ES2238130A1 - Variable measuring device for controlling effects of radioelectric emissions on health, has filtrate module, capturing substance that responds to incidence of emissions object, receiver answer measuring module and value registry module - Google Patents

Abstract

The device has a filtrate module (3), a capturing substance that responds to incidence of an electromagnetic emissions object (5), a receiver answer measuring module (12) and an obtained value registry module.

Description

Measuring devices for the variables that define the basic restrictions of exposure to fields electromagnetic covering the frequency range from 0 to 300 GHz

Technical sector

The invention falls within the technical sector of electromagnetic variable measuring devices, in this case particularizing in those that characterize the effects on the health of electromagnetic fields. Radiation electromagnetic considered are the non-ionizing

State of the art

Basic Restrictions Restrictions on exposure to electric, magnetic and electromagnetic fields of variable time, based directly on known health effects and biological considerations, are called basic restrictions. Depending on the frequency of the field, the physical quantities used to specify these restrictions are the magnetic induction B , the current density J , the specific energy absorption rate TAE - whose acronym in English responds to the translation of Specific Absortion Rate SAR - and the power density S. Magnetic induction and power density can be easily measured in exposed individuals.

Except for magnetic induction and density of power, the basic restrictions are difficult to measure. The measurement of them is carried out in laboratories under conditions controlled.

Reference levels These levels are offered to practical effects of exposure assessment, to determine the probability that the basic restrictions will be exceeded. Some reference levels derive from restrictions relevant basics, using measurements or techniques computerized, and some refer to perception and indirect adverse effects of exposure to fields electromagnetic The amounts derived are the intensity of electric field E, the magnetic field strength H, the magnetic induction B, the power density S and the current in IL limbs. The amounts that refer to the perception and other indirect effects are the contact current IC and, for pulsatile fields, specific energy absorption SA.

Although the reference levels are exceeded, no the basic restrictions are necessarily being exceeded, but it is necessary to directly verify that they are respected. The relationship between reference levels and restrictions Basic can only be set under certain conditions of average over exposed individuals, that is, in situations of a localized radiation exposure, such as the Use of a mobile phone, are not valid. In conditions near field, when wave conditions are not met flat, they are not valid either. In these situations you must resort to the determination of the basic restrictions, which is very complicated even with the possibility of doing it in a laboratory.

The purpose of this device is to provide a alternative method to laboratory measurements to perform estimates of basic constraints in environments where It was not possible so far.

Explanation of the invention.

The present invention relates to a device of measurement than through a series of filtering procedures of the received electromagnetic field, it affects it on a pickup element in such a way that a response occurs consisting of a variation of physical, chemical properties, in a change in the behavior or evolution of the element collector This response of the pickup element is related to the aforementioned variables as restrictions basic, providing the necessary comparison to perform the measurement or estimation of them. The value obtained is registered for later consideration.

The filtering process selects the electromagnetic fields object of the measurement, rejecting the fields with unwanted frequencies, which could affect the measurement. Filtering can be done through various layers of conductive and dielectric materials, arranged in such a way that reject fields with unwanted frequencies, and deliver the total power of the selected field to the collector. He result of the filtering process will be radiation selected electromagnetic ready to influence the system or pickup element

The pickup system is composed of a vessel that isolates the element from the conditions environmental conditions that may affect the measure. This container may be formed, in part or completely, by the Filtering system filters. In this container the collector element of the electromagnetic fields object of the measurement. The pickup element provides an answer to the electromagnetic fields that affect it. The answer, that it depends on the type of sensor, it is measurable, and from it the value of the basic restriction object of the measure is inferred. This response may be a variation in physical properties. or chemical of the collector, as well as a phenomenon that appears before radio stimulation, such as the emission of photons Likewise, changes in behavior or evolution in those cases in which the collector is a bioindicator, composed of a set of cells, microorganisms, or living tissues. The mass of the pickup element, the surface exposed to radiation or both, as the case may be, They are priced to calculate the measured variable. In those cases where necessary, the container container will provide the right conditions for the right conservation and maintenance of the substances used as collectors

In case some environmental variable, despite of the insulating container, could affect the measurement, is enabled another compartment in said container in which it is placed identical amount of pickup element, but in this new compartment is not subjected to the action of the electromagnetic field It is intended to measure. In this way the effect of the environment is evaluated on the measure to take it into account in obtaining the final score. These two compartments do not have to be contiguous, being able to be physically separated.

The function of the measuring module is to measure the feedback of the sensor. This may be, among others a modification of, temperature, ph level, color change of the pickup element, etc.

The measurement result is recorded in a permanent support, which allows its subsequent observation.

With respect to the prior art This device provides, through the ratio of reactions to the incidence of electromagnetic fields with the variables that comprise the basic constraints, a method for estimate their value in environments other than those of laboratory. In this way, the limitation involved was not overcome be able to estimate the basic constraints, based on the values of the reference levels, in situations where meet far field conditions.

The precision and accuracy of the measurements are will adjust to the requirements of each case, since for certain applications would suffice to verify that a threshold has been exceeded determined, without specifying the final measurement result while  that in other applications a sample of values would be recorded over a period of time.

Description of the figure

For better compression than is described in the following memory is accompanied by a drawing in which, just to example title, a case study of a TAE variable measuring device. Figure 1 shows the schematic drawing of a cross section of the elevation of the device.

The results display screen (13), the output port (14) and start-up switch, (16) They are the parts that will be visible. The other parts of the Figure 1 are hidden by the external housing (15), except the upper part (1) and (2) where the radiation enters.

An embodiment of the invention

The present invention is further illustrated. by the following example, which is not intended to be limiting of its reach. The description of the embodiment is based on the scheme depicted in figure 1.

In this case, the variable that is estimated is the energy absorption rate, APR. Electromagnetic field object of measurement will be variable in time with a 2450 MHz frequency.

The filtering system is composed of layers (1), (2), (3) and (4). The outermost layer of the filter (1), rejects incident electromagnetic radiation from outside. It allows the passage to the outside, as far as possible, of the  radiation that reaches, by some reflection, from the inside. Anyone who cannot transfer it will suffer heavy losses in its interior. To dissipate the energy caused by losses inside this layer will have a high thermal conductivity.

The section of the outer layer marked with (2) it is the removable part, as a cover, that will be removed when starting the measurement. This allows radiation to enter the surface which is released by removing the cover (2), towards the inside of the instrument. This surface will be perfectly defined, since the value of it plays a fundamental role in the calculation of The measured magnitude.

The layers marked with the number (3) allow the step of the work frequency, rejecting or dissipating the rest. The combination of their respective refractive indices. provides the necessary adaptation between the outside environment and the collector so that the total incident power, of the fields at the working frequency, enter the pickup medium. The outermost ones must dissipate the fields with frequencies not desired and have a high thermal conductivity so that this energy affects the collector as little as possible. The most internal, in addition to collaborating in the adaptation of refractive indices, they will have a low thermal conductivity, to isolate the collector from temperature variations abroad.

The last filter layer (4) has some characteristics similar to the layer (1). Its function is to prevent any fraction of radiation penetrates the collector (6), which will be used to discard the environmental variations that have been Could experience inside the instrument. The surface by the radiation will penetrate the sensor element (5) is not covered by the layer (4).

The pick-up elements (5) and (6) depend on the characteristics of the radiation studied, in this case water distilled Water, due to the dipole nature of its molecules, increases its molecular agitation when a field 2450 MHz electromagnetic frequency variable penetrates its inside. Molecular agitation is measured by temperature. Both pickup elements are an identical and known volume of Water. The upper surface of the pickup element (5) occupies the surface that the layer (4) leaves exposed to radiation electromagnetic Radiation does not affect the sensor (6) electromagnetic, so the temperature variation that experience are due to changes in the environment and not to The response to electromagnetic stimulation.

The collectors are surrounded by a layer insulator (9). This layer, of very low thermal conductivity, remains unchanged to the passage of the electromagnetic field of job. Its main function is to isolate the sensors from the ambient temperature changes.

The element (7) is a new reflective layer that surrounds the collector (5). In this way if part of the radiation that penetrates in it manages to cross it is reflected by influencing again on the collector. This element ensures that the radiation that enters the sensor (5) cannot leave the container in the that has entered, and therefore none reaches the collector (6).

Temperature measuring probes (8) in the sensors have identical characteristics and must be calibrated in the same way. They take the temperature of the sensors, which is sent to the device that interprets it. Its effect on the measurement is taken into account during the calibration of the device.

To separate the catchment area from the instruments that process the information obtained by the probes are place a separator (10), whose function is to isolate the sensors of the radiation that could come through the instruments of measurement and vice versa.

Each of the parts that make up the device are attached to the external structure by means of supports (11), whose function is to form a robust whole that support the proper handling of the use to which it will be subjected.

The box marked with (12) represents the device that will perform the APR calculations from the values delivered by the probes. Inside are the electronic circuits necessary to perform said calculation, Present and store the results. Electronic circuits integrated in this department are conveniently protected against external interference from electromagnetic fields.

A screen represented by the element (13) allows to visualize the state in which the meter is, the data, etc.

In this example, an optical port of serial data output (14) to dump the data obtained to a computer or printer. In the box (12) The circuits responsible for controlling this port are included.

External housing (15) provides support for the elements that constitute the device.

The start-up switch (16) will start The measurement procedure. While it turns on, it is removed the cover (2).

The device in the example works with batteries disposable or with a rechargeable. They are not represented in the scheme.

The operation of the described device is report below. The device is placed in place in the that the measurement will be made, oriented in this example, the part superior towards the direction of incidence of the fields. Retires the cover (2) and the meter (16) is put into operation by switching the switch to the ON position. At that time the meter records the temperature of both. The initial value of the temperature of the sensors (5) and (6) will be registered for the subsequent calculation of the APR. During a known time interval t, the Device remains in operation.

The Specific Absorption Rate is defined as the variation with respect to the specific Absorption time, that is, the increase in energy absorbed by a differential element of mass contained in an elementary volume of a given density.

APR = \ frac {d} {dt} \ cdot \ left (\ frac {dU} {dm} \ right) = \ frac {d} {dt} \ cdot \ left (\ frac {dU} {p \ cdot dV} \ right)

The APR is related to the increase in temperature at one point by:

APR = c \ cdot \ frac {\ Delta T} {\ Delta t}

where:

ΔT = temperature variation, measured in ° C.

\ Deltat = duration of exposure, measured in seconds.

c = specific heat of the collector, measured in J / kg ° C

We will assume that the measurements are made under ideal non-thermodynamic conditions, so they can neglect the effects of diffusion heat losses thermal, heat radiation or thermoregulation. This hypothesis it makes sense in this embodiment because of the isolation thermal in which the collectors are located.

We know the temperature increases in both collectors We discount the increase produced by variations environmental and registered in the collector (6) to the experienced by the sensor (5). We also know the time during which it has been The measurement and the specific heat of the sensor have been made. With these data we can get the APR at one point. Taking into account that the volume of the sensors is small enough, the measurement is performed for the necessary time as to consider that the temperature distribution inside is uniform. By integrating the value of the APR into the volume of the sensor we will have the result.

Additional considerations

The measurement process involves a modification of the measured variable. In order to minimize this effect, in particular the effect that on the measured electromagnetic fields had the introduction of the meter, nature more or less Conductor of the materials used for the construction of the device, is specified for each type of application. Equally the effects of electromagnetic fields in the edges and discontinuities of the device components in equipment calibrations.

Although the example presents a device that receives electromagnetic fields from a certain direction, to through a single surface, this will not be a limiting feature of the invention, since in other embodiments it can be realized omnidirectional meters varying exposure surfaces and The shape of the sensors.

Industrial applications

The industrial applications of this invention extend between the areas of emission control radio stations whose health effects must be controlled.  Its application as an emission level controller is evident radio stations of various facilities, let us take as an example the case of mobile phone antennas, radio transmitters and television, microwave oven emissions.

It also has applications to support the response study to exposures to electromagnetic fields of various materials, biological crops, tissues, etc. He development of this invention can provide a number of devices that allow performing the aforementioned studies outside of labs

Claims (5)

1. Device for measuring the variables that define the basic restrictions of exposure to fields electromagnetic covering the frequency range from 0 to 300 GHz, which comprises a filter to select the frequencies of electromagnetic fields subject to measurement, an element or substance that receives electromagnetic emissions subject to the measurement and whose physical or chemical properties are modified, temporarily or indefinitely, measurable by said emissions, a module measuring the modified properties of the collector element and a module for recording the values obtained by the meter. 2. Device according to claim 1 characterized in that the capture substances are formed by natural or synthetic organic compounds, cultures or samples of microorganisms, whose response to the radioelectric emissions object of the measurement is measurably related to any of the variables known as basic restrictions 3. Device according to claim 1 characterized in that the capture substances are inorganic elements, including synthetic elements designed for their response to the radio frequencies object of the measurement. 4. Device according to claim 1 characterized in that the measuring module comprises a series of electronic circuits and devices that perform the calculations necessary to transform the results of the measured variable into the magnitude of the basic constraint considered. 5. Device according to claim 1 characterized in that the measuring module comprises indicators that change color when the measured variable value exceeds a certain dimension.