation to a depression and is accepted in a cassette case can generate a.

Non-contact resistance, said inner electrodes (114a, 114b) the number 1 sheet layer (111) upper surface of is 233 each other to define gaps. Wherein, said inner electrodes (114a, 114b) micro 10-100 the gap is between m can be. Such a pair of internal electrode (114a, 114b) the number 1 sheet layer (111) is pattern printing upper surface of.

The, able to be the inner electrodes (114a, 114b) braced, electrostatic between the and is over voltage from circuit protection device and this removable cover protects the peripheral circuits are responsible for blocking off the leakage current void (164) top elid processing device is provided with.

Such void (164) essentially coplanar and said that are arranged parallel with each other on the inner electrodes (114a, 114b) disposed between the air can be filled is has hollow, said void (164) open the upper side said number 2 sheet layer (112) is layered on one surface of the.

The void (164) a plurality further includes a first sub-driving said inner electrode (114a, 114b) deflects accommodation of may be. As such, said void (164) number of a defect signal from a defect, static discharge by path is longer, to cope with static electricity can be to improve resistance.

The, said void (164) the number 1 sheet layer (111) from the upper surface of said inner electrode (114a, 114b) exceeds the height from the surface of a stage top of a height is formed so as to have. I.e., according to one embodiment of the present invention and a moving stroke of an (164) an internal electrode (114a, 114b) exceed entire height of height at which is provided having a pore of the vertebral column (164), can be expanded as the volume of outputs a relay driving signal..

The, static discharge in said inner electrode (114a, 114b) fine from ample space to apply the force to the door having void (164) through a can be raised by coolant is deficiency can be reduces the incidence of.

The, said void (164) the inner electrodes weight 233 each other (114a, 114b) extending upper surface or a lower surface of can be unit to.

Together, said void (164) a pair of internal electrode (114a, 114b) width of the same width as the width can be provided with, the, said void (164) a pair of internal electrode (114a, 114b) is larger than the thickness of can be than.

The void (164) the said inner electrodes (114a, 114b) after pattern printing gap authorization between the a substrate process removed to only said gap authorization is formed. Wherein, said re-gap number 1 sheet layer (111) and number 2 sheet layer (112) after body for forming a pixel block having a predetermined size in pressed by a pressure said void (164) the pressure-by with the is used for the prevention of.

To this end, said re-gap high-temperature heat can be decomposed by as viewers pass by, a protrusion/recess shape and are after sheet metal layers is fired and the organic constitution: removed when. In one example, said re-gap 200-2000 °C a temperature of between and may degrade in-range can be a protrusion/recess shape and are.

The, said inner electrodes (114a, 114b) a variety of shapes, and pattern can be provided with, in the same pattern each other includes, different pattern may be provided having.

For example, which are located opposite to each other an inner electrode (114a, 114b) a polygon are provided in the, circular, elliptical, helical and a combination of these a variety of shapes and can be arranged. And, inner electrodes confront in mutually the same pattern includes and shapes of teeth, other patterned and shape may be provided having.

For example, the inner electrodes said (114a, 114b) between the first maintenance having the substantially rectangular cross section and can be provided with, end having an edge of rectangular cross section approximately 'Y' -shaped configuration to. may be included.

Furthermore, the inner electrodes said (114a, 114b) having a general shape of a call end may be provided with between the first maintenance, comprising a generally plane-shape call end 'Y' -shaped configuration to. may be included.

However, the reproductivity of the laser diode by said electrode are not limited to, is the shape of the above-mentioned 4 combination into the may be, in such a manner that the end facing circular, polygonal, waveform and combining, a which may be into the. two is provided, in which the.

On the other hand, the inner electrodes said (114a, 114b) is with the openings being spaced from one predetermined interval between needles end supports upper and lower surfaces of gap is formed, said gap to the centre of the same in the vicinity of said void (164) top elid processing device is provided with. The, said void (164) on the inner wall of the inner electrode (114a, 114b) and thus a predetermined thickness along a height direction of the TIM a discharge that has been applied as a comprises the rectangular plate like nut 3. The, said blue discharge said void (164) may be included but only inner wall of, said void (164) open to cover an upper part of which may be applied is provided, in which the. two. I.e., said blue discharge said void (164) as well as inner wall of said void (164) connected stages over the open top of the can be extends.

On the other hand, said body constituting a number 1 sheet layer (111) and number 2 sheet layer (112) the number 1 sheet layer (111) on top of number 2 sheet layer (112) may be laminated directly but, said number 1 sheet layer (111) formed around upper surface of the inner electrodes (114a, 114b) and void (164) corresponding to height of a separate buffer layer may stack. Such inner electrode buffer layer (114a, 114b) of which the height and void (164) corresponding to the height of the height of performs serves removing.

Other as in the embodiment, also 15a to 15c as shown in also, said electric shock protection element (200 ', 200 ", 200" ') the protective topsheet layer (211) on the same face of the inner electrodes (211a, 211b) is is spaced apart to each other to form a gap, a pair of internal said cuxs is formed between the electrodes through hole (164) with a may be configured.

I.e., said through hole (164) essentially coplanar and arranged parallel to one another on the inner electrodes (211a, 211b) disposed between the air can be filled is has hollow.

On the other hand, said electric shock protection (210) constituting a inner electrode number 1 (211a) and inner electrode number 2 (211b) is protective topsheet layer (211) improves the filling of the filling material parallel with each other along the coplanar feet of that when the delivery system is placed, said number 1 inner electrode (211a) and inner electrode number 2 (211b), and pattern a variety of shapes also may be provided with.

I.e., electric shock protection element (200") 15b as shown in the, said electric shock protection (210) through hole (164) and thus a predetermined thickness along inner wall of a height direction a discharge that has been applied as a mesh (165) may be having.

Furthermore, electric shock protection element (200' ") as shown in the 15c, said electric shock protection (210) in that at least one through bore (164) to filler (166) may be is filled.

Supported to the front surface, said electric shock protection element to be used on the object a corresponding wireless a communication band suitable communication signals is to provide a variety of a capacitance can be.

Focuses over described but one embodiment of the present invention, specification the present idea of the present invention in the embodiment which is presented to the user to confirmation, if the limited to, understanding event of the present invention the same one skilled in the filamentous in a range of from, additional component, changing, deleting, in the embodiment example, in adding a other by easily proposed may or, in addition of the present invention is that the are within the stomach political of fender will.