SU1022200A1 - Smoke detector - Google Patents

Abstract

A SMOKE SENSOR, containing a radiation source, consistently installed with discontinuities at controlled points in space, sections of a coaxial fiber, each of which is soda (sew focusing elements, internal and external cores, with internal core of the first section; the input end faces the radiation source, and the outer core of the last section - to one input of the radiation receiver, the output of which is connected to the detector, a radiation absorber located in the inner core of the last section of the coaxial fiber, I distinguish due to the fact that, in order to increase its informativity, an additional core was inserted into each section of the coaxial fiber, the output end of the additional core of each section was coaxial with the external and internal cores and optically connected to the input core of the secondary core and the core CJBoy section the radiation receiver is made in the form of aHajwaaTopa, which emits its light fluxes, the second input of which is connected to the output end of an additional type of the last section, and the input end of the section is equipped with translucent coating.

Description

The invention relates to an automatic alarm and can be applied in fire-fighting devices.

A smoke sensor is known that contains several sources of optical radiation, and semi-transparent mirrors installed at different points in the monitored space with which the radiation receivers are optically coupled.

The radiation from the source of optical radiation, the passage and partially reflected from a row of translucent mirrors arranged one after the other in the forward and perpendicular direction of the scientific research institute to the source 5 gets to the reception of the NIKI radiation, thus crossing different areas of the monitored space. signal in the presence of smoke Cl.

The disadvantage of the device lies in the fact that translucent mirrors placed strictly one after another do not allow to control hard-to-reach places of fire-hazardous space, as well as to signal the occurrence of a fire when a temperature gradient occurs. In addition, the device requires a large number of receivers of sources of optical radiation, which makes it bulky and unreliable.

The closest to the proposed technical entity is a smoke sensor containing a radiation source, successively installed with gaps in controlled points in the space of a section of a coaxial light guide, each of which contains focusing elements, internal and external housing, and the internal core of the first section the input end faces the radiation source, and the outermost end of the last section is connected to the input of the radiation receiver whose output is connected to a signaling device, the radiation absorber located in the inner s core koaksialns last section) of the optical fiber 2 J,

However, the smoke detector signals a fire; does not allow to know exactly at which point of controlled space occurred,

The purpose of the invention is to increase the formatting of the device.

The goal is achieved by the fact that in a smoke detector containing a radiation source, successively installed with gaps in controlled points in space, sections of a coaxial light guide, each of which contains focusing elements, internal and external cores, the internal core of the first section facing the radiation source, and the outer core of the last section - to one input of the radiation receiver, the output of which is connected to the detector, the radiation absorber located in the inner core of the last An additional core is inserted into each section of the coaxial fiber, placed coaxially with the external and internal cores, the output end of the additional core of each section is optically connected with the input end of the additional core of the subsequent section and with the external core of its section, the radiation receiver is made in the form of an analyzer relations of magnitudes of light fluxes, the second input of which is connected to the output end of an additional core of the last section, and the input end of the outer core of each section is provided with a floor transparent coating.

The drawing shows one of the possible variants of the smoke sensor, section.

The radiation source 1 is connected to the radiation receiver 2 by means of a section 3 of a coaxial light guide comprising an inner 4, an additional 5 and an outer 6 core. The output of a section of each core is optically coupled to the input of the corresponding core of the next

sections by means of focusing elements 7. The outer core 6 is optically connected with the additional core 5 by means of a translucent coating 8. In the inner core of the last section

there is a radiation absorber 9. There is no optical connection between the inner core k and the outer core b.

With no smoke or temperature gradient at controlled points

Of the space, the light from the radiation source 1 goes only through the internal core and enters the radiation absorber 9. At the same time, there will be no signal at the receiver input,

When smoke appears or a gradient of temperature in the rupture of the coaxial fiber, the radiation enters the input of the additional core 5 of the section of the coaxial fiber 3s following the j1 rupture, in which there is smoke. Thanks to the focusing elements 7 of the additional core 5, the radiation passes through it to the radiation receiver 2. However, it comes to the receiver only. part of the luminous flux due to the fact that the semi-transparent coating 8 directs part of the luminous flux into the outer core 6, through which the radiation also reaches the receiver 2. Moreover, since there is no optical connection between the inner core and the outer core 6, it can radiation from the additional core 5 only is transmitted due to translucent coatings 8. Thus, the luminous flux caught in the additional core 5 is further divided in each section and goes through two cores, moreover, since the separation occurs from the law, then the ratio of the light fluxes at the outlet 5 and further 6 lived outer coaxial waveguide section the latter can be easily on; thinning the number of sections traversed radiation waveguide 3, i.e. determine the location of the phenomena of smoke or temperature gradient. For example, if the transmission coefficient of the translucent coating 8 is chosen to be equal to the reflection coefficient and equal to 0.5, then the amount of light at the output of the additional core 5 will be. ; E (0.5 ;, the amount of light at the output of the additional core 5 of the coaxial fiber; 0 E is the amount of light entering the input of the additional core 5 of the fiber when smoke appears; n is the number of sections 3 of the coaxial fiber from the discontinuity, where wils smoke up to radiation receiver 2. The amount of light E at the output of the outer core 6 of the coaxial light guide is equal to EI (-0.5Г Then the ratio of the signals at the input of receiver 2 is equal to EB from which it is analyzed; its device determines the number of sections 3 from the gap, where the wils smoke; up to the receiver 2 F EC and, accordingly, a gap in which the smoke is wielded. The proposed technical solution of a smoke sensor compared with a known sensor with a coaxial fiber will completely unify the sections of the fiber and their installation. Moreover, compared with the prototype, it will be used as an analyzing device of the receiver radiation simple electronic circuits and eliminate the use of spectral instruments, expensive and difficult to operate.

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Claims (1)

(54> (57 ·) SMOKE SENSOR., Containing a radiation source, sequentially installed with gaps at controlled points in the space of the coaxial fiber section, each of which contains focusing elements, an inner and an outer core, with the inner end of the first section facing the input end to the radiation source, and the outer core of the last section - to one input of the radiation receiver, the output of which is connected to the detector, the radiation absorber located in the inner core of the last section of the coaxial fiber, I distinguish In order to increase its informativeness, an additional core is inserted into each section of the coaxial fiber, placed coaxially with the external and internal veins, the output end of the additional core of each section is optically connected to the input end of the additional core of the next section and to its outer residential section, the radiation receiver is made in the form of an analyzer of the ratio of the values of the light flux, the second input of which is connected to the output end of the additional core of the last section, and the input end of the external core of each the projection is provided with a translucent coated