RU2547680C1 - Heat accumulator with phase transition material - Google Patents

Abstract

FIELD: heating.

SUBSTANCE: heat accumulator with phase transition material includes case filled with heat accumulating material with phase transition within work temperature range, heat exchange surface, and electric heating element, and features intermediate cover and solar radiation receiver; heat exchange surface consists of vertical tubes distributed through the whole volume of accumulator tank and filled with phase transition material, and electric heating element housings installed in vertical tubes; heat carrier passes in the intertubular space upwards, and empty cavity serving as chamber for phase transition material expansion from vertical tubes is positioned on top, above intermediate and sealed cover, while accumulator tank bottom is comprised by solar radiation receiver.

EFFECT: enhanced efficiency of heat accumulation and exchange with system heat carrier due to increase and regular distribution of heat exchange surface through the whole volume of accumulator tank.

4 dwg

Description

The invention relates to a power system and can be used to accumulate thermal energy, mainly solar and wind.

Known high-temperature battery heater [1], comprising a housing provided with a layer of insulation on the side of its inner surface, in which a heat storage element provided with a housing is housed coaxially with the housing. The heat storage element is made in the form of a block of parallel rows of hollow cylinders filled with a substance that changes its state of aggregation in the range of operating temperatures, and the cylinders are installed in oval holes made in the casing and are located in each row parallel and perpendicular to the cylinders of adjacent rows. The heating of a high-temperature battery heater can be carried out both by hot gas and by an electric heater. In the first case, hot gas is passed through the casing until the substance with which the heat-accumulating elements are melted is melted, after which the heating stops and the heater is purged with the heated gas. When the battery heater is heated by electricity, electric heaters are placed in the casing, the heat from which melts the substance in the heat-accumulating elements.

The disadvantage of this heater is the inefficient use of phase-transition heat-accumulating materials for heat storage due to the low thermal conductivity of solid phase-transition materials in a large tank volume and low heat exchange with the heat carrier throughout the volume and the need for periodic removal and installation of an electric heater when the heater is heated using electricity.

A known installation for implementing the method of operation of the heat accumulator at the phase transition [2]. The installation consists of a vertical shell-and-tube heat exchanger having an inlet chamber and a tube board at the bottom, in which, for example, four groups of tubes are fixed, the latter leaving respectively in four outlet chambers, each of which has a shut-off device at the outlet to the network, respectively. Between the tube plate and the chamber there is an annular space. For four groups, tubes are arranged in such a way that around each of the tubes of one group there are tubes of three other groups at the vertices of a regular hexagon.

The disadvantage of this device and method of thermal storage at the phase transition is that the heat transfer is carried out in a certain sequence, which is difficult to carry out automatically, and if manually, it is not convenient.

Closest to the claimed one is an electric heater [3], which contains a housing divided by a transverse perforated partition into upper and lower chambers, the first of which is equipped with a nozzle for supplying a heated coolant, and the latter is filled with a heat-accumulating substance with a phase transition in the operating temperature zone and equipped with an electric heating element. The electric heater is equipped with an additional transverse partition placed in the upper chamber with the formation of a cavity between the additional and perforated partitions, the volume of which is equal to the difference between the volumes of the heat-accumulating substance in the solid and liquid state at the melting point of the substance. An electric heating element with one end (lower) is electrically connected to a transverse perforated partition, which is made of metal, and the side walls of the housing and the heat-accumulating substance are made of insulating material. The bottom case is sealed with a sealed plug with a threaded connection, and the top is covered with a cover. A contact terminal is connected to the partition. At the bottom of the case is a second contact terminal. The electric heating element is provided with a central metal base, electrically and mechanically connected to the partition. The upper end of the electric heating element is connected to the base. The electric heater is equipped with an air vent. A pipe is used to drain the water. Electric heaters can be included in the heating system both in their nominal position and rotated 180 ° relative to their horizontal axis. The connection of electric heaters is carried out by pipes using couplings. Electrical connection of electric heaters is carried out by threaded couplings.

The disadvantage of this electric heater is the complexity of the design, the presence of an intermediate chamber, inefficient heat transfer between the phase-transfer heat-accumulating material (FTAM) and the consumer (room) and the inability to use it to accumulate solar thermal energy directly.

The objective of the invention is to ensure the stability of heat supply to buildings from renewable energy sources through the use of energy-intensive phase transitions of materials and increase heat transfer.

The technical result achieved in the claimed invention is to increase the efficiency of heat storage and heat exchange with the system coolant by increasing and evenly distributing the heat exchange surface area throughout the volume of the storage tank and the possibility of using it to accumulate solar thermal energy and electricity from wind energy devices.

To achieve this technical result, the heat accumulator housing with phase transition material further comprises an intermediate cover and a solar radiation receiver, the heat exchange surface consists of vertical tubes located inside the entire volume of the storage tank and filled with material with a phase transition, while electric heating elements are installed in the vertical tubes moreover, the coolant passes from bottom to top along the annular space, and from above above the intermediate and sealed cover of races a free cavity is laid, which acts as a chamber for expanding the phase transition material, and the bottom of the storage tank is made by a solar radiation receiver.

The proposed heat accumulator with phase transition material is illustrated in figures 1-4, where FIG. 1 is a main view of a heat accumulator with phase transition material (longitudinal section), FIG. 2 is a transverse section AA, FIG. 3 is a top view of an intermediate tank cap. battery and figure 4 - mounting an electric heater; where 1 is the case; 2 - working substance (phase transition heat storage material - FTAM); 3 - vertical tubes; 4 - bottom of the storage tank - solar radiation receiver; 5 - an intermediate cover; 6 - holes for the passage of vertical tubes; 7 - holes for mounting bolts; 8 - fixing bolts; 9 - cavity chamber for expansion of FTAM; 10 - sealed tank cover; 11, 12 - nozzles for supply and removal of coolant, respectively; 13 - electric heating elements; 14 - threaded ferrule; 15 - jumpers for attaching a threaded ferrule with an electric heating element to a vertical tube.

The heat accumulator with phase-transition material contains a housing 1, a working substance (FTAM) 2, filling vertical tubes 3, which are attached to the bottom 4, which can also serve as a receiver of concentrated solar radiation (SI), and an intermediate cover 5 with holes 6 for passing tubes and 7 for mounting bolts 8, the tubes are closed from below and open above for volumetric expansion of the FTAM 2 into a free cavity chamber 9 under a sealed cover 10, which is fastened through the gaskets to the main tank body with nuts and bolts 8 . To the body of the storage tank 1 are welded nozzles inlet 11 and outlet 12 of the coolant. In the vertical tubes 3 with FTAM, electric heating elements 13 are inserted, which are connected by electric wires to a source of electrical energy, for example, a wind power installation. Electric heating elements 13 are screwed into a threaded ferrule 14, which is attached to vertical tubes 3 with FTAM jumpers 15.

The heat accumulator with phase transition material operates as follows.

The lid 10 of the heat accumulator is removed, and the tubes 3 are filled with phase-transition heat-accumulating material 2, and the lid is closed. The battery with phase-transition material of heat is charged due to solar energy directed by the mirrors to the bottom 4 of the storage tank - the SR receiver, while due to the high thermal conductivity of the steel tubes 3 and the casing of the electric heating elements 13, the intensive melting of the working substance 2 occurs in them, volume the expansion of the working substance occurs in a free cavity-chamber 9 under a sealed cover 10. Charging can also occur due to electrical energy when the source is connected to an electric heating element am 13 in vertical tubes 3 with FTAM 2, then the heat carrier is heated in the annular space of the storage tank, which is supplied from below through the pipe 11 for supplying the coolant and is discharged through the pipe 12 of the outlet. If a heat accumulator with phase-transition material is used in traditional systems of heat supply using fossil fuels, the working substance melts (the battery is charged) due to the heat carrier (hot water) in the annulus. During an increase in the heat load or the absence of solar energy, the battery is discharged, and the coolant in the annular space of the storage tank is heated due to the phase transition (crystallization) of the working substance 2 in the tubes 3 evenly throughout the volume of the storage tank. Cases of electric heating elements installed in vertical tubes with FTAM, and in the absence of electric energy, act as heat exchangers.

Thus, the proposed heat accumulator with phase transition material is easy to maintain, differs from the known high efficiency of heat storage and heat exchange with the system coolant due to the location of electric heating elements, the increase and uniform distribution of the heat exchange surface area over the entire volume of the storage tank.

BIBLIOGRAPHIC DATA

1. G.I. Babayants, P.P. Kuznetsov, A.I. Dementiev, V.M. Yaroslavtsev, G.S. Kozak. "High-temperature battery heater", copyright certificate No. 857656, F24I 7/00, F28D 17/00, bull. No. 31, 08/23/81.

2. B.Z. Tokar, A.A. Plotnikov, E.V. Kotenko. "The method of operation of the heat accumulator at the phase transition", copyright certificate No.RU 2049968 C1, F24H 7/00, 02.24.1992.

3. I.P. Kolesnichenko, V.V. Fokin. "Electric heater", copyright certificate No. SU 1688071 A1, F24H 7/00, 1/20, bull. No. 40, 10.30.91.

Claims (1)

A heat accumulator with phase transition material, comprising a housing filled with a heat storage material with a phase transition in the operating temperature zone, a heat exchange surface, an electric heating element, characterized in that the housing further comprises an intermediate cover and a solar radiation receiver, the heat exchange surface consists of vertical tubes located inside the entire volume of the storage tank and filled with material with a phase transition, and the covers of electric heating elements installed vertical tubes, the coolant passes upwardly through the annulus, and the top of the intermediate cover and sealed cavity is free, serving as expansion chamber for fazoperehodnyj material and the bottom of the storage tank by the receiver of the solar radiation.

Images