BRPI1107242A2 - Sound receiver headset - Google Patents

Abstract

Ear device sound receiver. Consisting of two shell-shaped elements (1), it may, however, assume any other shape which, concomitantly, is compatible with the purpose for which it is intended and provides an appropriate aesthetic as well as convenience when applied. These ears are provided with an opening (2) suitable for fitting to the user's ears, as well as a front opening (3) protected by a screen (4) or any other component capable of avoid the admission of foreign bodies, such as exempt, so that through these openings, it will be possible to capture the sound, and for this, in the internal region of the devices is provided with proper material to absorb the sound and increase its where the sound will be captured in a directed manner, given the orientation of the opening of the devices, obtained by the positioning of the user's head, which tend to be in the direction of the generating source of the sound you want to hear, and thus, your receipt will become more audible, even without aid microphone or any other similar device, due to the fact the device is able to stifle, substantially periféricos.tt noise

Description

HEADPHONE RECEIVER APPLICATION FIELD

This patent specification report refers to a SOUND RECEIVER HEADPHONE, which acts as the directional sound receiver, condensing and amplifying it, while significantly reducing peripheral noisy interference. .

SUMMARY OF THE INVENTION The present SOUND RECEIVER HEADPHONE DEVICE has its functionality based on the concept of anechoic chamber, and aims, fundamentally, to reduce to a technically viable measure the phenomenon of sound reflection. in relation to the external environment, having applied, on its inner surface, material capable of absorbing the sound, increasing the dispersion, and whose shape will allow the capture of the sound in a directed way.

CORRELATED TECHNICAL CONCEPT Sound is the propagation of a mechanical compression front, or a mechanical wave, which propagates, circumcetrically, only in material media; that is, in media having mass and elasticity, such as solid, liquid or gaseous media.

Natural sounds are mostly signal combinations, but a pure monotonic sound, represented by a pure sinusoid, has an oscillation speed or frequency, measured in hertz (CHz), and amplitude or energy, measured in decibels. The sounds audible by the human ear have a frequency between 20 Hz and 20,000 Hz, and above and below this range are ultrasound and infrasound, respectively.

Human beings, like many animals, perceive sounds with the sense of hearing through their two ears, allowing them to know the distance and position of the sound source, which is also called stereo hearing.

When humans hear a sound, they actually hear various factors, all contributing to the ability to extract meaning; that is, they hear, among others, volume, duration, attenuation, frequency, timbre, brightness, heat, and it is the relationship between these factors that allows sophisticated interpretations, such as the location of sound sources and their identification. Several models have been proposed to try to explain the listener's ability to identify sound, including prototype creation, attribute identification, and the use of innate systems, however, none of these models have been shown to be adequate to explain sound's ability to identify sounds. . Sound is a key element in multimedia. Listening means much more than just listening; it implies the perception of sound with careful discrimination. Sound is generated by a source, propagated through a medium and received by a receiver (listener). The generation and propagation of sound are physical processes, however, their reception is physical, physiological and psychological.

Every sound generates a vibration in the medium through which it propagates, but not every vibration produces sound audible to us. From daily experience we know that when the sound intensity, popularly known as volume, is low; that is, the sound is weak, it is difficult to hear. This difficulty in hearing faint or low volume sounds depends on person to person, worsening greatly in old age. The human ear is divided into three parts outer ear, middle ear and inner ear, the latter being the most complex of all and is directly connected to the brain by the auditory netvo. Importantly, the brain is part of the auditory system, and it is the brain that decodes the electrical impulses generated in the inner ear. Without the brain the sounds would be meaningless to us.

In the external ear, sound can enter the ear canal directly, or be reflected by the ear (ear), whose shape is essential for reflected sound waves to also enter the ear canal, and in turn the differences of time between the sound that arrives directly and the sound reflected by the auditory pavilion that allows, with the interpretation of the brain, that we are able to locate the sources of sound. The auditory pavilion is a part of the outer ear that is present only in mammals. Their shape and size can vary greatly among mammalian orders, depending on their habits and survival needs. In animals such as bats and whales, the phenomenon of echolocalization is fundamental for their survival, the ultrasound emitted by bats and the infrasound emitted by whales are reflected by objects, allowing these mammals to orientate and locate game.

In the middle ear, the discussion of the tympanic membrane as an elastic membrane, and the need to amplify the transmission of pressure exerted by the tympanic membrane to the inner ear, which is completely filled with liquid, allows us to explore a set of mechanical, hydrostatic and undulatory concepts.

In the middle ear, the ossicles, hammer, anvil and stirrup act as a lever, amplifying the sound pressure on the eardrum approximately 25 times; On the other hand, when a very loud noise hits the eardrum, if it is still amplified, it could damage the auditory system, which is not the case due to two tensioning muscles, placed next to the skull, that tighten and slow the movement of the ossicles to the ear. as the intensity of the sound aumerrta. The inner ear is formed by the cochlea, which turns sound into electrical stimuli, and the labyrinth, which has nothing to do with hearing, but only with maintaining the balance of the body. In the cochlea, the buccal and tympanic scales behave as a hydrodynamic system, where the resulting pressure differences, through cochlear division, between the two scales cause upward and downward displacement of the basilar membrane, generating oscillations of different frequencies (ROEDERER, 1998). The high pitched sounds generate wider ripples in the basilar membrane region at the point where it is most stretched (near the stapes), while the low pitched sounds generate wider ripples where it is thicker and looser (end of cochlea). ). It is in the basilar membrane that the high and low sounds are distinguished, and upon which are Corti's sensory organs, which have thousands of hair cells that perform the functions of converting the energy of the mechanical vibrations of the fluid in the inner ear into impulses. and send these impulses to the auditory neurons in the spiral ganglion.

In the spiral ganglion are the auditory neurons, estimated at 35,000 to 50,0000, which are the fundamental units of processing and transmission of electrical signals, which contain information on frequency, intensity and timbre of sound to the brain; Thus, as in the functions performed by the other organs of the human body, the brain plays a fundamental role in the process of hearing, since it interprets and selects the sound signals received by the ear, and different brain regions process, analyze and analyze the brain. interpret different properties of sound. And through the brain sounds make sense to us. Noise is one of the main concerns of modern times. You can have different settings, such as random sound composed of all frequencies, and just like any unwanted sound. Several studies have shown that noise affects both physical and psychological well-being. It is argued that noise acts as a stress-causing agent and as such can activate various physiological systems leading to changes such as such as increased blood pressure, heart rate and vasoconstriction. Exposure to high occupational noise levels is associated with the development of neuroses and irritability, while exposure to high environmental noise levels is associated with mental illness. The magnitude and duration of these effects are determined in part by individual susceptibility, lifestyle and environmental conditions. During a working day, for example, and noise exposure can intersperse periods with levels ranging from low, non-injurious, to high, harmful. Impulsive noise is described as one or more occurrences of short and transient acoustic phenomena lasting less than 0.5 seconds. Physical discomfort caused by noise is experienced from sound pressure levels above 80 - 100 dB. Hearing loss associated with noise exposure can occur at any age, even in childhood. Very loud sounds, even short ones, such as explosions, can immediately produce severe and permanent hearing loss. Tinnitus (tinnitus) are sensory effects that usually accompany temporary or permanent hearing impairment.

Several studies have shown that there is a greater susceptibility of the human ear to noise at the frequencies of 3000, 4000 and 6000 Hz. Noise-induced hearing loss usually appears in the frequency range between 3000 and 6000 Hz. Most of the acoustic energy of speech between 100 and 6000 Hz, the most important between 300 and 3000 Hz. Noise interference with oral communication is a masking process in which simultaneous noise makes speech incomprehensible. Noise interference with speech discrimination results in a large amount of disabilities, such as problems with concentration, fatigue, insecurity and lack of self-confidence, irritation, misunderstandings, diminished working skills, problems in human relationships and countless numbers. stress-related reactions. Hearing loss in the most affected frequency range increases exponentially as a function of the duration of noise exposure. This hearing loss increases rapidly in the first 10 years of exposure and continues to increase gradually less until it reaches a plateau, and with continued exposure there is an extension of effects to the other frequencies.

The effects of noise on hearing can be divided into three categories: temporary threshold change, permanent threshold change and acoustic trauma. Acoustic trauma is restricted to the effects of single exposure or very few exposure to very high sound levels. In the case of acoustic trauma, the sound levels that reach the inner ear structures exceed the mechanical limits of these structures, and often produce their complete destruction or cell damage, and hearing loss from an acoustic trauma is most of the time permanent. Transient threshold change is an effect that may follow exposure to noise. Permanent threshold changes are changes in hearing that persist throughout the life of the affected person and are not reversible by surgical fracture.

BACKGROUND OF THE INVENTION The main objective of the proposed SOUND RECEIVER HEADPHONE DEVICE is to provide a means of easy construction, low cost of production and simple use through which it will be possible to condense and amplify, in a targeted way, the perceived sound. , making it more audible to the ear, due to the suppression of interference generated by peripheral noise, eliminating the use of any other auxiliary means, such as microphones, providing better sound reception, while maintaining the appropriate acoustic conditions for preservation. of the listener's health.

BRIEF DESCRIPTION OF DRAWINGS

For a better understanding of the proposed HEADSET HEARING DEVICE, reference is made to the accompanying drawings, where: Figure 1 - Illustrates a front perspective view of the proposed sound receiving earpiece without the protective screen;

Figure 2 - Illustrates an exploded front perspective view of the proposed device with the prediction of the protective screen;

Figure 3 - Illustrates a front perspective view of the proposed device with applied protection atheist;

Figure 4 - Illustrates a perspective view of the installation of the proposed device, with protection atheist, in the user's ears.

Preferred Description of the Invention

As shown in the accompanying figures, this HEADPHONE RECEIVER consists of two shell-shaped elements (1), but may take on any other shape which, concomitantly, is compatible with its intended purpose. intended and provides an aesthetic effect, as well as convenience, when applied to the user's ears, and these elements are provided with opening (2), fitting to fit the user's ears, and also having front opening (3), protected by a screen (4), or any other component capable of preventing the admission of foreign bodies, such as exempt, so that through these openings it will be possible to capture the sound, and for this, in the region The internal devices have their own material to absorb the sound and increase its dispersion, and where this sound capture will be done, in a directed way, in face of the orientation of the opening of the devices, obtained by positioning the head of the user, which will tend to be towards the source of the sound you wish to hear, and thus their reception will become more audible even without the aid of a microphone or any other similar device due to the fetus of the device is capable of substantially muffling peripheral noise.

Claims (6)

1 . HEADPHONE DECEIVER, characterized by the fact that it consists of two shell-shaped elements (1), which have an opening <2), suitable for fitting to the user's ears, having also a front opening (3), protected by a screen (4). 2. A HEADPHONES DEVICE according to claim 1, characterized in that the devices (1) can take any shape which is concomitantly compatible with its intended purpose and which has an aesthetic effect; as well as convenience, suitable when applied to the user's ears. 3. A HEADPHONE DECEIVER according to claim 1, characterized in that the opening (2) of the devices may provide for the application of any component capable of preventing the entry of foreign bodies. The earpiece of the sound receiver according to claim 1, characterized in that the internal region of the devices is provided with a material suitable for absorbing sound and increasing its dispersion. 5. HEADPHONE DEVICE according to claim Ί (characterized in that the sound pick-up is directed in the face of the opening direction of the devices by positioning the user's head towards the source). generator of the sound you want to hear. 6. A HEADPHONE DEEP RECORDER according to claim 1, characterized in that the reception of sound through the devices becomes more audible due to the fact that peripheral noise is muffled.