RU2687937C1 - Method of improving functional properties of industrial rubber articles by treatment in microwave electromagnetic field - Google Patents

Abstract

FIELD: technological processes.SUBSTANCE: invention relates to electrotechnical processes of modifying dielectric materials and can be used in production of sealing elements of pipeline and shut-off valves in power and transport machine building, to sealing characteristics and durability of which there are high requirements. According to this method, products are supplied to working zone, in which microwave electromagnetic field is generated, processed by microwave electromagnetic field of article and removal of processed article from working zone, field is generated by means of emitters in the form of horn antennas, and degree of its effect is regulated. At that, in addition, receiving antenna connected to ballast load is used, processed item is placed between radiating and receiving antennae, during primary processing of new rubber seals as the final process operation, specific radiation power is set equal to 1.5 W/cmand holding seal at given power for 1.5–1.6 minutes. Radiation pattern of the emitting antenna is formed such that the absorbed power in all sections of the circular article is uniform.EFFECT: increased elasticity of rubber technical articles leading to improvement of sealing properties and increase of their service life.1 cl, 6 dwg

Description

The invention relates to electrotechnical processes of modifying dielectric materials, namely to the finishing and restorative treatment of rubber products and can be used in the manufacture and repair of pipeline and valves in power engineering and transport engineering, to the sealing characteristics and durability which are subject to increased requirements.

There is a method of processing waste tires and / or rubber products and a device for its implementation (patent RU No. 2361731, IPC F23G 5/027). The method is intended for processing worn tires and / or rubber products, includes automatically loading them into the working volume of a device for pyrolysis, pyrolysis by microwave heating, removal of gaseous products, and automatic unloading of solid residue. The method is carried out cyclically by cyclic automatic loading, pyrolysis and unloading of solid residue, while pyrolysis of tires and rubber products is carried out by processing them in a device that provides pyrolysis in the mode of standing waves with uniform distribution of the microwave field in the working volume of the pyrolysis chambers by microwave heating with a frequency microwave radiation of 2.45 GHz under the conditions of supplying superheated steam, which is supplied when the temperature in the pyrolysis chambers reaches 100 ° C, while maintaining excess The pressure in the pyrolysis chamber up to 5 kPa by controlling the flow rate of the gaseous products formed. A variant of the method is characterized in that the pyrolysis of worn tires in the pyrolysis chambers is carried out individually, carrying out their automatic loading into the pyrolysis chambers of the device, providing a mode of standing waves. When loading worn tires and / or rubber products weighing 100-800 kg into the working volume of a single pyrolysis chamber, before starting pyrolysis, the power of microwave emitters is selected from the interval of 1100-14000 kW, and the process is carried out for 3-5 minutes.

The main disadvantage of this method is the complete destruction of rubber products due to microwave dielectric heating, which does not allow it to be used for finishing products or restoring their sealing ability. At the indicated microwave power levels, intensive heating of the product volume with breaking of mechanical and chemical bonds occurs, the material decomposes to form gaseous products and a solid residue.

There is also known a method of processing rubber and organic waste and a device for its implementation (patent RU No. 2321492, IPC C10G 1/10), according to which decomposition products are divided into solid and gaseous, rubber and organic waste processing is carried out in a reactor by direct thermal effects on them a source of infrared radiation in the circulating medium at a rate 0,01-3,5 m ³ / min flow of water vapor and / or gas to produce carbon black solid, liquid and gaseous fraction agricultu Mykh waste. At the same time, water vapor and / or gas is heated in a convector before being fed into the reactor, and cooling of solid degradation products in the first reactor is carried out with water vapor, in a superheated state it is fed to the second reactor, which performs the initial heating of the waste.

The disadvantages of this method is the following. The method can be used in the chemical, petrochemical and petrochemical industries, utilities for thermal decomposition in the vapor-gas medium and the separation of decomposition products into solid and gaseous. In accordance with the purpose for processing waste and used technological regimes that provide heating of the object of impact, and operations, the method cannot be used for processing products to improve their functional characteristics, since it causes destructive changes in the material.

The closest analogue to the claimed invention is a method and device adjustable non-pyrolytic regenerative processing of organic materials (patent RU №2106248, IPC HB 17/00, HB 6/64). This invention relates to the recovery treatment of organic materials using microwave radiation, for example, when extracting oil from oil shale or when processing waste. The method includes feeding organic materials into a microwave chamber in which microwave radiation is generated, treating organic material with microwave radiation, and removing the processed organic material from the chamber. When implementing the method, microwave radiation is generated in the chamber by means of generators connected to the antenna array, followed by transmission of the generated radiation to reflectors focusing the radiation according to a given radiation pattern, the reflectors are arranged in such a way that they ensure uniform distribution of radiation in the chamber, and the degree of radiation effect on the organic material The chamber is regulated, and the supply and removal of organic material is carried out continuously. To form a radiation pattern using parabolic reflectors, and form a circular radiation pattern. Processing of organic material is carried out in successively installed microwave chambers. The position of the antenna relative to the reflectors is adjusted. The method and apparatus of this invention may be applicable to an almost unlimited range of organic materials. It is believed that the effect of microwave radiation leads to the separation of weak material bonds in long-chain molecules, which contributes to the restoration of these molecules into simpler forms. In essence, it is a depolymerization process. The process is controlled to avoid pyrolysis of organic material. Those. This process is not a process of thermal decomposition or incineration of the material.

The disadvantages of the method is the following. The established technological regimes lead to non-thermal destruction of the material with the release of easily recyclable components from it. The process can be implemented in a special microwave chamber, which does not allow processing of large-sized products such as sealing rings of trunk pipelines connections due to the uneven distribution of the microwave electromagnetic field strength in the chamber due to the re-reflection from the walls. Due to this reason, individual zones of large-sized products are exposed to different intensities. Due to these reasons: the destructive changes and the unevenness of the impact of the method cannot be used to process rubber products in order to increase their elasticity, as well as to restore used products that have lost the required elasticity of products, especially large diameter o-rings.

The technical problem of the present invention is to improve the sealing properties and increase the durability of the elements of pipeline and valves, for example, in natural gas transmission systems operating under conditions of temperature and pressure gradients, as well as other environmental influences, by increasing the elasticity of new products through short-term processing in the microwave electromagnetic field. In modern machine building and power engineering, as well as in power engineering, for example, in energy carrier transportation systems, a significant amount of structural elements falls on pipeline valves: switches, fittings, taps, chokes, valves, seals, etc. The main requirement for these structures is to ensure the durability of maintaining the tightness of the joints or flow control systems of the moving medium (liquid or gas). At the same time, the most severe conditions are sealing rubber products of structural elements of the natural gas transmission systems (compressor stations, control systems, heating and cooling systems, pipe splitters, etc.), since they must ensure the tightness of the connections with long-term influence of external temperature and chemical factors associated with both natural effects and the effects of chemical elements inherent in natural gas, enhanced by high E pressures. In pipeline gas distribution systems, the control level of pressure of the medium at which tightness must be ensured is 150 atm. when working - up to 100 atm. Tightness of connections and flange joints is ensured by annular rubber seals of both round and profile cross-section with a diameter of up to 1500 mm.

The vast majority of domestic manufacturers of pipe fittings and control units make rubber seals of 2-3 groups with technical requirements according to GOST 18829-73. In accordance with this standard, the full specified service life of these seals is no more than 5 years. After this period, replacement of the seal is necessary for reliable equipment operation.

Gas-turbine gas-pumping units of the block-container type are equipped with a multi-stage air-cleaning device (cyclone and fine cleaning), which is the main element of the air preparation system for gas-turbine engines, which significantly affects the engine durability and its efficiency. During operation, due to the influence of external factors and the natural process of aging of the material, there is also a loss of elasticity of the rubber sealing rings of the multicyclones of the air-cleaning device. The loss of elasticity and cracking contribute to reducing the tightness of the joints and the deterioration of the multicyclone, violation of passport data. In the future, a decrease in the degree of purification of the incoming air and a decrease in its quantity due to etching through the seals causes a violation of the stable operation of the gas pumping unit and the wear of its parts.

Rubber, which is a composite material in the form of synthetic rubber with carbon filler, provides a technical specification for the combination of elastoplastic characteristics, which, when tightening the joint, form a tightness of the joint. Under the influence of external factors, destruction of the rubber composite occurs, which is manifested in a decrease in the plasticity of rubber due to the loss of fluid components, which is accompanied by a decrease in the volume of the rubber matrix, delamination, and local increase in hardness. Ultimately, the seal loses tightness, which can cause gas leaks and contribute to an emergency. Due to the general deterioration of the environmental situation, such violations may occur earlier than the prescribed period when new sealing elements are not prepared for replacement.

The problem is solved by the fact that in the method of controlled non-pyrolytic processing of organic materials, in particular, rubber sealing products of an annular form, including supplying products to the working area in which the microwave electromagnetic field is generated, processing the microwave electromagnetic field of the product and removing the processed product from the working area, wherein a microwave electromagnetic field is generated by radiators in the form of horn antennas, with the degree of electromagnetic field impact on the product They additionally use a receiving antenna connected to the ballast load, the workpiece is placed between the radiating and receiving antennas, during the initial processing of new rubber technical seals as a final technological operation set the specific radiation power equal to 1.5 W / cm ³ and withstand the seal at this power within 1.5-1.6 minutes, while the radiation pattern of the radiating antenna is formed in such a way that the absorbed power on all parts of the ring product is equal to omeric

The technical result of the proposed solution is to significantly increase the elasticity of the new rubber sealing elements, which prolongs their reliable operation while maintaining the tightness of the joints and connections. As a result, the cost of replacing failed seals is reduced, coupled with the need to shut off the relevant section of the pipeline and gas release.

In the modern rubber industry, automated installations and rubber vulcanization lines in the ultrahigh-frequency (microwave) electromagnetic field or under the combined effect of the microwave and infrared heating fields [http://elmash-micro.ru/vulkaniz., Http: //www.polymermachgroup. com / wave.html].

The use of microwave energy allows to intensify the process of vulcanization and to improve the quality indicators of rubber products, which is determined by the advantages of microwave processing, which allows for uniform volume heating of the object. This allows you to predict the possibility of regulating the characteristics of rubber seals by microwave exposure to them. However, the currently known areas of application of microwave processing are mainly related to thermal or non-thermal modifying effects on the original components of dielectric materials or on the process of synthesis or formation of material and material compositions [Arkhangelsky Yu.S. Reference book on microwave electrothermal: a reference / Yu.S. Arkhangelsk Saratov: Scientific book, 2011. 560 p., Kalganova S.G. Electrotechnology of non-thermal modification of polymeric materials in the microwave electromagnetic field. - Diss. Dr. tech. sciences. - Saratov, 2009]. In this case, it is necessary to influence the finally formed product, or a product with a structure and properties changed during operation.

The implementation of the method in the processing of large-sized products is shown in FIG. 1, products of small size in FIG. 2. In FIG. 1 denotes: 1 - the object of influence (sealing ring with a diameter of more than 200 mm), 2 - a horn antenna radiating a microwave electromagnetic field, 3 - a power source, 4 - a drive of rotation of the object of influence, 5 - a microwave radiation receiver, 6 - ballast load, 7 - magnetron. FIG. 2 designates: 2 - a horn antenna radiating a microwave electromagnetic field, 3 - a power source, 5 - a microwave radiation receiver, 6 - a ballast load, 7 - a magnetron, 8 - impact objects (sealing rings with a diameter of less than 200 mm), 9 - a table for placement objects of impact.

The method is as follows.

Pre-processed product is fed into the working area in which the microwave electromagnetic field is generated.

Processing of the microwave electromagnetic field is carried out on a microwave installation with a radiation source with an output power of 1000-1200 W and a frequency of 2450 MHz. The radiation source is at least one horn antenna with a rectangular cross-sectional profile. The distance from the plane of the radiating horn antenna to the workpiece can be adjusted in the range of 0-250 mm.

When processing large-sized products set the object to be processed (1), for example, a rubber ring with a diameter of 200-1500 mm, on the bearing and drive pulley of the drive (4) so that its segment is between the radiating (2) and receiving (5) horn antennas at a distance 100-150 mm from the plane, respectively, of the radiating and receiving horn antennas. Include the source of the microwave electromagnetic field (3) and set the exposure time of 1.5-1.6 minutes during preprocessing, so that at a set distance the specific power absorbed by the product, equal to 1.5 W / cm ^3, does not lead to heating more than 40 ° C. Excess power of radiation not absorbed by the product is diverted through the horn (5) into the ballast load in the form of a container with water (6). After a set time, the stepper drive (4) of the pulley rotation is turned on, which allows the ring to rotate through an angle, allowing the next segment to fall into the aperture of the antenna depending on the diameter of the ring and stop the rotation. After the expiration of the required time, the cycle is repeated. Thus, the entire surface of the ring is processed. Then carry out the removal of the processed product from the work area.

When processing small-sized products in the working area, a coordinate table (9) of a dielectric material, for example, polypropylene, is installed on which the processed products (8) are fixed. Carry out the simultaneous processing of the number of products, determined by their size and the possibility of placement in the aperture of the horn (2). If necessary, after processing one part of the products, the table is moved, introducing a new batch into the working area.

An example implementation of the method.

In the experiments, a special microwave process unit with a frequency of the generated electromagnetic field of 2450 MHz was used, which allowed to control the power supplied to the sample over a wide range (from 100 to 1000 W). Due to the undesirability of overheating the finished product with carbon filler, which can cause destruction, the treatment was carried out in a non-thermal mode (at a specific power of 1-4 W / cm ³ ) with an exposure time of 0.5; 1.0; 1.5; 2.0; 3.0; 4.0 minutes, which did not cause heating more than 40 ° C.

Samples of rubber had outer and inner diameters, respectively, 55.0 and 37.0 mm, thickness - 3.5 mm. For 5 years, the samples were kept in a dry room in air and exposed to temperatures from + 30 ° C to -10 ° C. One sample was installed in the hot water system and was under the action of chlorinated water at a temperature of + 50 ° C.

Additionally conducted a study of the influence of external factors on the change in compliance. Part of the samples (control and after microwave processing) were placed in water and kept frozen at -25 ° C for 60 hours. After defrosting, another part of the samples was placed on the Sun for 6 hours. The temperature at the same time was 43-45 ° С.

Initially, the surface structure of the samples was examined before processing with a digital microscope at x500 magnification. Re-samples were investigated after microwave exposure.

The elastic characteristics of the samples before and after processing were investigated at a special facility with computer processing of the signals of a strain gauge loaded with a lever mechanism. The mechanism acted on the sample with a cone with an apex angle of 90 ° and a rounding radius of 0.1 mm. Simultaneously with the loading moment, the corresponding deformation of the sample was also determined using a dial gauge with a scale value of 0.01 mm. Calculate the compliance of the material by the known formula:

λ = δ / P [mm / H],

where λ is compliance; δ is the deformation (the penetration of a cone, taken as 1.5 mm); P - loading force.

By changing the compliance Δλ, they made a conclusion about the change in plasticity and, consequently, the sealing properties of the seal.

The experimental results obtained are presented in FIG. 3-6. FIG. 3 shows the effect of the specific power of the microwave electromagnetic field P and the processing time t on the change in the rubber seals Δλ compliance. FIG. 4 shows the effect of exposure time on the compliance λ, when the specific power of the microwave electromagnetic field is 1.5 W / cm ³ . FIG. 5 shows the change in the compliance of the sample after freezing. FIG. 6 shows photographs of the microstructure in comparison with the flexibility of the seal samples: new ( a ); past aging to varying degrees of ductility reduction (b), (the last line shows the sample that was in the hot water system); passed aging with subsequent microwave processing at a specific power of 2.5 W / cm ³ for 2 minutes (c).

The mathematical processing of the graph of FIG. 3 allowed us to obtain an approximating function of the following form:

where P is the specific microwave power; t is time.

The analysis of the obtained dependences allows us to conclude that the power of the microwave electromagnetic field has a much greater effect on the change in compliance than time, which is possibly related to the formation of new and restoration of old bonds in the rubber matrix. The increase in time causes first of all the heating of the material, which from a certain moment causes destructive effects: drying of the matrix, breaking of bonds, cracking. The above confirms the nature of the experimental graphs of FIG. 3 and FIG. 4. With an increase in power density at a processing time of 1 minute, the effect of microwave processing weakens (the dependence becomes flatter). Practically after an increase in power of more than 1.5 W / cm ^{3, a} noticeable increase in the compliance of new seals is not observed. When the exposure time is 2 minutes, an increase in specific power causes a significant increase in compaction material compliance, however, with a further increase in power from 3 W / cm ³ to 4 W / cm ^3, there is a decrease in compliance by 2.5% or more, which makes it inappropriate to further increase power. When the power density does not exceed 1.5 W / cm, the maximum compliance is provided (see Fig. 4) with an exposure time in the range of 1.5-1.6 minutes.

It was established that the preliminary microwave treatment leads to an increase in the stability of the compaction compliance after external environmental influences: for the control sample, the changes ranged from 14 to 19%, for the treated sample in the microwave field - from 2 to 11%. For samples subjected to additional heating after freezing, microwave pre-treatment resulted in an increase in compliance depending on the strain by 13-50%. At the same time, the change of this parameter as compared with the initial state of the material did not exceed 8% as compared with 18-22% for control samples.

From the analysis of micrographs (Fig. 6), it follows that the new rubber seals have a generally homogeneous fine-grained carbon filler structure in a rubber matrix. In this case, there are individual defects in the form of folds and microcracks. After aging, the material becomes wrinkled, the surface is relief, sometimes there are numerous deep cracks that divide the structure into fragments. Apparently, these defects are a consequence of the drying and destruction of the rubber matrix, which on the one hand leads to a decrease in compliance (the material becomes hard and slightly deformable), and on the other hand leads to a decrease in compaction strength, and may lead to its destruction. If the source material already has defects in the form of cracks, then in the process of aging they develop further, the number of matrix-filler bonds is significantly reduced, which is manifested in the preservation of ductility (the first line of the figure). However, it can be considered that this is “pseudo-compliance”, since Deformation does not occur due to the elasticity of the material and its elastic properties, but due to the expansion of cracks and the breaking of bonds in the structure. The material that has undergone aging in a hot water environment has practically no cracks, moreover, the initial folds and cracks are hardly distinguishable. However, the surface morphology is highly developed, there are visible foreign inclusions of chemical deposits of the aquatic environment, possibly penetrating into the pores of the material and along with the thermal destruction of the matrix contributing to its curing, which manifests itself in a sharp (by an order) decrease in compliance.

Samples subjected to microwave processing, have a significantly modified structure. In all cases, almost no cracks and fractures appear, the material takes on a form similar to the original. That is, we can talk about "healing" defects. The mechanism of this phenomenon may be the restoration of long molecules of synthetic rubber, the formation of new bonds and the redistribution of the matrix under the action of the polarization of the dipoles of the molecules and their new orientation. As a result, the material becomes more elastic. Thus, it has been experimentally established that after processing new seals, their compliance increases by (19–20)%, which makes it possible to extend the service life under extreme conditions.

Thus, the problem posed is solved by increasing the elasticity of rubber sealing elements of pipeline and stop valves, which allows to extend the life of seals and increase the reliability of adjusting and connecting nodes of pipeline systems for various purposes.

Claims (1)

A method for improving the functional properties of rubber sealing articles of annular form by treating in a microwave electromagnetic field, including supplying products to a work zone in which a microwave electromagnetic field is generated, treating a microwave electromagnetic field of a product and removing the processed product from the working zone in which the microwave electromagnetic field is generated by radiators in the form of horn antennas, and the degree of the electromagnetic field on the product is regulated, characterized in that it additionally uses a cozy receiving antenna connected to the ballast load, the workpiece is placed between the radiating and receiving antennas, during the initial processing of new rubber seals, the specific radiation power is set to 1.5 W / cm and the seal is maintained at this power for 1, 5-1.6 minutes, while the radiation pattern of the radiating antenna is formed in such a way that the absorbed power in all areas of the ring product is uniform.

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