RU2790736C1 - Method for protecting the surface of vertical tanks using a polymeric soft two-layer liner - Google Patents

Abstract

FIELD: polymer masterials.

SUBSTANCE: protection of the surface of vertical storage tanks for liquid effluents using a polymer soft two-layer liner. Invention relates to a method for protecting the surface of vertical storage tanks for liquid effluents by using a polymer soft two-layer liner. The method consists in mounting and fastening a two-layer polymer elastic liner (1) in a vertical tank (2) at stage a), as well as in subsequent checking the integrity of the material of the polymer soft two-layer liner (1) at stage (b) by testing the tightness of each a closed section of the liner (1), performed by crimping with a pressure booster connected to the manometric assembly (e) of the liner (1). A polymeric soft two-layer liner is characterized by the presence of at least two sealed closed sections of a polymeric material located on the lower (a) and lateral (b) parts of the liner (1), generated by forming transverse (c) and longitudinal (d) seams, a manometric assembly (e), which is equipped with each section of the liner (1).

EFFECT: technical result consists in providing the possibility of increasing the service life of industrial equipment that is exposed to aggressive media during the storage of liquids, as well as reducing the time for testing the integrity of the used polymer soft liner.

15 cl, 1 dwg

Description

The field of technology to which the invention belongs

The invention relates to the field of application of polymer soft liners for protecting and restoring the surface of industrial equipment, in particular vertical tanks, from the effects of aggressive media during the storage of liquids, including products of the oil, chemical and other industries.

State of the art

Compared to chemically resistant coatings, materials made of alloyed steels, reinforced concrete structures, polymeric loose tanks have a number of significant advantages, which include:

- savings in capital costs for the installation of a protective coating from a polymeric elastic reservoir in comparison with the application of a chemically resistant coating or the use of alloyed steels, reinforced concrete structures. The cost of polymeric elastic reservoirs is several times lower,

- quick and easy installation,

- repeated cycle of application and reinstallation. Possibility of folding polymeric elastic reservoirs loose into a roll (package) of small volume,

- environmental safety during installation. Polymer elastic tanks (PER) are not subject to corrosion and adverse environmental influences. Additionally, during installation, no waste is generated that affects human health, as in the case of applying chemically resistant coatings,

- the possibility of installation on tanks with significant volumes, when the application of chemically resistant coatings at volumes above 5000 m ³ has disadvantages in stretching and expanding the coating (there are risks of cracks),

- lower specific pressure on the base of the tank compared to reinforced concrete structures and alloy steel,

- versatility. The material of the tank provides strength, tightness and performance of products in a wide temperature range in some cases from -50°C to +80°C and in almost all aggressive environments of oil products.

Known elastic tank for storage and transportation of liquids, which is a sealed closed shell pillow-shaped, equipped with a filler neck [Magula V.E. etc. Ship soft containers. - L .: Shipbuilding, 1979, pp. 162-163]. The disadvantages of the known elastic reservoir are the risks of leakage of the contents as a result of mechanical damage to the material. When the reservoir is filled with oil products, electrostatic fields are created on its surface and in the space around it with an electric field strength of 300 V to 20 kV. There is also observed freezing of the tank shell to the ground at negative temperatures as a result of condensation of water vapor from the atmospheric air on the surface of the tank, and in the event of depressurization of the closed shell or leakage of oil products, environmental pollution occurs.

An elastic tank is known, containing a tarpaulin tray, on which a closed shell is placed with the possibility of fixation, consisting of a two-layer rubber-fabric material containing a power layer of high-strength viscose fabric, placed between a fuel-resistant coating on the inside and a light-shielding one on the outside, while all layers are connected between each other using hot-curing adhesives. On the top panel of the tank near one of the corners there is a filler neck made of light alloys [YM Mikheev. Rubber tanks. M.: TsNIITEneftekhim, 1977, p.20].

The disadvantage of this elastic tank is:

- the mass of the tank, due to the high material consumption (3-5 kg/m ² ) of the rubber-fabric material;

- limited scope of the tank in areas with temperatures below minus 30°C, which is associated with the use of nitrile rubber as a fuel-resistant layer with a temperature brittleness limit of minus 30°C;

- high fire hazard when loading oil products, due to the dielectric properties of the rubberized fabric (insulator) - specific volume electrical resistance is 10 ¹¹ -10 ¹² Ohm⋅m.

The practice of operating such tanks has shown that the environment from oil products can affect the physical and mechanical characteristics of the material (adhesion of the inner and outer layers decreases, soot and plasticizers are washed out, etc.). All this generally reduces the efficiency of using the known reservoir.

A soft tank for liquids is known (State Research Institute of Chemotology, SU1559617, 04/20/2000), containing a closed shell with ends, a coating and a bottom, drain pipes located in one of the ends, a heating device with a tank roll assembly made in the form of flexible elements, characterized in that, in order to reduce the time for unloading the liquid while reducing labor costs, it is equipped with an elastic partition placed above the bottom to form a cavity for the coolant, the flexible elements are made of a material with a shape memory effect, have different lengths and are mounted in the partition, while the initial section of each of the flexible elements is located at the same distance from the end opposite to the located drain and fill pipes.

A reservoir for liquid is known (25th State Research Institute of the Ministry of Defense of Russia, RU2134225, publ. 08/10/1999), containing an elastic closed shell consisting of upper and lower panels, on the upper of which there is a manhole cover with a drain-filling neck and a device placed inside the shell to increase the completeness of the drain with flow holes. The device for completeness of the drain is made in the form of a spatial rigid structure, fixed around the perimeter of the manhole and having a diametrical rigid vertical partition, while the overall dimensions of the device for completeness of the drain are determined by the following dependencies:

D′=(0.8…2.2)D;

М=(0.8…2.5)S;

B=(0.2…0.4)d,

where D′ is the outer diameter of the device for completeness of the drain;

D is the outer diameter of the manhole cover fastening ring;

M is the total area of the flow holes in the side walls of the device for completeness of the drain;

S - cross-sectional area of the filler neck;

B - the height of the diametrical rigid vertical partition under the filler neck;

d is the inner diameter of the filler neck.

Also known is a soft polymer tank for water and oil products (Neftetank LLC, RU2424967, publ. 07/27/2011), containing a closed polymer shell with ends, a coating and a bottom, drain pipes, characterized in that the closed shell is made double with a sealed cavity between shells, and adjacent shells inside the cavity are connected by jumpers, and an air hose is hermetically connected from the cavity to the outside of the tank with the function of pumping cavity air through it, moreover, the inner shell of the tank is made of PVC and polyurethane (PU), the ratio of which is selected based on the proportion of 50% to 50% of the total substance. This solution was chosen as a prototype.

The disadvantage of these inventions is the time-consuming process of testing the tightness of the material, the inability to use in existing vertical tanks to ensure reliability and increase the operating time of structures, the time spent on detecting damage to the material for repair work.

Brief description of the invention

The objective of the present invention is to ensure the protection of the bottoms and walls of vertical tanks by using a polymer soft liner, as well as checking the tightness and promptly detecting damage and leaks of aggressive media that destroy the material of existing tanks, in particular steel, reinforced concrete structures, internal anti-corrosion coating of tanks, etc. .d.

The technical result of the invention is to increase the service life of industrial equipment that is exposed to aggressive media during the storage of liquids, as well as to reduce the time for testing the integrity of the used polymer soft liner.

Another technical result is to reduce capital costs for diagnostics and repair of industrial equipment, in particular vertical tanks.

This technical problem is solved, and the achievement of the technical result is ensured by using a polymeric soft two-layer liner (1), which includes at least two sealed closed sections located on the lower (a) and side (b) parts of the liner, as well as by checking the integrity of the material of the specified polymeric soft two-layer liner. The sealed closed section (a) covering the bottom of the tank is formed by forming a transverse seam (c) between the layers of this liner. The sealed closed section (b) covering the tank walls is formed by forming transverse (c) and longitudinal (d) seams between the layers of said liner. Checking the integrity of the material of the used polymeric soft two-layer liners is carried out by leak testing by pressing each closed section by forcing a gas-air mixture through an air hose connecting the gauge assembly (e) and the pressure injector.

The presence of hermetic closed sections in the design of the polymeric soft two-layer liner makes it possible to determine the integrity of its material at the stages before and after filling vertical tanks with liquid, in particular, with effluents from industrial petrochemical and chemical industries, without performing additional operations to dismantle the previously installed liner.

Thus, the advantage of the claimed invention is:

- increase in the service life of existing tanks;

- reduction of capital costs for diagnosing the internal surface of tanks for damage;

- reducing the time of testing the integrity of the used polymeric soft two-layer liner;

- environmental safety, which is ensured due to the double protection of the main material of the tank from the effects of aggressive environments. Provided that one of the layers of polymeric soft two-layer liners is damaged, the medium will not interact with the tank coating, damage will be detected during periodic inspection, which should be determined depending on the corrosion rate of the base material of the tank. In this case, the corrosion rate of the base material is determined by a control sample, which is, for example, a steel coupon or a polymer tape, which are placed in the same liquid aggressive medium that is stored in the tank for at least 1 month.

Brief description of the figures

To explain the technical solutions that reveal the essence of the present invention, Fig. 1.

On FIG. 1 shows a diagram of a polymeric soft two-layer liner (1), where (a) is the lower sealed closed section, (b) is the lateral sealed closed section, (c) is the transverse interlayer seam, (d) the longitudinal interlaminar seam, (e) is the manometric assembly for checking the integrity of closed sections.

Detailed description of the invention

The following is a detailed description of various aspects and embodiments of the present invention.

In accordance with the present invention, a method for protecting the surface of vertical tanks for storing liquid effluents consists in installing a polymeric soft two-layer liner in the tank and checking the integrity of all closed sections by crimping them.

More specifically, the method for protecting the surface of vertical effluent storage tanks includes the following steps:

a) carry out the installation of a polymeric soft two-layer liner (1) and fastening of the upper part of the polymeric soft two-layer liner (1) mounted in a vertical tank (2) to the upper part of the vertical tank (2) and fixing each section of the liner (1) on the walls and bottom of the tank (2) at points determined in situ;

b) checking the integrity of the material of the polymeric soft two-layer liner (1) by conducting a leak test of each closed section of the liner (1), performed by pressing with a pressure blower connected to the gauge assembly (e) of the liner (1);

c) optionally rechecking the integrity of the material of the liner (1), including the implementation of actions in accordance with step b),

characterized in that a polymer soft two-layer liner (1) is used, which includes at least two sealed closed sections made of polymer material located on the lower (a) and side (b) parts of the liner (1), formed by forming a transverse (c) and longitudinal (d) seams, manometric assembly (e), which is equipped with each section of the liner (1).

In accordance with the present invention, the polymer soft two-layer liner (1) includes sealed closed sections located on the lower (a) and side (b) parts of the liner (1). The tight closed lower section (a) is formed by forming a transverse seam (c) between the layers of this liner, and covers the bottom of the vertical tank (2). The sealed closed side section (b) is formed by forming transverse (c) and longitudinal (d) seams between the layers of said liner, and covers the walls of the vertical tank (2). The number of sealed closed sections of the liner (1) is at least 2. In one of the embodiments of the present invention, the number of these closed sections is not limited. An increase in the number of sealed closed sections formed between the layers of the liner (1) makes it possible to increase the efficiency of checking the integrity of the liner (1) material, as well as reduce the time to detect and repair damage to the liner (1) material.

Each closed section (a, b) formed between two layers of polymer soft liner material (1) includes a manometric assembly (e). The manometric assembly (e) includes the following interconnected components: branch pipe, pressure gauge, shut-off and control valves (ZRA), safety valve. The manometer, in one of the variants of the invention, is characterized by an accuracy class of not more than 0.15 atm and a measurement limit of at least 5 atm. The number of ZRA is at least two, one - in front of the pressure gauge, the second - before the gas-air mixture is supplied.

The polymeric soft two-layer liner is typically made from PVC, TPU, PVDF, PVDF, LLDPE, HDPE, preferably PVC.

Installation of a polymer soft two-layer liner (1) in a vertical tank (2) is carried out by placing the liner (1) in the tank (2) and attaching the upper part of the polymer soft two-layer liner (1) mounted in the tank (2) to the upper part of the tank (2) at points determined locally.

Before stage a), as a rule, phosphating is carried out, followed by priming of the inner surface of the operated tanks (2) in order to protect it from corrosion. For phosphating the surface of the tank (2), in one embodiment of the invention, phosphoric acid is used. For priming, the material is selected in accordance with the resistance to the stored product, as a rule, at least 1 month. for aggressive environments. In one of the embodiments of the invention, Polak EP 41 No. 3 TBS enamel or its analogues are used for priming.

Next, at stage b), the integrity of the material of the polymeric soft two-layer liner (1) is checked by crimping each closed section of the liner (1) using a pressure booster connected to the manometric assembly (e) of the liner (1).

Checking the integrity of the material of the liner (1), as a rule, is carried out during the daytime to eliminate the risk of an increase or decrease in pressure due to a possible difference in ambient temperature.

The pressure blower is selected from a group of equipment that includes an electric compressor and a mechanical pump. The pressure booster is connected to the manometric assembly (e) of the liner (1) using a flexible hose.

A flexible hose, in one of the embodiments of the invention, is led to a sealed closed lower section (a) of the liner (1) through a branch pipe, which is located on the side of the lower belt or under the bottom of the tank itself. A flexible hose is connected to the sealed closed side sections (b) of the liner (1) through the upper technological window of the tank roof (1) or the nozzles of the tank upper belt (1).

A gas-air mixture or nitrogen is used as an injection medium in case of storage of combustible or flammable liquids. In one embodiment of the invention, the pressure value during the integrity tests by pressure testing is not more than 0.3 atm, preferably not more than 0.25 atm. Next, hold the pressure during the test for 60 minutes, preferably for 15 minutes.

Closed sections of the liner (1) are considered to be tight, provided that the value of the achieved pressure in the section changes by no more than 0.02 atm during the pressure holding time. If the pressure values change during the integrity tests by more than 0.02 atm, in one of the variants of the invention, the damage is eliminated by applying a patch to the damage site of the liner material (1) with further re-testing the integrity of the material of the closed section of the liner ( 1).

Claims (19)

1. A method for protecting the surface of vertical tanks for storing liquid waste by using a polymer soft two-layer liner (1), including the following steps: a) carry out the installation of a polymeric soft two-layer liner (1) and fastening of the upper part of the polymeric soft two-layer liner (1) mounted in a vertical tank (2) to the upper part of the vertical tank (2) and fixing each section of the liner (1) on the walls and bottom of the tank (2) at points determined in situ; b) checking the integrity of the material of the polymeric soft two-layer liner (1) by conducting a leak test of each closed section of the liner (1), performed by pressing with a pressure blower connected to the gauge assembly (e) of the liner (1), characterized in that a polymer soft two-layer liner (1) is used, which includes at least two sealed closed sections made of polymer material located on the lower (a) and side (b) parts of the liner (1), formed by forming a transverse (c) and longitudinal (d) seams, manometric assembly (e), which is equipped with each section of the liner (1). 2. The method according to claim 1, where the sections of the mounted liner (1) are sealed closed sections located on the lower (a), adjacent to the bottom of the tank, and side (b), adjacent to the wall of the tank, parts. 3. The method according to claim 1, in which each closed section of the liner (1) includes a gauge assembly (e). 4. The method according to claim 3, in which the manometric assembly (e) includes a branch pipe, a pressure gauge, shut-off and control valves (SPA), a safety valve. 5. The method according to claim 3, where a pressure gauge of a manometric assembly (e) is used, which is characterized by an accuracy class of not more than 0.15 atm and a measurement limit of at least 5 atm. 6. The method according to claim 1, wherein the polymeric soft two-layer liner (1) is made of polyvinyl chloride, thermoplastic polyurethane, polyvinylidene fluoride, polyvinylidene chloride, linear low density polyethylene, high density polyethylene, preferably polyvinyl chloride. 7. The method according to claim 1, where before stage a) phosphating is carried out, followed by priming of the inner surface of the tank (2). 8. The method according to claim 1, where the pressurizer in step b) is selected from a group of equipment that includes an electric compressor or a mechanical pump. 9. The method according to claim 1, where the pressure booster is connected to the gauge assembly (e) of the liner (1) using a flexible hose. 10. The method according to claim 9, where the flexible hose is led to the sealed closed lower section (a) of the liner (1) adjacent to the bottom of the tank (1) through a branch pipe located on the side of the bottom belt or from below under the bottom of the tank itself. 11. The method according to claim 9, where the flexible hose is led to the sealed closed side sections (b) of the liner (1) through the upper technological window of the tank roof (1) or the nozzles of the tank upper belt (1). 12. The method according to claim 1, in which a gas-air mixture or nitrogen is used as the injection medium. 13. The method according to claim 1, wherein the pressure during the integrity tests in step b) by pressure testing is not more than 0.3 atm, preferably not more than 0.25 atm. 14. The method according to claim 1, wherein the pressure during the tests in step b) is maintained for 60 minutes, preferably for 15 minutes. 15. The method according to claim 1, in which the closed sections of the liner (1) are considered tight, provided that the pressure value changes by no more than 0.02 atm during the pressure holding time. 16. The method of claim. 1, which optionally re-check the integrity of the material of the liner (1), including the implementation of actions in accordance with step b).

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