RU2199103C1 - Device for automatic sampling - Google Patents

Abstract

FIELD: equipment for remote automatic sampling in ground atmospheric layer. SUBSTANCE: invention can also be used to evaluate content of impurities in air and dynamics of their propagation. Target of invention lies in provision for automatic taking air samples at various altitudes which enables authenticity of evaluation of condition in ground atmospheric air and operational reliability of device to be raised. Device for automatic sampling is made up of altitude column, endless tape, samplers and system of liquid draining communicating through shut-off and control equipment with samplers and tankaccumulator. Pistons with floats installed in samplers go down while liquid is drained through system of liquid draining to tank-accumulator. With this air is sucked into spaces located pistons through conical bell mouths. In extreme low position of piston in body bell mouth is shut off by end-piece. EFFECT: raised authenticity of evaluation of ground atmospheric air and operational reliability of device. 1 cl, 3 dwg

Description

 The invention relates to techniques for remote automatic sampling of air in the surface layer of the atmosphere and can be used to assess the content of pollutants and the dynamics of their distribution in areas adjacent to land-based stationary and mobile sources of environmental pollution.

 A device for sampling air in the surface layer of the atmosphere, comprising a pilot balloon, a variable-volume chamber with a limiter and intake openings, a shut-off and release device, a piston is installed in the variable-volume chamber, and a sleeve is placed above the intake openings, and the release device is made in in the form of a plate with a hook and a halyard, the locking device is made in the form of stops connected to the piston using flexible connections [1].

 However, this device allows you to take air samples only at one point of the surface layer of the atmosphere, and, therefore, it is impossible to obtain a reliable estimate of the state of the atmosphere in the territory adjacent to ground-based sources of pollution, while the reliability of the design of the device is low.

 Known for the closest set of features is a device for automatic sampling, containing a sampler in the form of a cylindrical body with a drive piston installed in it, the drive of which is made in the form of a rod connected to a parachute. The piston is connected by flexible coupling to the cavity inlet plug formed by the inner surface of the cylindrical body and the piston surface. This cavity is in communication with the fitting for the withdrawal of the sampled air sample. The inlet of this cavity is a speed adjuster [2].

 However, despite the fact that this device allows automatic sampling of air, sampling by such a device is carried out only at one specific point in the surface layer of the atmosphere, and, therefore, it is impossible to obtain a reliable estimate of the state of the atmosphere in the territory adjacent to ground-based sources of pollution when this reliability of the design of the device is low.

 The objective of the invention is to enable automatic sampling of air in the surface layer of the atmosphere simultaneously at different altitude levels, which allows to increase the reliability of assessing the state of the surface layer of the atmosphere, as well as improving the reliability of the device.

 The problem is achieved in that in a device for automatic sampling containing a sampler in the form of a cylindrical body with a drive piston installed in it, connected by flexible connection with a plug of the cavity inlet formed by the inner surface of the cylindrical body and the piston surface in communication with the nozzle for output The selected air sample, as well as the speed controller, distinguishing features from the prototype is that it is equipped with a high-strut with a lifting fur low in the form of an endless tape mounted on a drive and tension drums, mounted on a rack, as well as a storage tank with an outlet valve and additional samplers, fixed, like the main one, on an endless tape using detachable fastening elements and equipped with floats attached to the surfaces pistons opposite to the cavities of the cylindrical housing with inlet openings and forming, together with the inner surfaces of the cylindrical housing, cavities with fittings for liquid, periodically communicating with the outlet valve of the storage tank and flexible hoses with speed adjusters for sampling in the form of needle valves communicated with a common liquid pipe through a shut-off valve with a storage tank, attached to an endless belt, with each sampler equipped with an inlet a branch pipe with a conical bell through which a flexible connection is passed, connected to a plug made with a taper corresponding to the taper of the conical bell.

 It is advisable that the drive drum of the lifting mechanism was made with a safety cargo brake, and the tension drum is spring-loaded.

 Placing the samplers on a high rack, remote from each other at a distance, and ensuring the general control of sampling by all samplers, can simultaneously automatically take air samples in the surface layer of the atmosphere at different altitude levels, which improves the reliability of assessing the state of the surface layer of the atmosphere.

 Figure 1 shows the design of a device for automatic sampling; figure 2 - sampler filled with liquid; figure 3 is the same, in the case of forced supply of a sampled air sample to a gas analyzer.

 The device for automatic sampling consists of a high rack 1, fixed by braces 2 vertically on the ground. An endless lifting belt 3 is mounted on a high rack 1, worn on a drive drum 4 mounted on a rack 1 with a safety load-holding brake 5 and on a drum 7, spring-loaded with a spring 6. Detachable elements 8 are mounted on the endless belt 3 for mounting the samplers 9 on it.

 The sampler 9 consists of a cylindrical body 10 in which a piston 11 is mounted. At one end of the body 10 there is a nozzle 12 for inlet of the selected sample, and at the opposite end there is a nozzle 13 for liquid inlet and outlet. To the surface of the piston 11 facing the nozzle 13, a float 14 is fixed, forming together with the inner surface of the piston 10 a cavity 15 for liquid. A shut-off valve 16 is installed on the fitting 13. The fitting 13 has the possibility of connecting, through the flexible tube 17, through the outlet valve 18 to the fluid storage tank 19, as well as to the flexible hose 20 of the common fluid drainage system, consisting of a common pipeline mounted on an endless tape 3 fluid outlet 21, made flexible, communicated through tees 22 and elbow 23 with flexible hoses 20, on which needle valves 24 are installed, which are sampling rate adjusters, the pipe 21 is connected through a shut-off valve 25 to the storage tank 19 elem.

 In each sampler 9, the nozzle 12 is in communication with the cavity formed by the inner surface of the cylindrical body 10 and the surface of the piston 11 and with a pipe with a conical socket 26. The piston 11 is connected by a flexible connection 27 passed through the socket 12, the pipe with a socket 26 and bearing a plug 28, made with a taper corresponding to the conical bell 26. The length of the flexible connection 27 corresponds to the distance from the surface of the piston 11 at its extreme position in the cylinder of the sampler 10 to the narrowest hole of the conical bell 26. N and a cylindrical body 10 of each sampler 11 is equipped with an additional fitting 29 with a plug 30. An additional fitting 29 is designed to communicate with the sampled air sample to the gas analysis device 31 through the intake adapter 32. In the case of forced supply of the sampled air to the gas analysis device 31, through the nozzle 13 when the shut-off valve 16 is open, a rigid rod 33 is inserted, with which the piston 11 is pushed with the float 14 all the way into the upper end of the cylindrical body 10. On the flexible hoses 20 topics of general liquid discharge mounted blanking plugs 34.

 A device for automatic sampling works as follows. On the ground, in the common pipeline 21 with flexible hoses 20, liquid is poured from the valve 18 of the storage tank 19 with the shut-off valve 16 open. As the liquid drainage system is filled, the free exits of the flexible hoses 20 are blocked by plugs 34.

 Rack 1 with an endless tape 3 and a filled liquid drainage system is installed vertically in the investigated place on the ground and fixed in this position by braces 2.

 Alternately, the samplers 9 are filled with liquid as follows. A flexible tube 17 is connected to the nozzle 13 with the open valve 16 connected to the outlet valve 18 of the storage tank 19. When the outlet valve 18 is open, the liquid enters through the nozzle 13 into the cavity 15 of the samplers 9. When the entire cavity 15 is filled with liquid, the shut-off valve 16 is closed and the flexible tube 17 is disconnected from the nozzle 13. The liquid-filled samplers 9 are alternately secured using detachable fasteners 8 located on the tape 3 at a certain distance from each other, depending on the tasks of the research Nia dynamic processes impurity distribution in the atmospheric air layer. After attaching the samplers 9, the output of the corresponding flexible hose 20 is freed from the stopper plug 34 and is put on the fitting 13. The shut-off valve 16 opens. Samplers 9 are mounted on an endless tape 3 at an accessible distance from the ground, then by rotating the drive drum 4, the tape with samplers 9 rises up and loose detachable fastening elements 8 are brought in, after which the drive drum 4 stops and stops with a safety load-holding brake 5.

 After installing all the samplers 9 on the tape 3, the device is ready for air sampling. With the shut-off valve 19 open on the common pipe 21, fluid from the cavities 15 of the samplers 9 through the fittings 13 and the needle valves 24 through the flexible hoses 20 is routed to the common pipe 24 and is drained from it into the storage tank 19. The pistons 11 with floats 14 are lowered in cylindrical bodies 10 at the same time, and the freed cavity above the pistons 11 through the conical sockets 26 fills the air. The sampling rate is determined by the rate of fluid outflow from the cavity 15 by a needle valve 24. The needle valves 24 of all samplers are configured for the same throughput taking into account the pressure in the fluid drainage system. The piston 11, dropping, drags through the flexible connection 27 the plug 28, which at the extreme lower position of the piston 11 in the housing 10 completely blocks the narrow opening of the conical socket 26 due to the same taper. This means that sampling simultaneously at different levels from the surface of the earth is finished. Then the shut-off valve 16 is closed.

 To analyze the selected air samples, the samplers 9 are alternately removed in the reverse order of their installation.

 The content of impurities in the air of each sample is measured through the nozzle 29, having previously released it from the plug 30, by connecting the air intake adapter 32 from the gas analyzer 31 to the nozzle 29. In the case when it is necessary to force the selected air sample into the gas analyzing device 31, through the nozzle 13 at open shutoff valve 16, insert a rigid rod 33, which push the piston 11 with the float 14 until it stops in the upper end of the cylindrical body 10.

 Thus, this design of the device provides the ability to automatically take air samples in the surface layer of the atmosphere simultaneously at different altitude levels. This allows you to reliably determine the content of impurities and their dynamic distribution in the surface layer of the atmosphere in areas adjacent to land-based stationary and mobile sources of environmental pollution.

Sources of information
1. Copyright certificate of the USSR 887995, MKI G 01 N 1/24, 1980

 2. Copyright certificate of the USSR 1493919, MKI G 01 N 1/22, 1987

Claims (2)

 1. A device for automatic sampling, containing a sampler in the form of a cylindrical body with a drive piston installed in it, connected by means of a flexible connection with a plug of the cavity inlet formed by the inner surface of the cylindrical body and the piston surface in communication with the fitting for outputting the selected air sample, and also a speed adjuster, characterized in that it is equipped with a high-rise stand with a lifting mechanism in the form of an endless belt mounted on a drive and tension bar Abanas, mounted on a rack, as well as a storage tank with an outlet valve and additional samplers, fixed, like the main one, on an endless belt by means of detachable fastening elements and equipped with floats attached to the surfaces of the pistons opposite to the cavity of the cylinder with inlet openings and forming together with the inner surfaces of the cylindrical cavity bodies with liquid fittings periodically communicating with the outlet valve of the storage tank and flexible hoses with adjusters growth of air sampling in the form of needle valves connected to a common fluid drainage pipe mounted on an endless tape through a shut-off valve to the storage tank, each sampler equipped with a conical pipe connected to the inlet through which a flexible connection is connected, connected to a plug made with a taper corresponding to the taper of the conical bell.  2. The device according to claim 1, characterized in that the drive drum of the lifting mechanism is made with a safety load-lifting brake, and the tension drum is spring-loaded.

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