RU2563271C1 - Method of protecting internal surfaces of heating systems from corrosion and sediments accumulation - Google Patents

Abstract

FIELD: chemistry.

SUBSTANCE: method of protecting internal surfaces of heating systems from corrosion and sediments accumulation includes introduction of octadecylamine (ODA) into heating system. Increase of octadecylamine concentration in heat-carrier to target level in 2-10 mg/kg is realised during time, not less than 50 times exceeding period of heat-carrier circulation in heating system. When target level of concentration of octadecylamine in heat-carrier is reached, support of said level is realized during time, not less than 100 times exceeding period of heat-carrier circulation in heating system.

EFFECT: invention makes it possible to form uniform stable layer of octadecylamine on the entire area of internal surface of heating system, optimise ODA consumption and reduce processing time.

5 cl

Description

The invention relates to the field of solutions aimed at cleaning and protecting the inner surfaces of pipes from corrosion and accumulation of deposits, and can be used to increase the reliability and resource of heat supply systems.

In large cities of the Russian Federation, heat is supplied to consumers using a dual-circuit piping system in which the coolant circulates, usually water. The first circuit connects heat-generating equipment, for example, district heating stations (RTS) with one or more central heating centers (TSC). Boiler plants or thermal power plants (TPPs) can act as RTS, and in the first case, the boiler itself is the heat source for the first circuit, and the steam-water turbine circuit in the second. In the central heating center with the help of heat exchangers, heat is transferred from the first circuit to the second, which, in turn, connects the central heating system with consumers - the residential sector and enterprises, delivering heat to them. Further, in the text of this application, the heat supply system is understood to be the first circuit of the above-described dual-circuit piping system that transfers heat from the RTS to the central heating system.

A known method of operating heating systems (RU 2323391 C1, F24D 10/00, 04/27/2008), used to protect pipeline circuits and equipment from corrosion and accumulation of deposits, and selected as a prototype of the invention. According to this method, aliphatic amine, in the preferred case, octadecylamine (hereinafter - ODA), which is in the form of an aqueous emulsion, is dosed into the pipelines of the heat supply systems. From patent publication RU 2439204 C1, C23F 11/14, 01/10/2012 it is also known that a solution of ODE in ethanol can be used for dosing into a heat supply system.

The prototype uses the property of ODA to deposit on metal surfaces with the formation of a continuous mono- or multimolecular layer, known as the "Langmuir picket". The molecular layer prevents the access of oxygen and carbon dioxide to the treated surfaces, thereby preventing the appearance of foci of corrosion on them and the accumulation of deposits. In addition, ODA has a pronounced detergent effect, allowing you to remove the existing corrosion centers and accumulated deposits already existing at the time of treatment.

It should be noted that in the known solutions, the mass of the ODE sorbed per unit surface area was considered as a criterion for the quality of the ODE layer on the inner surfaces of the heat supply systems. In this case, the formation parameters of this layer, which, as will be shown below, have a significant effect on its quality, were overlooked. Hereinafter, layer quality means the following properties of the ODE layer: uniformity of coating over the entire area of the inner surface of the heat supply system and the ability to prevent the occurrence of foci of corrosion and the accumulation of deposits over a specified period. It turned out, for example, that a uniform stable layer of ODE can be formed only if there is some optimal concentration of ODE in the coolant, which was not installed in the prototype. Since the effectiveness of processing heat supply systems with the help of ODA in the known solutions is not guaranteed, the prototype provided for regular hydropneumatic washing.

Studies have shown that even with accurate observance of the optimal concentration of ODA, the results of processing heating systems can vary significantly. In some cases, detachment of a significant amount of sediment occurring in a short period of time is observed, as a result of which sediment particles can reduce or block the passage section of the water path. In other cases, the dosing of the calculated volume of the reagent to achieve the optimal concentration of ODA is accompanied by unreasonably high costs of labor and energy resources.

The aim of the invention is the formation of a uniform stable layer of ODE on the entire area of the inner surface of the heat supply system while optimizing the consumption of ODE and reducing processing time.

To achieve this goal, a method is proposed for protecting the internal surfaces of heat supply systems from corrosion and accumulation of deposits, including the introduction of ODA into the heat supply system. The method is characterized in that for a time exceeding the period of circulation of the coolant in the heat supply system by at least 50 times, the concentration of ODA in the coolant is increased to the target level of 2-10 mg / kg. Upon reaching the target level of concentration of ODA in the coolant, this level is maintained for a time exceeding the period of circulation of the coolant in the heat supply system by at least 100 times.

ODA can be introduced into the heat supply system in the form of an aqueous emulsion or a solution in ethanol.

In the particular case of the invention, the time during which the concentration of ODA in the coolant is increased to the target level of 2-10 mg / kg does not exceed the period of circulation of the coolant in the heat supply system by more than 200 times.

In the preferred case of the invention, the time during which the concentration of ODA is maintained at the target level does not exceed the period of circulation of the coolant in the heat supply system by more than 200 times.

Analysis of statistical data allows us to conclude that in order to form a uniform stable layer of ODA on the internal surfaces of heat supply systems and to eliminate negative phenomena associated with the process of removing deposits accumulated by the time of processing, it is necessary to ensure the optimal ratio of the following factors:

- concentration of ODA in the coolant;

- the time to maintain the optimal level of concentration of ODA in the coolant;

- the intensity of increasing the concentration of ODA in the coolant to achieve the optimal level.

In the course of studies, it was found that the optimal level of ODE concentration in the coolant, which ensures the formation of a uniform stable layer of ODE on the inner surfaces of heat supply systems, is 2-10 mg / kg.

When the concentration of ODE in the coolant is less than 2 mg / kg, the ODA molecules are not able to create a continuous uniform layer even during prolonged treatment, especially in places where the flow rate of the coolant is high and the process of desorption of molecules from the surface (including with exfoliated deposits) is comparable with sorption process.

In addition, the accuracy of measuring the concentration of ODE at values less than 2 mg / kg becomes comparable with the measurement error, which complicates the measurement of concentration, and, as a result, guarantee the quality of the ODE layer.

Establishing the concentration of ODA in the coolant above 10 mg / kg with the right intensity of its change leads to an increase in reagent consumption and processing time without increasing the quality of the ODA layer.

Of essential importance for the formation of a uniform stable layer of ODE is the intensity of increasing the concentration of ODE in the coolant to the target level, which is the optimal value for the ODE concentration justified above. An excessively high intensity of increasing the concentration of ODE leads to the fact that deposits on the entire area of the inner surface exfoliate in a short period of time, which can cause clogging of the bore of the pipeline. Therefore, the time to increase the concentration of ODA in the heat supply system must be correlated with the area of the treated surface, which, in the approximation acceptable for this case, is proportional to the length of the pipeline circuit.

Heat supply systems can have different lengths, however, the average flow rate of the coolant in them is in technologically limited narrow limits - from 1 to 2 m / s. A guideline for the implementation of the proposed method is the upper limit of the specified range of velocity of the coolant 2 m / s

Thus, it is advisable to calculate the time to reach the target level of concentration of ODE as a multiple of the period of circulation of the coolant, which is a product of a conditionally constant value - the average flow velocity of the coolant and a variable value - the length of the pipeline.

The research results showed that if you increase the concentration of ODA to the target level faster than in a time equal to 50 periods of circulation of the coolant in the heat supply system, then there is an unacceptable intensification of the process of exfoliation of existing deposits, particles of which can significantly reduce the flow cross section of the water path or even completely block it. It was also noted that increasing the concentration of ODE to the target level more slowly than during the period equal to 200 periods of circulation of the coolant does not affect the quality of the ODE layer, which means it is not advisable.

After the concentration of ODA in the coolant has reached the target level, to ensure the above parameters of the molecular layer, this concentration level must be maintained for a certain time. Taking into account that the larger the surface area to be treated, and the more ODE molecules are deposited on it at each moment of time, the drop in the concentration of ODE from the target level will be proportional to the length of the pipeline circuit. According to the above considerations, the time during which it is necessary to maintain the target level of ODA concentration for the formation of a high-quality ODA layer throughout the pipeline circuit will be directly dependent on the coolant circulation period.

It was found that the target level of concentration of ODA should be maintained for at least 100 periods of circulation of the coolant. This time is enough to form a layer of the required thickness, uniformly covering 100% of the internal surface of the heat supply system. The required thickness of the ODE layer, ensuring the preservation of its functionality for a period of at least three years, is characterized by an indirect parameter in the form of the mass of the ODE deposited per unit area and comprising at least 0.3 μg / cm ² .

At the same time, it was possible to establish that maintaining the concentration of ODA at the target level over 200 periods does not give an additional effect for the formation of a more stable layer, therefore, in order to reduce processing time and save resources, this was considered inappropriate.

At a specific object, the proposed method can be implemented as follows.

The object is a heat supply system, which is a pipeline circuit with a length of 80 km, connecting the boiler of the district heat station (RTS) and a number of central heat points (TSC). The coolant circulation period is 15 hours, the system volume is 8000 m ³ . The heating system has been in operation for 4 years and has been regularly processed by known methods.

A metering device connected to the facility for the production of a substance containing ODA will be connected to the object. Such a substance may be an aqueous emulsion of ODA, a solution of ODA in ethanol, or a melt of ODA. The most technologically advanced option at present seems to be the use of an aqueous emulsion of ODA.

The target level of ODE concentration is determined in the range of 2-10 μ / kg, taking into account that it is advisable to choose values close to the lower boundary of the specified interval for new or regularly processed heat supply systems, and close to the upper boundary for new-processed systems having long term of operation. It should be noted that any value of the target concentration level selected from the specified interval will allow the formation of a high-quality ODA layer on any heat supply system subject to other conditions according to the invention, however, the optimal choice of the target concentration level will reduce processing time and reagent consumption. Based on the fact that the considered pipeline circuit underwent regular processing, the target level of ODA concentration was estimated at 3 mg / kg (a value was chosen near the lower boundary of the optimal interval).

Next, determine the mass of ODA to be introduced into the heat supply system and in this case at least 24 kg (8,000,000 kg * 3 mg / kg), and prepare the appropriate amount of water emulsion, which is introduced into the heat supply system for at least 400 hours (50 * 8 hours). Check the concentration of ODA in the coolant and make sure that the target level is reached.

Achieving the target level of ODA concentration for a time exceeding the coolant circulation period by at least 50 times (in this case, at least 750 hours) eliminates the risk of clogging of the pipeline cross section with intensely exfoliating deposits. In the case of using higher target concentration levels, the time of administration of ODA can be increased in order to create conditions for the formation of a more uniform layer. At the same time, the indicated minimum time for the introduction of ODEs ensures safe peeling and removal of deposits for any heat supply systems and any target levels of ODE concentration from the above interval.

A special case of the invention also determines the upper limit of the time interval for the introduction of ODA, which is 200 periods of circulation of the coolant (in this case, 3000 hours), exceeding which does not give a positive effect for further formation of the layer, but leads to additional resource consumption.

Further, for no less than 1500 hours (100 * 15 hours), the concentration of the ODE is maintained at the target level by periodically checking the concentration and dosing the appropriate amount of the ODE emulsion. Due to the settling of the ODE on the internal surfaces of the heat supply system without additional dosing of the emulsion at this stage, the concentration of the ODE will decrease.

Maintaining the target level of ODE concentration for a time exceeding the coolant circulation period by not less than 100 times (in this case, not less than 1500 hours), allows us to form an ODE layer of the required thickness, uniformly covering 100% of the internal surface area of the heat supply system. In the case of the presence in the heat supply system of extended sections with a high flow rate of the coolant and the resulting increased intensity of desorption of ODE molecules, this time can be increased in order to create a thicker layer in these zones, which may be appropriate in case of irregular further processing. However, it should be noted that the indicated minimum time to maintain the target level of ODE concentration is sufficient to form a layer of the required thickness for any heat supply systems and any target concentration of ODE from the above interval.

A particular case of the invention also determines the upper limit of the time interval for maintaining the target level of concentration of ODE, which is 200 periods of circulation of the coolant (in this case 3000 hours). Exceeding the indicated time leads to an additional consumption of resources, however, it does not have a positive effect for the formation of a more stable layer in fast sections, since sorbed ODE molecules have a weaker electrical connection with the metal and are carried away by the flow due to its increased thickness.

After carrying out the processing of the heat supply system according to the proposed method, a prototype installed in the heat supply system as a part of its inner surface is removed and verified that the ODE layer on it is at least 0.3 μg / cm ² .

Claims (5)

1. A method of protecting the internal surfaces of heat supply systems from corrosion and accumulation of deposits, including the input of octadecylamine into the heat supply system, characterized in that
for a time exceeding the coolant circulation period in the heat supply system by at least 50 times, increase the concentration of octadecylamine in the coolant to the target level of 2-10 mg / kg, and
upon reaching the target level of octadecylamine concentration in the coolant, this level is maintained for a time exceeding the period of circulation of the coolant in the heat supply system by at least 100 times. 2. The method according to p. 1, characterized in that octadecylamine is introduced into the heat supply system in the form of its aqueous emulsion. 3. The method according to p. 1, characterized in that octadecylamine is introduced into the heat supply system in the form of its solution in ethanol. 4. The method according to p. 1, characterized in that the time during which increase the concentration of octadecylamine in the coolant to the target level of 2-10 mg / kg does not exceed the period of circulation of the coolant in the heat supply system by more than 200 times. 5. The method according to p. 1, characterized in that the time during which the concentration of octadecylamine is maintained at the target level does not exceed the period of circulation of the coolant in the heat supply system by more than 200 times.