RU2406938C1 - Method of heat- and hot water supply and system of vacuum water deaeration which is used in it - Google Patents

Abstract

FIELD: power industry.

SUBSTANCE: compensation reserve of deaerated water is formed in order to provide stable vacuum water deaeration and uninterrupted supply of deaerated hot water to consumer at the tank volume reduced by many times for accumulation of deaerated hot water. The above reserve is used by means of uninterrupted and forced removal of some part of deaerated hot water flow at the outlet of vacuum deaerator by means of pump and its integration with initial water flow at the inlet of vacuum deaerator on the basis of combination of two simultaneous automated control processes.

EFFECT: invention allows increasing the deaeration depth and enlarging the use of vacuum water deaeration system in various water supply systems in connection with the possibility of decreasing the functional load of accumulation and variation with the value of the above decrease depending on the purpose of the system, and reducing the area of the building site of the implemented system, which is vital in urban conditions, and reduction of investments.

4 cl, 1 dwg

Description

The proposed group of inventions relates to the field of power engineering and can be used for domestic and industrial heat and hot water supply with vacuum deaeration of water.

One of the main tasks of the functioning of heat and hot water supply systems with vacuum deaeration of water is to ensure reliable operation of these systems based on the implementation of stable vacuum deaeration and uninterrupted supply of deaerated hot water to the consumer.

An uninterrupted supply of deaerated hot water to a consumer is achieved as a result of a known accumulation of deaerated hot water (see, for example, the book by Truba I.A. and Litvin O.P. Vacuum deaerators. M.: Energy, 1967, p. 44).

This (traditional) accumulation of deaerated hot water, in addition, eliminates the destabilizing effect on the vacuum deaeration of the variable flow rate of the consumed deaerated water, but worsens the overall performance of the heat and hot water supply systems with vacuum deaeration of water in connection with the use of capacious storage tanks (at least two).

The above disadvantage is saved in the known method of heat and hot water supply, selected by the applicant as a prototype of the proposed method and including the supply of heated source water to the vacuum deaeration system of water, deaeration of water in it using a vacuum deaerator, accumulation of deaerated water and supply of accumulated deaerated water to the consumer ( see the book Chistyakova NN and others. Improving the efficiency of hot water supply systems. M: Stroyizdat, 1988, p. 1999, Fig. 7.3, b) with the exception of the destabilizing water effects on the vacuum deaeration of the variable flow rate of the consumed deaerated water and, as a result, ensuring uninterrupted supply of deaerated hot water to the consumer due to the accumulation of deaerated water in the capacious storage tank (see the book by V.V. Tsvetkova and I.A. Berezhnova, Reference book on heat supply to industrial enterprises. Kharkov, "PRAPOR", 1987, p. 78-80).

As a prototype of a vacuum deaeration system for water used in the claimed method, a vacuum deaeration plant is selected that contains a pipeline section for the forced supply of heated source water, which has an automatic control valve built into its pipeline and is connected to the inlet of the vacuum deaerator, which is connected to its outlet via a pipeline of the outlet of deaerated hot water with the inlet of the tank for accumulating deaerated hot water equipped with a water level sensor, is connected with the aforementioned automatic control valve, and having access to the pipeline section for the consumption of deaerated hot water (see the directory "Vacuum Deaerators". M: NIIINFORMTYAZHMASH, 1972, p.17, Fig.17).

The technical result of the claimed technology of heat and hot water supply is to increase the efficiency of ensuring stable vacuum deaeration of water and uninterrupted supply of deaerated hot water to the consumer by eliminating the need for a capacious storage tank (referred to as part of the vacuum deaerated water system and as “tank for accumulating deaerated hot water "- an explanation of the applicant in order to observe the unity of terminology in this application) while increasing the depth of deaeration and expanding the use of the use of a vacuum water deaeration system in a variety of heat and hot water supply schemes in connection with the possibility of reducing the functional load (need) of accumulation and varying the value of this decrease depending on the purpose of the scheme, as well as reducing the construction site of the implemented scheme, relevant in urban conditions, and accordingly, a reduction in investment in connection with this.

To achieve the stated technical result in a method of heat or hot water supply, which includes supplying heated source water to a vacuum deaeration system, deaerating the water therein with a vacuum deaerator, accumulating deaerated water and supplying the accumulated deaerated water to a consumer while maintaining a stable deaeration mode by use of the formed reserve of deaerated water to compensate for the destabilizing variable flow rate of consumed deaerated water, f The specified compensation reserve of deaerated water is formed by continuous and forced removal of part of the deaerated water stream at the outlet of the vacuum deaerator and its combination with the source water stream at the inlet of the vacuum deaerator, and the use of the deaerated water reserve thus formed to compensate for the destabilizing variable flow rate of the consumed deaerated water is carried out a combination of two simultaneous automated control processes: flow continuously and part of the deaerated water stream forced to the inlet of the vacuum deaerator and the feed rate of the feed water to the inlet of the vacuum deaerator depending on the consumption of deaerated water while ensuring a constant combined flow of water at the inlet and outlet of the vacuum deaerator.

To ensure the possibility of realizing a small-capacity storage tank (functional approximation of the storage tank to a measuring tank), a double simultaneous automated regulation is proposed, which is carried out in case of exceeding the maximum discharge of deaerated water over the maximum consumption of deaerated water or their equality.

In this case, in a vacuum deaeration system for water containing a pipeline section for forced supply of heated source water, having an automatic control valve built into its pipeline connected to the inlet of the vacuum deaerator, which is connected by its outlet using the pipeline section of the outlet of deaerated hot water to the inlet of the tank for accumulating deaerated hot water equipped with a water level sensor associated with the said automatic control valve, and having access to the pipeline th section of consumption of deaerated hot water, an additional pipeline section for continuous drainage of deaerated water was introduced with a pump built into its pipeline having an automatic regulator of the latter's capacity connected with a water flow sensor at the inlet of the vacuum deaerator, and the specified pipe section for continuous drainage of deaerated water connects the outlet of the vacuum deaerator with an insert into the pipeline of the forced supply of heated source water in the area between its automatic machine cal control valve and the water flow rate sensor at the inlet of the vacuum deaerator.

In a particular embodiment of the proposed system of vacuum deaeration of water, the tank for accumulating deaerated hot water is made in the form of a measured tank with a small volume.

The well-known use of water recirculation during its vacuum deaeration to increase the removal of aggressive gases from water (see the book by I.A. and Litvin O.P., cited as an example, p. 62, Fig. 21) does not contradict the requirements of the patentability criterion of “inventive level ”, because as a sign in the claimed combination of signs does not manifest itself in a known purpose: firstly, the depth of deaeration in the proposed method, due to the continuity of recycling of the part of the deaerated water stream forced to the inlet of the vacuum deaerator, is higher and more stable due to the fact that the known recycling is a limited multiple in the case of insufficiently deep deaeration, and secondly, the main argument in favor of the legitimacy of the applicant’s claim for a patent of the Russian Federation is in the accompanying nature of increasing the depth deaeration due to recirculation, the latter simultaneously leads to a sharp decrease in the need for accumulation of deaerated water in the inventive method to ensure stable vacuum deaeration of water and uninterrupted supply of deaerated hot water to the consumer and to other winning characteristics of the proposed heat and hot water supply technology set forth in the technical result.

The drawing shows a diagram of heat or hot water supply for the implementation of the proposed method, including used in the latter system of vacuum deaeration of water.

The proposed scheme of heat or hot water supply consists of a source of heated (in this example, up to ~ 70 ° C) source water, a vacuum deaeration system of water 1 and a pump for supplying deaerated hot water to a consumer 2.

Moreover, the system of vacuum deaeration of water 1 contains a pipeline section of the forced supply of heated source water 3, which has an automatic control valve 4 integrated in its pipeline and connected to the inlet of the vacuum deaerator 5.

The vacuum deaerator 5 is connected to the inlet of the deaerated hot water 7, provided with a water level sensor 8 connected to the automatic control valve 4, and connected to the pipeline for the consumption of deaerated hot water 9, with a feed pump consumer of deaerated hot water 2.

In addition, a pipeline section of a continuous drainage of deaerated water 10 with an integrated pump 11 in its pipeline 12 having an automatic capacity controller of the latter 12 connected to a water flow sensor 13 at the inlet of the vacuum deaerator 5 is additionally introduced into the system 1. Moreover, the pipeline section of a continuous drainage of deaerated water 10 connects the outlet of the vacuum deaerator 5 with the insert into the pipeline of the forced supply of heated source water 3 in the section between its automatic control valve m 4 and a flow sensor 13 at the inlet of the vacuum deaerator 5.

In a particular embodiment of the proposed system of vacuum deaeration of water, the tank for accumulating deaerated hot water 7 can be made in the form shown in the drawing of a measured tank with a small volume and combined at the bottom of the latter inlet and outlet.

The proposed method of heat and hot water supply is as follows.

During the operation of the scheme shown in the drawing, a compensated reserve of deaerated water is formed to ensure stable vacuum deaeration of water and uninterrupted supply of deaerated hot water to the consumer with a repeatedly reduced volume of the tank for accumulating deaerated hot water 7 by continuously and forcibly draining with the pump 11 part of the deaerated hot water flow to the exit of the vacuum deaerator 5 and its association with the flow of feed water at the inlet of the vacuum deaerator 5.

The use of the deaerated water reserve thus formed to compensate for the destabilizing variable flow rate of the consumed deaerated water at small dimensions of the tank 7 is carried out on the basis of a combination of two simultaneous automated control processes: using the flow controller 12 continuously and forcibly discharged to the inlet of the vacuum deaerator 5 of the deaerated water flow according to indications sensor 13 and using valve 4 of the feed rate to the input of the vacuum deaerator of the source water, depending on p consumed vanishing deaerated water under indications of the sensor 8 to provide a time constant of the combined water flow at the inlet and outlet of the vacuum degasifier 5.

In a particular example of the implementation of the proposed system of vacuum deaeration of water can be used: as a vacuum deaerator 5 - vacuum deaeration column type DV-200 with a capacity of 200 m ³ / h, as a pump 11 - pump type K150-125-315δ / 4-5, as valve 4 - a valve of the type 25 h940nzh Du = 80 mm, Kv = 160 m ³ / h, as tank 7 - a tank with a volume of 12 m ³ .

With an increase in the consumer's consumption of deaerated hot water supplied by the pump 2 from the tank 7, the water level in it decreases and the valve 4 increases the supply of heated source water to the inlet of the vacuum deaerator 5. At the same time, the controller 12, responding to a change in the pulse of the control signal of the sensor 13, reduces the pump 11 feeds a portion of the deaerated hot water stream to the inlet of the vacuum deaerator 5, thereby providing a constant total supply of the total flow of the mixed heated source and deaerated hot water partially discharged from the outlet of the vacuum deaerator 5. As a result, the redistribution of the total flow of deaerated hot water at the outlet of the vacuum deaerator 5 occurs with a constant flow rate of water at the indicated outlet and a decrease in the flow rate of the part of the outlet deaerated water stream forced to the inlet of the vacuum deaerator 5, leading to an increase consumption flowing into the tank 7 deaerated hot water and compensation for the initial increase in water consumption by the consumer.

With a decrease in the consumer's consumption of deaerated hot water, the order of the two simultaneous automatic control processes outlined is the reverse.

For the implementation of heat or hot water supply with a minimum volume of tank 7 in the form of a measuring tank, the described double simultaneous automated control is carried out under conditions when the maximum flow rate of the deaerated water is discharged over the maximum consumption of deaerated water or their equality.

The proposed thermal technology is universal in nature. It does not depend on the type of vacuum deaerator and is compatible with various thermal schemes for its inclusion.

The claimed technological solution of heat and hot water supply can be used in boiler rooms for the preparation of make-up water, hot water and in district heating systems at existing and newly constructed central heating centers for the preparation of hot water.

Using the proposed group of inventions can reduce the total footprint, as well as reduce investment and annual operating costs for the maintenance of the tank farm.

The winning component of the technical result of the claimed group of inventions is to improve the quality (depth) of deaeration and the stability of its maintenance in comparison with the known use for recycling degassing (see, for example, USSR author's certificate No. 1257364, F24D 17/00, 19986) due to the intensified by the applicant continuous (constant) multifunctional (regulatory and technological) partial return of deaerated hot water from the outlet of the vacuum deaerator.

Claims (4)

1. A method of heat or hot water supply, comprising supplying heated source water to a vacuum deaeration system of water, deaerating water in it using a vacuum deaerator, accumulating deaerated water and supplying accumulated deaerated water to a consumer while maintaining a stable deaeration mode by using a formed deaerated reserve water to compensate for the destabilizing variable flow rate of the consumed deaerated water, characterized in that the formation of the specified compensation of the deaerated water reserve is produced by continuous and forced removal of part of the deaerated water stream at the outlet of the vacuum deaerator and its combination with the source water stream at the inlet of the vacuum deaerator, and the use of the deaerated water reserve thus formed to compensate for the destabilizing variable flow rate of the consumed deaerated water is carried out based on a combination of two simultaneous automated controls: flow continuously and forcibly diverted to the vacuum inlet eaeratora part of the flow rate of deaerated water and applied to the input of the vacuum deaerator untreated water according to the flow of deaerated water consumption, while ensuring a constant in time combined water flow at the inlet and outlet of the vacuum deaerator. 2. The method according to claim 1, characterized in that the double simultaneous automated control specified in claim 1 is carried out provided that the maximum flow rate of the discharged deaerated water exceeds the maximum flow rate of the consumed deaerated water or their equality. 3. A system for vacuum deaeration of water, comprising a pipeline section for the forced supply of heated source water, having an automatic control valve integrated in its pipeline and connected to the inlet of the vacuum deaerator, which is connected by its outlet using the pipeline section of the outlet of deaerated hot water to the tank inlet for accumulating deaerated hot water equipped with a water level sensor associated with the said automatic control valve, and having access to the pipeline section ok consumption of deaerated hot water, characterized in that the pipeline section of the continuous drainage of deaerated water is additionally introduced into the system with a pump built into its pipe having an automatic regulator of the latter’s capacity connected with a water flow sensor at the inlet of the vacuum deaerator, said pipeline section of the continuous drainage of deaerated of water connects the outlet of the vacuum deaerator with an insert into the pipeline of the forced supply of heated source water to the There is a gap between its automatic control valve and the water flow sensor at the inlet of the vacuum deaerator. 4. The system according to claim 3, characterized in that the tank for accumulating deaerated hot water is made in the form of a measured tank with a reduced volume.

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