SK8614Y1 - Connection of the block for heating the heat- transfer medium, the block of accumulation cells and the source with extended accumulation and control range - Google Patents

Abstract

The connection of block for heating the heat- transfer medium, the block of accumulation cells and the source with extended accumulation and control range. The source contains device for heating of the medium and accumulation cell connected to the power source via electrical node. The accumulation cells are connected between power source and delivery point. The block for heating the heat-transfer medium is s intended to heat the water if the electrical power at the point of connection of the electricity produced by the source (3) to the power system is reduced to a minimum power source.

Description

The technical solution relates to a circuit with an extended accumulation and control range of electrical power supplied to the power system, where the electricity is produced by a source for producing electricity and / or for producing electricity and heat.

BACKGROUND OF THE INVENTION

One of the major problems in the electricity industry is the limited possibility to store electricity in its original form. Therefore, there is currently a focus on maintaining a balance between the production and consumption of electricity at all times. This is the responsibility of the central control system in the electricity system. Ancillary services shall be purchased by the transmission system operator to ensure compliance with the quality of electricity supply and the operational reliability of the electricity system through system services. Activation of ancillary services results in the supply of regulatory electricity. In particular, heating and power plants producing electricity and heat from coal, natural gas or other fuels provide support services to a greater extent. However, the scope of the provision of ancillary services is limited from above by the installed electrical power of the source and the minimum operational-technical output from below. Minimum operational power is the power at which the power supply can still be operated stably. For some sources, this minimum or the whole band may be obstructed by the obligation to supply heat.

The reason for the impossibility of reducing the power of a heat source for generating electricity by simply reducing the power of the turbine is a certain control band of the turbine and steam boiler operation where the turbine and the boiler can be operated optimally. At the same time, if high heat demand from the off-take condensing turbines is required to meet the demand for heat, high electricity production on the high-pressure part of the turbine is also forced, even at times when electricity supply needs to be regulated. The steam turbine can be shut down and the heat supply can be realized by reducing, throttling and cooling the heel produced in the boilers, but this presents some disadvantages, the system is operated with high pressure and temperature parameters and it is time consuming to restart the turbine. it limits the life of the turbine and is accompanied by considerable losses from start-up and required power.

When generating electricity in a turbine / generator, it is given a minimum limit of its sustainable output. This minimum turbine power limit can be increased by the demand for heat supply from the turbine draw. If the turbine power demand is required to control the electrical power, this minimum turbine power may be exceeded and the turbine operating in an unstable mode. For this reason, only the scope of functioning given by its technical and operational capabilities influenced by forced electricity production in demand for heat supply (forced increase in electricity production in cogeneration mode) can be used.

The need for greater scope and possibilities for regulating the electricity system has been increasing rapidly in recent years. The reason is the increase in the installed capacity of renewables (renewable energy sources across European countries, the operation of which depends on weather conditions and the possibility of predicting the operation and production of electricity 'is minimal. As a result, electricity on exchanges is sold at negative prices (surplus). other moments is its shortage and the price is above average.

The presently known method for solving electricity power regulation for ancillary transmission systems is solved in the document No. 5956 entitled System for rapid regulation of tertiary power output for ancillary transmission system services, which contains at least one group of diesel generators located in the upstream of the transmission system. If the secondary regulation becomes stable at the maximum level and the balance deviation increases, the central dispatching manually activates the tertiary regulation. 3-, 10-, and 15-minute reserves, either plus or minus, offsetting the secondary control so that it can drop. Specifically for Slovakia, if a high-power atomic power plant fails, fast support services are activated as a priority. j. The 3-minute positive on Čierny Váh, in the 10-minute service, the transmission system has various types of steam-gas all over Slovakia or diesel generators. Diesel engines are not environmentally friendly.

As is apparent from the foregoing, the current power generation sources do not have the inadequate ability to dynamically change the range of power supplied to the electricity grid, while maintaining a stable and efficient operation of the power supply, and in particular without the need to waste some of the generated electricity.

The essence of the technical solution

These shortcomings are overcome by the technical solution, the connection of the hot water heating unit, the accumulator cell block and the power supply with an extended accumulation and control range of the electrical power supplied to the power system, where the electricity is produced by the source for electricity production and / or

S K 8614 Υ1 for electricity and heat production. At the same time, the control range of the source itself is limited from above by the given maximum power of the source and from below the minimum power of the source at which the source can still be operated stably.

The principle of an extended storage and regulation range is that the hot water heating block and the storage cell block are connected through an electrical node to conduct the output to the mains, and it is important that they are installed at the source upstream of the connection point. heat) produced by the source to the power system. The hot-water heater block comprises a high-efficiency electric heater for heating the hot-water medium and, together with the electric accumulator from the accumulator block, is connected to the electrical node tj to conduct the electrical power of the source in the substation. In addition, the blocks' have their own control systems with at least one control means, which are operatively interconnected (via information flows, control and command) to the control and information system (RIS) of the dispatching controlled electrical stations.

The accumulator cell block preferably comprises at least one unified battery or accumulator. The accumulator cell block, if it contains more accumulator cells, comprises an accumulator transformer, has a voltage converter connected before it is connected to the tapping point, i. j. customer.

A preferred embodiment is to install the accumulator cell block in front of the point of connection of the power produced by the source to the power system. This block of storage cells is designed to regulate the power supply of electricity supplied to the electricity system, if necessary. At the same time, it is advantageous to install a block for heating the hot water medium which is connected to. a steam or hot water heat exchanger of the source for heating the heating water by steam. The hot water heating block is designed to heat the water in case of need to reduce the electric power at the connection point to the power system below the minimum power of the source. High efficiency electric heater, resp. a plurality of electric water heaters from the hot water heating block are / are arranged to heat at least a portion of the cooled chilled water returned to it before entering the steam or hot water exchanger or to additionally heat at least a portion of the water coming from the heat exchangers to the heat consumers can also be combined.

The connection can be used for unattended operations, in which case it is equipped with a surveillance system and a remote control system of the communication system.

The purpose of the present invention is to connect a hot water medium heating block, a storage cell block and a power supply with an extended storage and control range, which not only guarantees a wider and more dynamic control range of the electrical power supplied to the power system, use in times of high demand or in crisis management in the electricity system (start from tirra, operation in island mode).

Advantageously, wiring with extended accumulation and regulation range provides a source of income for power plants as market electricity prices are low today and the cost of regulatory energy and deviations is significantly higher. The technical solution utilizes the interconnection of heat production with the increase of electricity consumption in heat sources for the production of electricity or electricity and heat, while neither electric nor thermal energy will be wasted, but purposefully used.

BRIEF DESCRIPTION OF THE DRAWINGS

The technical solution is explained in more detail with the help of the drawings, on which the br. 1 schematically illustrates a schematic of one of the possible arrangements of a hot water medium heating block and a storage cell block; and FIG. 2 schematically illustrates a wiring control, regulation and communication system with an extended electrical power storage and control range that is part of the wiring according to the technical embodiment.

EXAMPLES

The example of an embodiment with an extended accumulation and control range of electrical power supplied to the power system is not a limitation of the technical solutions, but an illustration of a particular embodiment. The arrangement and particular technical solution of the power system will depend on each particular source 3 for electricity production and heat production. There are limiting factors in the disposition arrangement of the power and heat production source 3, the parameters of the power output, the parameters of the heating medium, the specifics of the local market for the central heat supply and the like.

An example of an embodiment with an extended accumulation and control range of electrical power supplied to the power system according to Figure 1 is described.

S K 8614 Υί of a hot-water medium, which is one high-efficiency electric heater for heating a hot-water medium and a block 2 of storage cells AC1-ACn, where the index n indicates the number of storage cells and the size of the index i is not limited by which the storage cell is unified. These are connected to an electrical node 5 in the substation where they are connected to the power supply 4 to the source 3, of which only the heat exchanger 3a of the water heater with the steam supply 6 is shown in the figure. The cooled water 7 is returned from the heat draw-off points 11 to the heater, respectively, if the electrical output suddenly falls below the control range of the source 3. electric boiler from block 1 for heating a hot water medium, where it is heated by consumption of electricity produced by the source 3.

The increase in self-consumption of electricity can be realized, for example, by switching on the charging mode of the accumulation cell A C of the electric power from block 2 of the storage cells and switching on the high-efficiency electric water or other heat transfer medium from block 1 of the hot water heating device n.

Increasing the power consumption can also be realized by switching on the charging mode of the storage cell block 2 and by switching on the high-efficiency electrical heating of the hot water medium from the block and the hot water medium heating equipment for the source's own needs 3,

Increasing the power consumption can also be realized by switching on the charging mode of the storage cell block 2 and by switching on the high-efficiency electrical heating of the hot water medium from the block and the hot water medium heating equipment for the own needs of the source 3a. at the same time for the supply of electricity and hot water at the offtake point 11.

The team is Part ⁵ of electricity stored in the battery block 2 of accumulating articles and consumed for heat production and also will supply 3 operated in the normal operating range, because there is no falling below the minimum operating performance. In this solution to increase the self-consumption of electricity and thereby reduce the aggregate power of the electricity system below a sustainable level, in terms of the source, a power accumulator is installed at the electrical output of the source 3 and an existing heat exchanger 3a is installed. high-efficiency electric water heater.

Black and white

The technical solution is industrially applicable in the electricity industry, in the field of support services of electricity transmission system operators, such as primary and secondary regulation, reduction and regulation of power output for the supporting transmission systems, crisis management in the electricity system, etc.

N E 8614 Υ1

List of reference marks

Although the block of hot water heating equipment block of accumulation cells block electricity and / or electricity production atepl heat exchanger: water heating source electricity supply electric node heel supply chilled water heating water no voltage voltage transformer accumulation point acuration cell · ok

RS control system

KS comics system

RP regulatory means

Claims (7)

1. Connection of a hot-water titanium block, an accumulator cell block and a power supply with an extended accumulation and control range of electrical power supplied to a power system in which electricity is produced by a power generation and / or power and heat generation of the source itself limited by the above maximum power of the source and from the bottom-side power of the source, characterized in that it comprises a block (1) of hot water heating equipment, a block (2) of accumulation cells (AC1) - (ACn) and a source (3) for generating electricity and / or generating electricity and heat, comprising a water source heat exchanger (3a), a hot water medium heating block (I), and a storage cell block (2) - (ACn) ) contain their own control means (RP) and control system (RS) and are connected by a two-way communication system (KS) to and an information system (RIS), wherein the hot water heating device block (s) and the storage cell block (2) are powered by a power supply (4) produced by the power supply (3) and / or power and heat generation via an electrical node (5) and are included between a source (3) for producing electricity and / or for producing electricity and heat and at least one sampling point (11). Connection according to claim 1, characterized in that the block (i) of the hot-water medium heating device comprises at least one electric heater and the storage cell block (2) comprises at least one storage cell (AC), a battery and / or a supercharger. Connection according to claims 1 and 2, characterized in that the storage cell block (2) comprises an accumulator transformer (10), Connection according to claims 1 and 2, characterized in that the electric heater from the block (i) of the hot-water heating device installed to the steam or hot-water exchanger (3a) of the hot-water supply (8) is arranged by steam. for heating the returned cooled water (7) from the tapping points (II), before it enters the steam or hot water exchanger (3a). Connection according to claims 1 and 2, characterized in that the electric heater from the block (1) of the heating medium of the aqueous medium installed to the steam or hot-water exchanger (3a) and the steam heater for heating the hot water (8) by steam. It is arranged for additional heating of the heating water (8) coming from the exchangers (3a) to the heat collection points (11). Connection according to claims 1, 2, 4 and 5, characterized in that the electric heater from the block (J) of the hot water medium heating device installed to the steam or hot water heat exchanger (3a) of the hot water heating source (6). 8) the steam is arranged to heat the cooled water returned (7) from the heat collection points (U) before it enters the steam or hot water exchanger (3a) and at the same time to reheat the water leaving the heat exchanger (3a) to the collection points (il) ) heat. Connection according to claims 1 and 2, characterized in that the communication system (KS) is equipped with a monitoring system and a remote control system of the communication system (KS).