RU131616U1 - DEVICE FOR RADIATION OF CURRENT MEDIA - Google Patents

Abstract

A device for irradiating current media, comprising a cylindrical chamber with nozzles for supplying and discharging the current medium, a radiation source containing an emitter coaxially located in the chamber, a sensor, a control panel operably connected to the sensor, the nozzles being spaced apart in height relative to one another, different the fact that the camera is made in the form of two cylindrical coaxial pipes, the volume between which is divided into equal sections by radial partitions and connected to a differential pressure sensor, in the inner tube is connected with the space outside the chamber, the emitter is mounted on the axis of the chamber with the possibility of movement along this axis, the diameter of the outer tube of the chamber D satisfies the relation D <D + 2d, where D is the diameter of the inner tube, d is the radiation path in the irradiated liquid medium, the inlet pipe the camera is located on the camera axis and contains a mixer of the current medium, as a sensor on the outside of the camera, an annular sectioned radiation sensor is installed coaxially with it, which can be moved along the camera axis, the power supply unit is connected to a teacher, with a transmitter control panel, with a differential pressure sensor, with a ring sectioned radiation sensor and with a recorder connected to a differential pressure sensor, a ring sectioned radiation sensor and a transmitter panel.

Description

The utility model relates to the design of installations for irradiating current media and can be used in installations designed to sterilize flowing liquids, activate chemical reactions in flowing solutions, and nuclear conversion of flowing radioactive waste used, in particular, in medicine, food, chemical and nuclear industries .

For irradiation, the current medium is passed through a chamber in which the flow is cylindrical. Typically, the medium flows through an annular gap formed by the camera body and the emitter. The flow rate determines the residence time of the current medium in the irradiation zone. The amount of radiation absorbed by the current medium during the irradiation process at a given radiation flux density on its surface is directly proportional to the irradiation time and, therefore, inversely proportional to the flow rate of the current medium.

To irradiate the current medium, various types of radiation are used: electromagnetic, for example, ultraviolet, X-ray or gamma radiation, as well as neutron.

Radiation sources provide the required flux density on the surface of the current medium. To uniformly irradiate the flow of the current medium of a cylindrical shape, the radiation pattern of the source has a symmetry axis, and the source is installed inside the flow of the current medium so that the axis of symmetry of the radiation pattern coincides with the axis of the stream. Quartz lamps, ampoule gamma sources, X-ray and neutron portable generators, etc. are used as emitters.

The flow of the current medium in the chamber should be uniform in space and constant in time. Otherwise, despite the symmetry of the radiation flux, irradiation of the medium becomes uncontrolled. The heterogeneity and inconstancy of the flow occurs when the flowing medium consists of several fractions that differ in their properties, and / or in the presence of a gas fraction. The violation of homogeneity is manifested in the form of a distribution of the density of the medium in the irradiated section and is caused mainly by the action of the gravitational force, especially in the case of a horizontal chamber or centrifugal force in the case of a circular flow.

It is known "Device for the processing of rare-metal concentrates" [Application for invention RU 95111909, IPC: C22B 3/02, 06/27/1997. Analogue], containing a pulsed optical radiation source, consisting of a radiator, a capacitor energy storage device, a control panel combining source systems with a control connection, a pump with a drive, an autoclave leaching apparatus, a cylindrical chamber with pulp supply and discharge pipes with a coaxially emitted emitter , a level sensor located at the inlet of the outlet pipe, and the cross-sectional area of the supply pipes and nozzles made the same and more than the cross-sectional area of the diametrical coaxial gap between the chamber and the emitter, while the capacitor energy storage device is multi-sectional with the number of sections determined by the ratio h = N _о / N ₁ , where N _о is the number of pulses per minute, which provides the necessary performance and sufficient quality of activation, N ₁ - the maximum allowable the number of pulses per minute for the selected type of capacitors included in the capacitor bank, and the device is equipped with a switch sections of the drive to the emitter, characterized in that the device contains a circulation circuit p, consisting of a pump to an actuator, the flow control system of the pulp, conduits volume defined by the relation V = V _{n n} / h, where V _n - amount of the coaxial cavity between the emitter and the camera, n - experimentally or clearance certain number of irradiation pulses, with which achieves the maximum degree of leaching of raw materials.

The disadvantages of the analogue are: the lack of control of the dose of radiation absorbed by the pulp, due to the lack of control of the distribution of its density over the cross section of the pipeline and the time of its exposure; the inability to service and replace the emitter without stopping the flow of pulp, due to the fact that the pulp flows between the wall of the emitter and the wall of the cylindrical chamber.

It is known "Device for sterilizing a liquid" [Application for invention RU 94009348, IPC: C02F 1/32, 05/10/1997. Prototype], comprising a cylindrical chamber with nozzles for supplying and discharging the current medium, an optical radiation source containing an emitter coaxially located in the chamber, a sensor, a control panel operably connected to the sensor and a pump with a drive, while the nozzles are spaced apart in height relative to one another characterized in that the diameter of the chamber D _{to is} selected from the relation D _to = D _and + 2l, where D _and is the diameter of the emitter, l is the calculated or experimentally selected value of the path of radiation in the treated liquid, at which m, the disinfection effect of this liquid is achieved, the radiation source contains a pulsed gas-discharge emitter and a pulsed capacitor power source, the cylindrical chamber is horizontal, the inlet and outlet nozzles are located at right angles to the chamber axis along one vertical line, while the inlet and outlet nozzles are made with sections extending from the inlet and outlet pipes to a size that matches the length of the irradiated part of the chamber, and the width of the cross section of the pipes at the output of the inlet pipe and at the input e of the outlet pipe is made no more than (D _to -D _and ), and the areas normal to the axis of the sections of the inlet and outlet pipes along their entire length are made equal and equal to the area of the normal section of the inlet and outlet pipes, the level sensor is located in the inlet section of the outlet pipe, this power supply is configured with the number of sections of multi-part, determined from the relation n = N / N _1, where N - number of pulses per minute, providing the necessary performance and desired quality of cleaning, N ₁ - maximum number of pulses minute for the type of capacitors, the apparatus is provided with a switch drive sections to pulse the emitter.

The disadvantage of the prototype is the lack of control of the dose of radiation absorbed by the liquid, due to the lack of control of the spatial distribution of the density of the liquid over the cross section of the pipeline and the time of its irradiation.

The technical result of the utility model is to control the dose of radiation absorbed by the current medium due to: increasing the spatial uniformity of the flow of the current medium at the device inlet, dividing the pipeline into sections, measuring radiation absorbed by the current medium in different parts of the cross section of its flow, and monitoring the exposure time current environment by determining the speed of its flow through the device.

The technical result is achieved in that a device for irradiating current media, comprising a cylindrical chamber with nozzles for supplying and discharging the current medium, a radiation source containing an emitter coaxially located in the chamber, a sensor, a control panel operably connected to the sensor, while the nozzles are spaced apart one height relative to the other, the camera is made in the form of two cylindrical coaxial pipes, the volume between which is divided into equal sections by radial partitions and connected to differential m with a pressure sensor, the inner tube is connected with the space outside the chamber, the emitter is mounted on the axis of the chamber with the ability to move along this axis, the diameter of the outer tube of the chamber D _k satisfies the ratio D _to <D _W + 2d, where D _W is the diameter of the inner pipe, d - range of radiation in an irradiated liquid medium, the inlet of the chamber is located on the axis of the chamber and contains a mixer of the current medium, an annular sectioned radiation sensor with the ability to move along the axis of the chamber is mounted coaxially with the outside of the chamber, block The device is connected to a radiator, to a transmitter control panel, to a differential pressure sensor, to a ring-shaped sectioned radiation sensor and to a recorder connected to a differential pressure sensor, a ring-shaped sectioned radiation sensor and a transmitter control panel.

The essence of the utility model is illustrated in the drawing, where 1 is the camera; 2 - external coaxial pipe; 3 - inner coaxial pipe; 4 - current medium flowing between the inner 3 and outer 2 coaxial pipes; 5 - a cavity inside the camera associated with the space outside the camera 1; 6 - emitter; 7 - ring sectioned radiation sensor; 8 - a recorder for recording the readings of the differential pressure sensor 15 and the readings of the annular sectioned radiation sensor 7; 9 - control panel emitter 6; 10 - power supply unit, providing power to the emitter 6, an annular sectioned radiation sensor 7, a differential pressure sensor 15, a transmitter control panel 9 and a recorder 8; 11, 12 - inlet and outlet nozzles of the chamber 1; 13 - a mixer of the current medium located in the inlet pipe 11 of the chamber 1; 14 - flow direction of the current environment; 15 - differential pressure sensor; 16 - electric cables; 17 - radial partitions dividing the annular space of the chamber 1 into equal sections.

The device consists of a camera 1, an emitter 6, a ring sectioned radiation sensor 7, a recorder 8, a control panel of the emitter 9, a power supply 10, electrical cables 16.

The chamber 1 includes two cylindrical coaxial pipes 2 and 3, an inlet 11 and an outlet 12 nozzles, a mixer 13 installed inside the inlet nozzle 11, radial partitions 17 installed inside the chamber volume between the tubes 2 and 3 and a differential pressure sensor 15, which hermetically connected to the volume occupied by the current medium, through the through holes in the pipe 3 and pipelines.

For the manufacture of cylindrical coaxial pipes 2 and 3, a sufficiently transparent fraction of the radiation of the emitter 6 is used. In the case of ultraviolet radiation, this can be, for example, quartz.

The spatial homogeneity of the flow of the current medium at the inlet to the chamber 1 is provided by a mixer of the current medium 13 installed inside the inlet pipe 11, and the location of the inlet pipe 11 on the axis of the chamber 1. Radial partitions 17 installed inside the volume between the pipes 2 and 3 prevent the occurrence of a vortex flow of the current environment 4 around the axis of the chamber 1, leading to radial stratification of the flow of the multiphase flowing medium 4 due to the action of centrifugal force. The vertical arrangement of the chamber 1 prevents stratification of the flow of the multiphase flowing medium 4 along the diameter of the chamber 1 due to the action of gravity in the case of a horizontal arrangement of the chamber 1.

The mixer 13 can be either active or passive. An active mixer is a mixing device, for example, of a rotary type (Patent RU 2186615, IPC: B01F 7/00, 08/10/2002), using an external energy source. A passive mixer is made of spatially distributed barriers in the flow path, for example, in the form of spherical or elliptical balls (US Patent No. 6272934 B1; IPC: G01F 1/74; 08/14/2001), and / or perforated plates.

An annular sectioned radiation sensor 7 is mounted on rails (not shown in the drawing) and can move along the axis of the camera 1. The type of sensor is determined by the type of radiation and can be made in the form of a set of identical sensors installed around the circumference around the camera 1, or in the form of a single position sensitive sensor. The output of the annular sectioned radiation sensor 7 is electrically connected to the input of the recorder 8 using electric cables 16. The recorder 8 displays the intensity of radiation transmitted through the current medium 4 obtained from the sections of the annular sectioned radiation sensor 7 in various parts of the cross-section of the chamber 1, providing control of flow uniformity (current medium density) and absorbed energy in these parts.

The differential pressure sensor 15 is hermetically connected to the volume occupied by the flowing medium using the through-holes in the pipe 2 and is electrically connected to the recorder 8 using electric cables 16. The principle of the differential pressure sensor 15 is based on the fact that the pressure drop in the fluid flow on the measured plot is proportional to the square of the fluid flow rate. The readings of the differential pressure sensor 15 are received in the recorder 8, where the readings are processed using a calculating device and software. The result of the treatment is the effective exposure time of the current medium.

The registrar 8 receives data from the differential pressure sensor 15 and from the sections of the annular sectioned radiation sensor 7 using electric cables 16.

The recorder 8 is connected via electric cables 16 to a differential pressure sensor 15, to sections of a ring sectioned radiation sensor 7 and to a transmitter control panel 9, processes data from sensors 15 and 7, and controls the operation of the transmitter 6 by means of a control panel 9. For this the recorder 8 is equipped with a calculating and solving device and software for calculating the density of the current medium 4 and the effective time of its irradiation, as well as an electrical communication device with a control panel 9 for turning on and off the emitter 6 and controlling in this way the degree of irradiation of the current medium.

The emitter 6 is installed in the cavity 5 of the chamber 1 on its axis. For this, the emitter 6 is mounted on the end of the rod (not shown), which can move inside the bushings (not shown), mounted on the camera body 1, along its axis. The location of the emitter 6 on the axis of the chamber 1 provides axial symmetry of the spatial distribution of radiation intensity. The emitter 11 may be, for example, a quartz lamp, an x-ray or neutron portable generator.

The power supply 10, the control panel of the emitter 9, the annular sectioned radiation sensor 7 and the recorder 8 are located outside the camera 1 and are connected electrically to each other using electric cables 16.

For irradiation, the camera is installed on the pipeline used to pump the current medium 4, using the inlet 11 and outlet 12 nozzles stationary, or for the duration of the irradiation, using flexible hoses. In the case of a flowing medium having a fractional composition and / or a gas fraction, the chamber is mounted so that its axis occupies a vertical position.

The device operates as follows.

The power supply unit 10 provides power to the emitter 6, the annular sectioned radiation sensor 7, the differential pressure sensor 15, the recorder 8 and the transmitter control panel 9 using electric cables 16. The current medium 4 flows into the inlet pipe 11, flows through the gap between the pipes 2 and 3, and flows through the pipe 12. The flow of the current medium 4 in the gap between the pipes 2 and 3, to which the differential pressure sensor 15 is connected, acts on the differential pressure sensor 15, the readings of which are entered in the register p 8 using electric cables 16. Being in the gap between the pipes 2 and 3, the current medium 4 is exposed to radiation from the emitter 6 located on the axis of the chamber 1. During the irradiation, the radiation from the emitter 6 is partially absorbed by the current medium 4, and partially exits the chamber 1 where it lands on a ring sectioned radiation sensor 7, the readings of which are entered by the recorder 8 using electric cables 16. The registrar 8 calculates the energy of the radiation absorbed by the current medium 4 and controls it using electric cables 16 turning on and off the emitter 6, thus, regulating the degree of its exposure.

Claims (1)

A device for irradiating current media, comprising a cylindrical chamber with nozzles for supplying and discharging the current medium, a radiation source containing an emitter coaxially located in the chamber, a sensor, a control panel operably connected to the sensor, the nozzles being spaced apart in height relative to one another, different the fact that the camera is made in the form of two cylindrical coaxial pipes, the volume between which is divided into equal sections by radial partitions and connected to a differential pressure sensor, in the inner tube is connected with the space outside the chamber, the emitter is mounted on the axis of the chamber with the possibility of movement along this axis, the diameter of the outer tube of the chamber D _K satisfies the relation D _K <D _BT + 2d, where D _BT is the diameter of the inner tube, d is the range of radiation in the irradiated liquid medium, the inlet of the chamber is located on the axis of the chamber and contains a mixer of the current medium, as a sensor outside the chamber, an annular sectioned radiation sensor is installed coaxially with it and can be moved along the axis of the chamber, the power supply unit of the device is connected ene with emitter with remote control transmitter, a differential pressure sensor, radiation sensor annular partitioned and recorder connected to a differential pressure sensor, radiation sensor sectionalized annular panel and emitter control.

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