DE19756627A1 - Radiation screening device for mobile telephone - Google Patents

Abstract

The radiation screening device (2) has a radiation screening membrane or mesh, e.g. of aluminum and is incorporated inside a pocket of an item of clothing, e.g. a jacket pocket, in which the mobile telephone (1) is transported, for preventing transmission of radiation between the mobile telephone and the body of the wearer.

Description

The invention relates to the field of reducing electromagnetic radiation exposure from carriers of a mobile phone.

Mobile phones receive and emit electromagnetic radiation. Not only in Talk mode but also in standby mode ready to receive.

To attenuate the radiation emitted by the mobile phone, use electromagnetic radiation known to be different methods. Among other things, shields come in housing and antenna parts of the mobile phone and mobile phone antennas with directional characteristics are used. The efficiency of such radiation attenuation devices is critical to the location of the Mobile phones depend on the body or head of humans and on normal operation Operating situation, designed on the head of the person on the phone. When transporting the mobile phone in a clothing pocket, e.g. B. in a jacket pocket, is the probability of the defined, with respect shielding the effective orientation of the mobile phone to the body is very low. At the same time it is The likelihood that emissions from the mobile phone affect the body of the wearer is high.

The above-mentioned shielding devices do not protect the wearer of the mobile phone or only do so insufficient during the transport of the body, which is undefined with regard to the position to the body Mobile phones in a clothing pocket.

Likewise, the transport of mobile phones on the waistband or belt using a belt clip known.

Mobile phones transported in this way usually have the radiation-attenuated side - the microphone and Speaker side - to the outside, so that the damping devices designed for operation on the phone in the mobile phone is not facing the body, therefore not protecting and also protecting the body Reception characteristics deteriorated.

Furthermore, the transport of mobile phones in special bags available in accessories stores - Mobile phone pockets - or quivers, possibly with an integrated radiation attenuation device known.

When transporting the mobile phone in these pockets or quivers with regard to its position Radiation damping device - on the waistband or on the belt - is a shielding effect. However, the radiation-attenuated side of the cell phone usually points outwards, so that in Combination with the possibly body-directed radiation attenuation of the bag or Köchers has radiation protection, but there is also an unnecessary deterioration in Reception characteristics result. Under certain circumstances, this leads to an unnecessary posting of the  Mobile phones from the network or for a booking in a distance that is not the cheapest Transmitting cell of the network, that is, to unfavorable connections in the network.

When transporting the cell phone in pocket or quiver in a clothing pocket, e.g. B. in a jacket pocket, is the probability of the defined, meaningful in terms of shielding Alignment of the bag or the case and the mobile phone to the body is very low that the ratio of reception properties to radiation exposure becomes even more unfavorable.

Last but not least, the pockets that can be worn on the waistband or belt correspond to their dominant ones Visibility or the potential disturbance when sitting or moving, not everyone Taste. Even then, some of the wearers of a mobile phone would not have these special bags are useful if they relate to the ratio of reception properties to radiation exposure would be optimized. And that despite potentially resulting health damage.

The invention specified in claim 1 is based on the problem, a certainly effective Radiation damping device for the close-to-body transport of the mobile phone in To create clothing bags on people. Furthermore, one regarding the standby Send properties as functional, optically little visible, as little disruptive, universal usable and inexpensive radiation attenuation device for the body-near transport of Mobile phones in clothing bags aimed at people.

This problem is solved by the invention specified in claim 1.

The advantages achieved by the invention are in particular that using a Radiation damping device according to the invention, one of the orientation or rotational position of the Mobile phones independent of the wearer's body, mostly invisible to third parties, for the wearer Hardly noticeable and therefore less disruptive, universally applicable and safe radiation protection standby emissions from the mobile phone.

Attaching or inserting the radiation attenuation device into or into a clothing pocket, between the mobile phone and the wearer of the mobile phone, enables one with respect to the body - e.g. B. of Heart - the wearer's most effective protection against the emissions of the mobile phone, regardless of the rotational position of the mobile phone. Only the spatial location: body, in between Damping device and subsequently the mobile phone must be observed.

The damping device can, for. B. partially incorporated into the lining (jacket) of an inside breast pocket or be deposited or attached or inserted into the inside breast pocket of a jacket. Especially at  A cell phone inner pocket of clothing provided for this purpose is one according to the invention Radiation damping device makes sense.

An advantageous embodiment of the invention is specified in claim 2.

A membrane-like design of the damping device, with approximately the same dimensions as the inside dimensions of the clothing pocket guarantees that the inside of the clothing pocket Damping device between the radiation source of the mobile phone and the body of the wearer located. In contrast to transport without a damping device according to the invention Large solid angle safely shielded on the body side. In this way, the most endangered, the radiation source part of the body very close to the mobile phone (1 / rˆ2 depending on the radiation intensity) largely shielded and thus protected.

A further advantageous embodiment of the invention is specified in claims 3 and 4.

Fixing the position of the mobile phone or its transmission source to the damping device and thus to the body of the wearer, creates a defined position and thus a defined, effective Solid angle of the damping device. Due to the predeterminable, fixed position of the mobile phone Damping device, the protected solid angle can be maximized and sensibly aligned. In particular, this turns into a pocket-like approach (or a worked-on one) to a mobile phone matching bag) made of non-radiation-damping material on the damping membrane. This Approach takes the mobile phone in a defined manner and fixes it relative to the damping membrane.

A further advantageous embodiment of the invention is specified in claim 5.

An execution of the damping part of the device according to the invention as a highly conductive, possibly soft ferromagnetic membrane, realizes a sufficiently high damping of the electromagnetic Radiation with a thin membrane.

A further advantageous embodiment of the invention is specified in claim 6.

The execution of the damping part of the device according to the invention as an approximately 15 × 10ˆ (-6) m thick, highly conductive aluminum membrane realizes a physically sensible dimensioning. This is explained in more detail below. The cardboard layer and the plastic layer cause an increase the flexural strength of the damping membrane in the composite. This facilitates the handling of the Radiation damping device in the clothing pocket.

Briefly about the nature of electromagnetic radiation:
Electromagnetic radiation is wave-like and can be described by MAXWELL's equations of electrodynamics.

Waves show diffraction properties when the wavelength λ of the radiation is approximately equal to the size of the irradiated object. The equation applies: λ = c / f. Here λ is the wavelength of the radiation in Meter (m), c the speed of light 3.10ˆ8 m / s and f the frequency in Hz (1 / s). With D-Netz Mobile phones with a frequency of 900 MHz (wavelength 0.33 m) and with E-Netz mobile phones with a frequency of 1.8 GHz (wavelength 0.166 m) is the mobile phone and the Damping device approximately equal to the wavelength of the radiation, so that with the occurrence of Diffraction must be expected. The ratio of the field strengths of diffracted radiation (behind the Damping device) and direct illumination (in front of the damping device) by the mobile phone is assumed to be 1/100 below. So there is behind the damping device diffraction-related in about 1% of the primary radiation.

In addition to the typical wave properties - e.g. B. Diffraction - radiation is electrical Conductivity, the magnetic permeability and the electrical permittivity of the irradiated Medium of crucial importance for the course of the radiation.

The field strength of the electromagnetic radiation suffers in every damping medium exponential waste. The degree of electrical conductivity, magnetic permeability and electrical permittivity of the irradiated medium determines the strength of the waste.

For a damping device, it is mainly the low transmission of the electromagnetic Radiation from the device is important, ie the most complete possible shielding of the electromagnetic radiation.

As a mathematical approximation (diffusion approximation of the MAXWELL equations) for the relative ratio of the field strengths at the beginning (B_o or E_o) and at a distance x from the edge, within the medium (B_x or E_x) and thus also for the transmission of radiation through layers of thickness x (e.g. Lehner; electromagnetic field theory; Springer Verlag; 2nd edition; page 384 ff):

where µ is the magnetic permeability of the medium, κ is the specific electrical conductivity of the Medium, π the number of circles, f the frequency of the radiation and x the depth of penetration into the damping medium or the thickness of the damping medium.  

If one dissolves according to the thickness x, the required layer thickness x of the damping device is obtained as a function of µ (the magnetic permeability of the damping layer, κ (the specific electrical conductivity of the damping layer), f (the frequency of the radiation) and the desired one Ratio of field strengths:

If one considers that approximately 1% of the primary radiation is present behind the attenuation device due to diffraction, it is sufficient to limit the ratio of the field strengths to approximately the same order of magnitude due to attenuation. So it makes sense to:

If you insert the last ratio in the equation for the layer thickness, you get a practical equation for the dimensioning of the damping layer thickness.

The equation shows that a high specific conductivity κ and a high magnetic permeability µ minimize the layer thickness x. (Furthermore, that higher frequencies penetrate less deeply or better dampened - "skin effect".)

Sample calculation

For an e-network mobile phone (f = 1.8.10ˆ9 [1 / s]) and a damping membrane made of aluminum (Al) with the material sizes µ_Al = µ_r.µ_o ≈ 1.1.256.10ˆ (-6) [(Vs) / ( Am)] and κ_Al = 3.7.10ˆ7 [A / (Vm)] results:

E-network: x≈9.10ˆ (-6) m.

For comparison, there is an x ≈ 13.10ˆ (-6) m for a D-network mobile phone (f = 0.9.10ˆ9 [1 / s]).

D-network: x ≈ 13.10ˆ (-6) m.

Through an aluminum membrane with a selected layer thickness of approximately 15.10ˆ (-6) m thus implement physically sensible radiation protection for E and D network mobile phones.

Two embodiments of the invention are shown in the drawings and are described below described in more detail.

In Fig. 1, the carrier of a mobile phone is sketched from the front and from the side. In the side view, the jacket of the wearer is spared and thus allows a view of the inside of the pockets of the jacket. Detail A outlines the breast pocket of the jacket in enlargement. A side view of a mobile phone ( 1 ) is located in the breast pocket. A radiation attenuation device ( 2 ) according to the invention is drawn between the mobile phone ( 1 ) and the carrier. The radiation attenuation device ( 2 ) is by means of connecting elements ( 3 ) - z. B. snap fasteners - fastened in the pocket wall ( 4 ) or in the lining. Alternatively, the radiation attenuation device ( 2 ) can also be sewn on or glued on. When the damping device ( 2 ) is inserted into the pocket, this fastening is advantageous but optional for the insertion process of the mobile phone ( 1 ) into the pocket.

In the case of design variants in which the membrane ( 2 ) is firmly incorporated into the lining of the jacket (not shown), the membrane ( 2 ) is sensibly and securely fixed.

Detail B outlines another pocket of the jacket on an enlarged scale. In the pocket there is an embodiment variant of the radiation attenuation device ( 2 ) according to the invention with an attached pocket ( 2.1 ) in which a mobile phone ( 1 ) is held. The mobile phone ( 1 ) is accommodated in a defined manner in this pocket ( 2.1 ) and thus advantageously positioned with respect to the position and the rotational position of the mobile phone ( 1 ) relative to the body of the wearer. The optional attachment of the radiation attenuation device ( 2 ) to the jacket ( 4 ) or to the jacket pocket ( 4 ) is not shown here.

In Fig. 2 5 arrangements ( Fig. 2a to Fig. 2e) of mobile phone and radiation attenuation device are outlined.

Fig. 2a and Fig. 2b show an example of the size of the device protected by the angle, in dependence on the position of the radiation source dimensions a and b of the mobile phone to the edges of the radiation attenuation device. The more symmetrical the dimensions a and b, the greater the protected angle or - taking all dimensions into account - the solid angle.

Fig. 2c and Fig. 2d show an example of the size of the device protected by the angle, in dependence on the spacing between the radiation source c of the mobile telephone to the radiation damping device. The smaller the distance c, the greater the protected angle or - taking all dimensions into account - the solid angle.

The meaning of the bag ( 2.1 ) can be seen from the dimensions a, b and c and their effect on the angle or solid angle protected by the damping device . The defined position of the pocket ( 2.1 ) is thus advantageously such that the dimensions a and b are as symmetrical and large as possible and the dimension c is also as small as possible. (A trough shape of the damping device open to the mobile phone would further increase the protected angle or solid angle.) In addition to optimizing the geometry of the radiation damping device, it is useful to point the mobile phone towards the body with the damped side, that is, mostly with the microphone and speaker side Body turned.

Fig. 2e schematically illustrates the screen in the region of the angle alpha and the diffraction (6) of the radiation behind the inventive damper. The concentric circles ( 5 and 6 ) represent equipotential lines of the field strength. The radiation is propagated perpendicular to the equipotential lines. In the shielded area (alpha), every second equipotential line is not drawn for the optical representation of the lower intensity of the radiation.

Claims (6)

1. Radiation damping device for mobile phones for the purpose of transporting the mobile phone close to the body in clothing bags - for. B. inner jacket pockets - on humans, characterized in that the radiation damping device is attached or inserted in or on clothing pockets so that after the insertion of the mobile phone into the clothing pocket, the radiation damping device acts between the mobile phone and the body of the wearer. 2. radiation attenuation device for mobile phones according to claim 1, characterized, that the radiation attenuation device on the body side approximately the size of the internal dimensions of the Has a clothing pocket on the body side of at least one radiation-damping membrane or such a fabric or network and that this radiation-damping membrane or such fabrics or mesh in clothing bags can be inserted or attached in such a way that after inserting the mobile phone into the clothing pocket, the radiation-damping membrane or the tissue or network between the mobile phone and the body of the wearer is and acts. 3. radiation attenuation device for mobile phones according to one of the preceding claims, characterized, that the radiation attenuation device in the clothing pocket the location of the mobile phone Damping device fixed. 4. radiation attenuation device for mobile phones according to claim 3, characterized, that the fixation of the position of the mobile phone to the damping device by a pocket-like, non-radiation-damping approach to the radiation-damping membrane on the body or the like Fabric or mesh is realized. 5. radiation attenuation device for mobile phones according to one of the preceding claims, characterized, that the body-side radiation attenuation by at least one highly conductive, possibly ferromagnetic membrane or such a fabric or network is realized.   6. radiation attenuation device for mobile phones according to one of the preceding claims, characterized, that the body-side radiation attenuation through an approximately 15.10ˆ (-6) m thick membrane or layer made of aluminum, in a layered composite of plastic, paper and aluminum.