DE102024200584A1 - Storage system with cooling circuit - Google Patents

Abstract

The invention relates to a storage system for storing thermal energy with a charging circuit comprising, in direct or indirect sequence, an evaporator and a compressor, a heat exchanger coupled to a heat accumulator, and a throttle. For this purpose, the charging circuit is supplemented by a cooling circuit. This circuit comprises, in direct or indirect sequence, the compressor, a cooling circuit throttle, and a mixing device, wherein water can be introduced into the cooling circuit via the mixing device.

Description

TECHNICAL FIELD

The invention relates to a storage system for storing thermal energy, wherein thermal energy is stored in a heat storage unit via a charging circuit. A temporary water supply enables reliable start-up.

BACKGROUND

Especially when renewable energy is available, energy is available during periods when there is no demand for it. In contrast, periods in which the supply of renewable energy is insufficient to meet demand must be bridged. Various storage technologies are used to balance energy generation and demand.

One well-known option is to store excess heat and electricity as thermal energy in heat storage systems. This thermal energy can then be recovered at a later time.

In one known design, a charging circuit is formed with an evaporator, a compressor, the heat accumulator, and a throttle. In this case, waste heat from other processes or energy generated from renewable sources is advantageously fed to the evaporator. The compressor is also advantageously driven using energy generated from renewable sources.

If additional energy is required at a different time, the energy can be recovered from the heat storage by using it to evaporate and superheat water so that the steam can be used in a steam turbine, for example to drive a generator.

However, starting the charging process is problematic, especially when all components of the charging circuit have cooled down. Excessive pressure and temperature changes must be avoided.

SUMMARY OF THE INVENTION

The object of the present invention is to enable gentle start-up of a charging circuit of a storage device.

The object is achieved by an embodiment of the invention according to the teaching of claim 1. Advantageous embodiments are the subject of the subclaims.

First, a storage system is used to store thermal energy with a charging circuit, which comprises, in direct or indirect sequence, an evaporator and a compressor and a heat exchanger coupled to a heat storage unit and a throttle.

According to the invention, the charging circuit is supplemented by a cooling circuit. This comprises, in direct or indirect sequence, the compressor, a cooling circuit throttle, and a mixing device, whereby water can be introduced into the cooling circuit via the mixing device.

DESCRIPTION OF THE INVENTION

A storage system of this type is used to store thermal energy. It comprises a charging circuit and a discharging circuit.

The charging circuit comprises, in direct or indirect sequence, an evaporator, a compressor, a heat exchanger, and a throttle. The heat exchanger is coupled to a heat accumulator for storing thermal energy.

The charging circuit operates when the storage system is in a charging state. Water is first evaporated as it passes through the evaporator. The steam is then compressed by the evaporator and thus heated. As the steam flows through the heat exchanger, the thermal energy contained in the steam is partially removed and transferred to the heat storage tank. The cooled steam then passes through the throttle before flowing back to the evaporator.

To enable a gentle start with a reduced temperature and pressure gradient in the charging circuit, a cooling circuit is used. A portion of the mass flow in the charging circuit is diverted during the storage system's start-up and directed through the cooling circuit. Initially, the entire mass flow can also be directed into the cooling circuit.

For this purpose, the cooling circuit comprises, in direct or indirect sequence, the compressor, a cooling circuit throttle, and a mixing device. It is essential that water can be introduced into the cooling circuit via the mixing device.

The cooling circuit with the supply of water enables controlled heating and controlled pressure build-up in the charging circuit.

It is particularly advantageous if the temperature and pressure in the charging circuit can be regulated. For this purpose, the flow through the cooling circuit can be advantageously regulated with a circulation valve.

Furthermore, in order to regulate the temperature and pressure in the charging circuit, the amount of water introduced into the cooling circuit can advantageously be regulated by a water valve.

For this purpose, the temperature in the charging circuit, in particular between the compressor and the heat accumulator, is preferably determined. This makes it possible to control the amount of water supplied and the steam flowing around the cooling circuit depending on the temperature and/or a temperature change.

Particularly preferably, a permissible temperature gradient and/or a limit curve for the temperature gradient is defined as a function of the absolute temperature. When the charging circuit is started, the current temperature gradient is determined. The water flow can then preferably be regulated as a function of the difference between the current temperature gradient and the permissible temperature gradient or the limit curve.

It is particularly advantageous to provide a multi-stage arrangement instead of a single-stage compression and heat dissipation via the heat exchanger.

For this purpose, the charging circuit comprises, in direct or indirect sequence, the evaporator, a first compressor, a first heat exchanger, a first line section, a second compressor, a second heat exchanger, a second line section, a final compressor, a final heat exchanger, and the throttle. The heat exchangers are obviously coupled to the heat storage unit.

Furthermore, it can advantageously be provided that the arrangement is expanded by one or more additional stages. Accordingly, the charging circuit comprises, in direct or indirect sequence between the second line section and the last compressor, a third compressor, a third heat exchanger, and a third line section.

In order to ensure a smooth start of the storage system in the charging circuit, the arrangement of the cooling circuit according to the invention can be provided on one of the compressors.

In the case of multiple stages with compressors, a respective cooling circuit is preferably arranged on at least two of the compressors. Particularly preferably, this involves a first cooling circuit on the first compressor and a second cooling circuit on the second compressor.

In principle, it is also possible to operate the charging circuit with a medium other than water/steam. For example, higher efficiency can be achieved using CO2 as the medium—albeit with greater effort.

Other media, particularly those exhibiting a phase change between gaseous and liquid within a technically feasible range, can also be used. Accordingly, the use of alternative media instead of water/steam in the charging circuit is expressly considered to be encompassed by the invention.

BRIEF DESCRIPTION OF THE DRAWINGS

• The FIGURE schematically outlines an exemplary storage device with charging circuit and cooling circuit.

DESCRIPTION OF THE EMBODIMENTS

The figure schematically shows a storage device 01 with a charging circuit 11. The essential element of the storage device 01 is the heat accumulator 02. Arrows symbolize the flow direction in the circuits 11.

The charging circuit 11 comprises a first compressor 13.1 by means of which the steam in the charging circuit 11 is compressed and thus heated.

The first compressor 13.1 is followed by a first heat exchanger 12.1, which is coupled to the heat storage unit 02. In this regard, it is initially irrelevant whether the first heat exchanger 12.1 is located directly adjacent to or within the heat storage unit 02. It can also be arranged separately, and, for example, a flow of a storage medium from the heat storage unit 02 through the first heat exchanger 12.1 back into the heat storage unit 02 can be provided.

During operation of the charging circuit 11, heat energy is released via the first heat exchanger 12.1 to heat the heat storage tank 02.

A second compressor 13.2 and a second heat exchanger 12.2 are installed downstream of the first heat exchanger 12.1. The same applies here as for the first compressor 13.1 and the first heat exchanger 12.1.

Furthermore, in this embodiment, a third compressor 13.3 and a third heat exchanger 12.3 are sketched.

Finally, there is a final compressor 13.n and a final heat exchanger 12.n, which also transfers heat energy to the heat storage 02.

Downstream in the charging circuit 11, the design includes a throttle 15 and an evaporator 14. Advantageously, regenerative thermal energy is supplied to the evaporator 14.

The starting of the charging circuit 11 becomes more controllable in terms of pressure and temperature by the arrangement of a cooling circuit according to the invention.

In this example, a first cooling circuit is arranged on the first compressor 13.1 and a second cooling circuit is arranged on the second compressor 13.2.

Each cooling circuit has a cooling circuit throttle 16.1, 16.2 and a mixing device 17.1, 17.2. Water can be supplied to the mixing device 17.1, 17.2, which can then be supplied to the cooling circuit and subsequently to the charging circuit 11.

Claims (5)

Storage system (01) for storing thermal energy with a charging circuit (11), which (11) comprises, in direct or indirect sequence, an evaporator (14) and a compressor (13.1, 13.2, 13.3, 13.n) and a heat exchanger (12.1, 12.2, 12.3, 12.n) and a throttle (15), wherein the heat exchanger (12.1, 12.2, 12.3, 12.n) is coupled to a heat accumulator (02); characterized by a cooling circuit, which comprises, in direct or indirect sequence, the compressor (13.1, 13.2) and a cooling circuit throttle (16.1, 16.2) and a mixing device (17.1, 17.2), wherein water can be introduced into the cooling circuit via the mixing device (17.1, 17.2). Storage facility (01) to Claim 1 , wherein the flow through the cooling circuit can be regulated by a circuit valve; and/or wherein the amount of water introduced can be regulated by a water valve. Storage facility (01) to Claim 1 or 2 , wherein the charging circuit (11) comprises, in direct or indirect sequence, the evaporator (14) and a first compressor (13.1) and a first heat exchanger (12.1) and a first line section and a second compressor (13.2) and a second heat exchanger (12.2) and a second line section and a last compressor (13.n) and a last heat exchanger (12.n) and the throttle; and/or wherein the charging circuit (11) comprises, in direct or indirect sequence between the second line section and the last compressor (13.n), a third compressor (13..3) and a third heat exchanger (12.3) and a third line section. Method for starting the charging process of a storage system (01) according to one of the preceding claims, wherein the temperature in the charging circuit (11), in particular between the compressor (13.1, 13.2, 13.3, 13.n) and the heat accumulator (02), is determined and the amount of water supplied is regulated as a function of the temperature and/or a temperature change. Procedure according to Claim 4 , wherein a permissible temperature gradient and/or a limit curve for the temperature gradient is defined as a function of the absolute temperature and the current temperature gradient is determined, wherein the water quantity is regulated as a function of the difference between the current temperature gradient and the permissible temperature gradient or the limit curve.