RU2130755C1 - Detector for electronic stethoscope - Google Patents

Abstract

FIELD: medical devices, in particular, electronic equipment for sound detection. SUBSTANCE: device has housing, resonator and electroacoustic transducer, which has cable which is mounted in housing. In addition device has unit for embracing cable jacket in point in which it is mounted in housing. Housing, resonator and embracing unit have direct acoustic contact to one another and are made from materials in which sound speed is greater than sound distribution speed in material of cable jacket, preferably metal, for example, steel. In addition weight of detector conforms to condition

, where m is weight of detector, in kg, K is elasticity of human body, in N/m, F_e is lower band of effective range of stethoscope, in Hz. EFFECT: . dwg

Description

 The invention relates to medical equipment, in particular to electronic devices for auscultation (listening).

 A known sensor is a cardiomicrophone / 1 / containing a resonator, a housing, an electro-acoustic transducer installed inside the housing and a cable connected to it, fixed in the housing.

 The prototype of the proposed technical solution is an electro-acoustic probe / 2 /, comprising a housing, an electro-acoustic transducer located inside the housing and a cable connected to it, fixed in the housing, the housing and the cable mounting assembly having acoustic contact with each other, and made of a material with a sound propagation velocity greater propagation speed for cable sheath material.

 The disadvantages of the known technical solutions is the high level of acoustic noise caused by the re-emission of extraneous noise into the internal cavity of the sensor and their effect on the electro-acoustic transducer.

 The invention is aimed at reducing the level of interference and increasing sensitivity to weak signals, i.e., increasing the reliability of recognition of the sound picture during auscultation.

где m - масса датчика с резонатором и устройством обжатия оболочки кабеля, кг;
k - коэффициент упругости тканей тела человека, н/м;
F_н - нижняя граница рабочего диапазона частот, Гц.The essence of the invention lies in the fact that the cable attachment node further comprises crimp elements of the cable sheath, and a resonator is installed on the housing in acoustic contact with it, made of a material with a speed of propagation of sound vibrations greater than the speed of propagation of sound vibrations in the material of the cable sheath, and the total mass case, resonator, electro-acoustic transducer and mounting unit with a cable sheath crimping device is selected from the condition

where m is the mass of the sensor with a resonator and a cable sheath crimping device, kg;
k is the coefficient of elasticity of the tissues of the human body, n / m;
F _n - the lower limit of the operating frequency range, Hz.

 The invention is illustrated by the drawing, which shows the proposed sensor design (in section).

 The sensor consists of a housing 1 and a resonator 2 connected to it with an opening connecting the cavity of the resonator and the housing. An electro-acoustic transducer (microphone) 3 is installed inside the housing, separated from the housing 1 and the resonator 2 by elastic gaskets (shock absorbers) 4. The terminals 5 of the microphone are connected to the cores of the cable 6, which is fixed in the housing using a shell crimping device consisting of a collet 7 and a tip 8. The latter is connected by a thread with the fitting 9 of the housing having a conical socket for interaction with the collet 7.

 The sensor is installed by the resonator 2 on the studied area of the patient's body. Sound phenomena captured from the surface of the body excite acoustic vibrations in the cavity of the resonator, which are transmitted through the hole into the internal cavity of the housing 1 and are sensed by the microphone 3. An electrical signal from the microphone terminals 5 is fed through cable 6 to a stethoscope recording and amplification unit (not shown) for diagnosing the condition the patient.

 Due to the fact that the cable sheath crimping device and the resonator have acoustic contact with the case, parasitic noises acting on the sensor (from friction of foreign objects on the cable, the sound background of the room, etc.) propagating along the cable sheath, over the patient’s body surface, in the form of a sound wave in air, they are reflected from the interface between two media (air-metal of the case, cable sheath-metal of the crimping device, the surface of the patient’s body-metal of the resonator) and do not penetrate into the internal cavity of the body to electro-acoustic ohm converter. The reflection coefficient depends on the ratio of the speeds of sound in the material of the medium and in the body material, and for the air-steel boundary is about 0.99. As a result, the signal-to-noise ratio increases, i.e. real sensor sensitivity improves.

 Increasing the sensitivity and reducing the level of incidental noise of the sensor is also facilitated by the execution of the massive resonator and the housing (with the cable mounting and crimping device) of the sensor. With reliable acoustic contact between the parts of the sensor and the proper selection of the total mass, a decrease in its resonance frequency is lower than the lower boundary of the working frequency range, which excludes the possibility of excitation of acoustic vibrations in the housing and their re-emission into the internal cavity to the electro-acoustic transducer.

 For example, in the manufacture of a sensor made of steel with dimensions of ⌀ 35 x 35 mm, the mass of the sensor is about 150 g. This gives the lower limit of the working frequency range of 25 Hz (the resonant frequency of the sensor is about 12-13 Hz).

Sources of information
1. The sensor is a cardiomicrophone of the mingograph 34 of SIEMENS-ELEMA company. Description of the device E 114Е002Е0610305.

 2. Electro-acoustic probe. A.S. USSR N 108885, class A 61 B 7/04. 1958

Claims (2)

1. The sensor of an electronic stethoscope, comprising a housing with an electro-acoustic transducer installed in it, connected by means of an attachment unit to a cable, the attachment unit and the housing being made with acoustic contact with each other and from materials with a sound propagation velocity greater than the sound propagation velocity for the shell cable, characterized in that the mounting unit further comprises crimping elements of the cable sheath, on the housing, in acoustic contact with it, a resonator made of a material with a speed of propagation of sound vibrations, a greater speed of propagation of sound vibrations of the material of the cable sheath, while the total mass of the housing, resonator, electro-acoustic transducer and mount

where m is the total mass, kg;
K is the elasticity of the tissues of the human body n / m;
F _n - the lower limit of the working frequency range of the stethoscope, Hz.  2. The sensor according to claim 1, characterized in that the housing, the resonator and the mount is made of metal, such as steel.