Information
-
Patent Grant
-
6783839
-
Patent Number
6,783,839
-
Date Filed
Wednesday, May 24, 200024 years ago
-
Date Issued
Tuesday, August 31, 200420 years ago
-
Inventors
-
-
Examiners
- Morris; Terrel
- Salvatore; Lynda
Agents
-
CPC
-
US Classifications
Field of Search
US
- 002 69
- 002 79
- 002 115
- 002 102
- 002 108
- 361 212
- 442 185
- 442 186
- 442 222
- 442 305
- 428 192
- 428 193
-
International Classifications
- D03D1500
- B32B514
- B32B2302
- A41B100
-
Abstract
An electromagnetic field deflecting garment made up of a dry knitted conductive fabric (2) with conductive filaments (3) disposed in parallel fashion, edged with a lattice conductive fabric (4) with filaments (5) disposed in a criss-crossed pattern, an electrical circuit (10) able to disperse the electromagnetic signal coming from the garment being connected to said fabric (4).
Description
FIELD OF THE INVENTION
The present invention concerns a garment capable of deflecting electromagnetic fields arising from outside sources.
BACKGROUND OF THE INVENTION
At present there are no examples in the clothing field of garments that deflect 5 electromagnetic fields.
The need to produce this type of garment has arisen recently precisely because the quantity of electromagnetic waves to which the human body is exposed has risen considerably.
In the home environment we are continually bombarded by electromagnetic fields originating from radio transmitters and receivers that propagate waves in the radiofrequency range, from liquid crystal displays of various items of electronic equipment and above all phosphorus screens of televisions that transmit electromagnetic waves at a frequency concentrated around 900 GHz.
In the working environment we are often obliged to stay constantly in front of the monitor of a computer which, like a television set, transmits electromagnetic waves at a frequency around 900 GHz.
Outdoors it often happens that we pass near high voltage power cables and these too give off electromagnetic waves. Furthermore, there has recently been a strong development of the GSM cellular telephone network resulting in a considerable spread in the use of cellular telephones and these also emit electromagnetic waves around a frequency of 15 GHz.
Recent medical studies have ascertained that any charge of an electrical or electromagnetic nature that is absorbed the human body impairs the cellular balance of the chondrioma. The chondrioma is a cellular structure formed by the chondriosomes which are cytoplasmic bodies in the form of granules, filaments and rods thought to be responsible for a major part of cell physiology.
The human body initially reacts by compensating for the cellular imbalances in the chondrioma caused by electromagnetic radiation, but in the long term these imbalances are no longer compensated and this causes poor cell physiology with consequent harmful effects on human health.
The object of the invention is to prevent such problems, providing a garment that is simple to make.
SUMMARY OF THE INVENTION
This object is achieved according to the invention, which provides, in one aspect, an electromagnetic field deflecting garment, comprising:
a conducting fabric edged with a lattice fabric;
an electronic circuit operably interconnected to said conducting fabric and said lattice fabric to form a closed circuit, wherein said electronic circuit is operable to dispel an electromagnetic signal received at said garment through a Joule effect.
Preferred embodiments of the invention appear from the dependent claims.
The garment according to the invention is made by means of a lattice-pattern conductive fabric -connected to an electronic circuit Said conductive fabric absorbs the electromagnetic fields and directs them towards the electronic circuit where they are dissipated through the Joule effect. The garment can act as a sort of Faraday cage discharging the electromagnetic signal to ground. The ground must obviously be understood as a virtual ground, since grounding of the circuit is achieved by means of a connection thereof to a cord of conductive material, acting as a groundplate.
Any parallel resonator characterized by a high cutting frequency so as to act as a low-pass filter and cut off all the signals at a frequency above said cutting frequency can be used as the electronic circuit.
It is possible to connect a micro-amperometer to the circuit capable of providing a measurement of the electromagnetic field present in whatever point the user happens to be. The user thus knows when his garment is absorbing and deflecting an electromagnetic field and knows the magnitude of said field.
Said garment is particularly useful for users who spend long periods in front of a television screen or who for reasons of work are subjected to the radiation of a computer monitor.
Furthermore the garment according to the invention can have a pocket especially for holding a cellular telephone so as to protect the user from the magnetic fields given off by said telephones.
Further characteristics of the invention will be made clearer by the detailed description that follows, referring to a purely exemplary and therefore non-limiting embodiment thereof, illustrated in the appended drawings, in which:
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1
shows a plan view of a jacket according to the invention;
FIG. 2
shows a plan view of the jacket in
FIG. 1
open;
FIG. 3
shows a plan view of a detail of a fabric of the jacket in
FIG. 1
;
FIG. 4
shows a plan view of a detail of the edging weave of the jacket in
FIG. 1
;
FIG. 5
shows the electrical diagram of an electronic circuit according to the invention;
FIG. 6
shows a phase diagram and a diagram of the voltage gain according to the frequency of the electronic circuit in
FIG. 5
;
FIG. 7
shows an axonometric view of a further embodiment of the invention.
The garment according to the invention is described with the aid of the figures.
DETAILED DESCRIPTION
Reference is made purely by way of example to a magnetic field deflecting jacket
1
, consisting of dry, conductive knitted fabric
2
. Filaments
3
of conductive material which can preferably be tungsten and carbon are woven parallel into the weave of said fabric
2
. Said filaments
2
are able to conduct the electromagnetic fields that gather on the jacket
1
.
The jacket
1
is edged around the perimeter with a crisscrossed lattice fabric
4
. The fabric
4
has crisscrossed lattice filaments
5
. The filaments
5
must be made of conductive material, preferably tungsten and carbon. The crisscrossed lattice fabric
4
is disposed on the edge of the jacket
1
and is folded over, being made of a thicker and closer weave than fabric
2
and serves to close the conductive circuit that has been created in the jacket
1
.
The jacket
1
can also be covered with a nonconductive material at said edging; purely by way of example velvet can be used as the covering material for the edging. The jacket
1
can be made in a single block or can have closing means such as buttons
6
or zips.
A pocket
7
made of conductive fabric can be made on the inside or on the outside of the jacket
1
. Said pocket
7
can preferably be of such a size as to contain a mobile telephone
8
according to the shapes and size most commonly used commercially or any other object of a similar size.
An electronic circuit
10
is positioned in a special housing
9
that can be made inside the jacket
1
so that the circuit
10
is hidden. The circuit
10
is connected by means of a conductor wire
11
to the edging fabric
5
of the jacket
1
. Grounding of the circuit is obtained by means of a cord
12
made of conducting material, preferably copper. The cord
12
is made to hang from the jacket
1
, so as to be able to discharge the electromagnetic field present on the jacket
1
.
The electronic circuit
10
can be any parallel resonator circuit with a specific cutting frequency and resonance frequency. Said circuit
10
must be able to disperse the electromagnetic signal coming from the jacket
1
through a Joule effect and must be able to cut off the signals above its cutting frequency.
FIG. 5
shows a possible embodiment of the electrical diagram of the circuit
10
. A coupling capacitance
13
is positioned between the edging fabric
4
and the parallel resonator circuit. The parallel resonator consists of the connection in parallel of an inductance
14
, two capacitances
15
,
17
and a resistance
19
. The two capacitances
15
and
17
are decoupled by means of a diode
16
for stabilization of the supply to the circuit
10
. A micro-amperometer
18
is connected between the capacitance
17
and the resistance
19
.
Said micro-amperometer
18
, more or less the size of a wrist watch, can be digital or analogic and is positioned ins special housing
21
made in the outer part of the jacket so as to be visible to the user, and is connected to the electronic circuit
10
by means of connecting cables
20
. The user can thus read the intensity of the electromagnetic field absorbed by the jacket
1
at any time.
The resistance
19
must preferably be chosen with a very high value, about 2 MΩ, in order to be able to disperse the electromagnetic signal coming from the jacket through a Joule effect. The power dispersed by said resistance
19
is in the order of nano Joules. This leads to a minimal increase in temperature, quantifiable as about half a degree centigrade.
The coupling capacitance
13
can be chosen with a value of about 100 pF. The capacitances
15
,
17
of the resonator can be chosen respectively with a value of 20 pF and 10 μF, so that their parallel gives a capacitance of about 20 pF. For the stabilizing diode
16
a commercially available model 1N32A can be used. The inductance
14
of the parallel resonator can be chosen with a value of 10 μH.
In
FIG. 6
a phase diagram of the circuit according to the frequency and a diagram of the voltage gain according to the frequency are shown. Said diagrams are obtained as the output taken on the resistance
19
when a sinusoidal signal with a frequency of 1 kHz is given as the input to the circuit. From the phase diagram two changes of phase can be noted, with a phase shift of 90° around 10 Hz and a phase shift of 180° around 7 MHz.
From the voltage gain diagram we see a peak around 7 MHz, the frequency that corresponds to the cutting frequency of the circuit. Below this cutting frequency of the circuit the signals coming from the jacket
1
are filtered
FIG. 7
shows a farther embodiment of the invention represented by a hat made of the knitted conducting fabric
2
and an edging made of the conducting lattice fabric
4
. The electronic circuit
10
connected by means of the conducting wire
11
to the edging of the hat is positioned inside said hat. A cord
12
hangs from said circuit and acts as the ground.
This embodiment is particularly effective in the case of use of cellular telephones. In fact by wearing the hat according to the invention while communicating with the cellular telephone near the ear, the electromagnetic fields coming from the phone are deflected.
Claims
- 1. An electromagnetic field deflecting garment, comprising:a conducting fabric edged with a lattice fabric having conductive filaments which serve to close a conductive circuit between said conducting fabric and said lattice fabric; and an electronic circuit interconnected through a conductor to said lattice fabric, wherein said electronic circuit is operable to substantially completely dispel an electromagnetic signal coming from said garment through a Joule effect, wherein said electronic circuit is a parallel resonator at a predetermined cutting frequency and predetermined resonance frequency.
- 2. A garment according to claim 1, wherein said conducting fabric is a knitted fabric with filaments consisting of conductive material disposed parallel to each other.
- 3. A garment according to claim 1, wherein said lattice fabric has filaments of conductive material disposed in a lattice wherein at least one filament of conductive material is arranged in a perpendicular orientation relative to the remaining filaments of conductive material.
- 4. A garment according to claim 1, wherein said parallel resonator consists of the connection in parallel of an inductance, a first and a second capacitance decoupled by a diode, and a resistance, said parallel resonator being coupled to the conductive fabric by means of a coupling capacitance.
- 5. A garment according to claim 4, wherein said inductance is about 10 μH, the first capacitance is about 20 pF, the second capacitance is about 10 μF, the diode is the model 1N32A, the resistance is about 2 MΩ and the coupling capacitance is about 100 pF.
- 6. A garment according to claim 1, wherein grounding of the electronic circuit is achieved by means of a cord protruding from the garment and made of conductive material.
- 7. A garment according to claim 1, wherein a microamperometer is connected to said electronic circuit allowing the intensity of the electromagnetic field absorbed by the garment to be displayed.
- 8. A garment according to claim 1, wherein said garment is a jacket.
- 9. A garment according to claim 8, wherein said jacket comprises a housing to hold objects, a housing to contain the microamperometer and a housing to contain the electronic circuit.
- 10. A garment according to claim 1, wherein said garment is a hat.
- 11. A garment according to claim 10, wherein said electronic circuit is positioned inside the hat.
- 12. A garment according to claim 1, wherein said predetermined cutting frequency is about 7 MHZ.
- 13. A garment according to claim 1, wherein said electronic circuit is operable to substantially completely dispel said electromagnetic signal independently of any other connections to said garment.
Priority Claims (1)
Number |
Date |
Country |
Kind |
MI97A2638 |
Nov 1997 |
IT |
|
PCT Information
Filing Document |
Filing Date |
Country |
Kind |
PCT/EP98/07556 |
|
WO |
00 |
Publishing Document |
Publishing Date |
Country |
Kind |
WO99/27807 |
6/10/1999 |
WO |
A |
US Referenced Citations (7)
Foreign Referenced Citations (1)
Number |
Date |
Country |
WO 9637647 |
Nov 1996 |
WO |