WO1990004140A1 - A heat-storing heating device - Google Patents

Abstract

The invention relates to a heat-storing heating device comprising a heat-storing unit (1) and a heat exchanger (2) serving as a condenser for discharging stored heat by means of a heat transfer medium, such as water, circulated through an evaporation space (3) provided within the heat-storing unit (1) and the heat exchanger (2) by means of a circulation pump (4), the heat-storing unit (1) comprising a frame (5) of a material of high thermal conductivity, such as iron, for use as heat-storing material, and at least one electric resistor (6) arranged to heat the frame (5). In the invention, in order to be able to control the discharge of the heat storing unit within wide limits with very simple means, the evaporation (3, 7) space adjoins directly the heat-storing material, whereby the heat-transfer medium is evaporated on to the surface of the heat-storing material.

Description

A heat-storing heating device

This invention relates to a heat-storing heat¬ ing device comprising a heat-storing unit and a heat exchanger serving as a condenser for discharging stored heat by means of a heat transfer medium, such as water, circulated through an evaporation space pro¬ vided within the heat-storing unit and the heat ex¬ changer by means of a circulation pump, the heat-stor- ing unit comprising a frame of a material of high thermal conductivity, such as iron, for use as heat- storing material, and at least one electric resistor arranged to heat the frame.

German Offenlegungsschrift 3 341 676 discloses a system with a heat-storing unit and a heat ex¬ changer, which is substantially of the type described above. In this system, water is fed into the heat- storing unit by utilizing the thermosiphon phenomenon, and the steam is led into the heat exchanger so as to transfer heat from the heat-storing unit to the heat exchanger and further into the point of application, such as circulation water in a heating system. In this apparatus, the heat-exchanger, serving as a water storage, is positioned above the heat-storing unit in such a manner, however, that water is able to enter the heat-storing unit only when the heating resistor effecting the thermosiphon phenomenon is switched on. Such a control is relatively inaccurate and slow. If the heat-storing unit is discharged wholly, water re- mains in the evaporation space, from where it has to be evaporated before the proper heating of the heat- storing unit.

The object of the present invention is to pro¬ vide a system formed by a heat-storing unit and a heat exchanger, in which the rate of discharge of the heat- storing unit is adjustable within very wide limits with very simple means. Possible applications of the system include room heaters and central units of cen¬ tral heating systems operated by water or air heating systems. This is achieved by means of a heat-storing heating device of the invention, which is character¬ ized in that the evaporation space adjoins directly the heat-storing material, whereby the heat-transfer medium is evaporated on to the surface of the heat- storing material. Thus the best possible heat transfer from the heat-storing material to the heat transfer medium is achieved. The invention further enables efficient adjustment of the rate of discharge with simple means because the discharge is directly de- pendent on the amount of water fed into the heat-stor¬ ing unit. The amount of water to be fed into the heat- storing unit, in turn, can be simply controlled either by varying the rate of rotation of the circulation pump or by adjusting a valve provided in a pipeline between the circulation pump and the heat- storing unit. The high thermal conductivity of iron used as heat-storing material ensures that the temperature gradients occurring in the heat-storing material are only of the order of a few degrees even though the discharge would take place at full capac¬ ity. Therefore the heat-storing unit can be discharged at very even capacity. Being ordinary iron, the heat- storing material is easily weldable so that the evap¬ oration space is easy to seal with weld joints. In the following the structure of one specific embodiment of the heat-storing heating device of the invention will be described by way of example and in greater detail with reference to the attached drawing, wherein Figure 1 is a cross-sectional view of a speci- fie embodiment of the heating device of the invention, and

Figure 2 is a top view of one layer of the frame of the heat-storing unit. Figure 1 shows by way of example one specific embodiment of a heat-storing heating device of the in¬ vention. The heating device comprises a heat-storing unit 1 and a heat-exchanger 2 communicating by means of a steam conduit 11 which passes steam from the heat-storing unit to the heat-exchanger acting as a condenser. The heat-storing unit and the heat-ex¬ changer also communicate by means of a condensate pipe 12 from the condenser, a condensate tank 13, and a pipeline 8 going from the condensate tank through the circulation pump 4 into the heat-storing unit. In this way, a closed circulation loop is formed, in which heat-transfer medium, preferably water, is circulated through the heat-storing unit 1, the heat-exchanger 2 and the condensate tank 13. From the heat-exchanger 2, in the case of the invention always a condenser, heat can be transferred into the desired point of applica¬ tion, such as room air, supply air in an air heating system, or circulation water in a central heating sys¬ tem. In the invention, it is essential that the heat- transfer medium, such as water, is allowed to evapor¬ ate freely immediately upon entering an evaporation space 3 in the heat-storing unit. In the evaporation space, water evaporates directly on to the surface of the heat-storing material. The steam is then passed through a vertical discharge conduit 7 provided within the heat-storing unit and the steam conduit 11 to the condenser 2. As the temperature of the steam entering the condenser is relatively constant, at least when the temperature of the heat-storing material in the heat-storing unit is substantially above 100°C, the amount of heat discharged from the heat-storing unit depends solely on the amount of water passed through it. As a consequence, the discharge of heat from the heat-storing unit can be controlled very simply and accurately by varying the amount of water passed through it. The amount of water can be varied easily either by controlling the circulation pump 4 or, even more simply, by controlling a valve 9 provided between the circulation pump and the heat-storing unit. In this way the discharge of heat from the heat-storing unit 1 can be controlled as desired in a very simple manner.

The heat-storing unit 1 shown in Figure 1 com¬ prises an iron frame 5 serving as heat-storing ma- terial. The frame is formed by several plates 10 piled on top of each other as shown in the figure. Electric resistors, such as pipe resistors 6, are pro¬ vided in every other plate interspace for heating the material, whereas the other interspaces form the evap- oration space 3. By means of the electric resistors 6, the temperature of the heat-storing material can be raised up to about 600°C. To achieve good contact bet¬ ween the resistors 6 and the plates 10, the plates can be piled substantially directly on the resistors 6. In this way, the resistors 6 are pressed on two sides against the relatively heavy plates 10. In order to prevent the flattening of the resistors 6, support pieces 14 can be positioned between the edges of the plates 10, as shown in Figure 1. In addition, the plate interspaces for the resistors 6 are separated from the discharge conduit 7 by means of a ring 15 formed by the support pieces and a gasket. The ring also prevents steam from entering into direct contact with the resistors 6. The evaporation spaces 3, like- wise formed in the interspaces between the plates, are formed similarly by positioning support pieces 16 on the outer periphery of the plates 10. The plates can be positioned at a desired distance from each other by means of the support pieces. In order to prevent steam from escaping across the support pieces 16, they are provided with suitable gaskets. Since the heat-storing material consists of iron, the evaporation space could be sealed easily by means of weld joints as well. The first layer on the outside of the frame 5 consists of a thermally resistant insulation 17 which is further surrounded by a relatively thick additional insulation 18 in order to prevent discharge of heat from the heat-storing unit into the surroundings through ther¬ mal radiation. Figure 2 is a top view of one plate 10 in the frame 5 of the heat-storing unit. It appears from this figure that a guide groove 24 is formed on the upper surface of the plate, on which water evaporates. The guide groove leads the water along a suitable path be- fore being discharged into the discharge conduit 7. The aim is to discharge the heat contained in the plate evenly and, on the other hand, to ensure that water is evaporated before it enters the discharge conduit 7. If, however, liquiform water enters the discharge conduit, it can be passed into the conden¬ sate tank 13 through a pipeline 19 provided in the bottom of the discharge conduit 7.

The heat-storing heating device of the inven¬ tion operates in the following way. First, the core of the heat-storing unit is heated electrically to the desired temperature, e.g., 600°C, preferably by night. Of course, it is also possible to apply lower temperatures, especially when the daily demand of heat remains below the capacity of the heat-storing unit. On initiating the discharge of the heat-storing unit for the first time, the interspaces 3, the discharge conduit 7 and the steam conduit 11 are full of air. The air can be removed in a simple manner. When water is introduced into the evaporation space, it evapor- ates, and with a sufficient amount of feed water, saturated steam is formed in the interspaces to such an extent as to force the air ahead of it into the condensate tank 13. From the condensate tank 13, the air can be removed by means of a bleeding valve 20. This bleeding procedure enables the operation of the apparatus even when the temperature of the heat- storing material is below 100°C. This is because the pressure in the evaporation space and steam conduit drops below atmospheric pressure, still enabling evap- oration of water in the space and emission of heat from the heat-storing material. After the removal of air form the circulation loop, the discharge of the condenser 2 can be initiated, that is, the transfer of heat to the desired point of application from the heat storing unit 1. The discharge of heat from the differ¬ ent portions of the heat-storing unit is controlled by adjusting the valves 9 by a control operating on the basis of temperature measurements, for instance. Tem¬ perature sensors 21 can be positioned in the vicinity of each heating resistor layer 6. By adjusting the valves 9, the discharge can be initiated, for in¬ stance, from the upper portion of the core 5, where- from it is continued evenly downwards in such a manner that the temperature throughout the heat-storing a- terial remains substantially constant. The constant temperature, on the whole typical of the heat-storing material of the heat-storing unit of the invention, increases notably the service life of the resistors 6. This is due to the fact that in this way they are not exposed to rapid temperature changes. Alternatively, it is also possible in the ar¬ rangement of Figure 1 to spray water from the condensate tank 13 by means of a pump 22 into the steam conduit 11 through a nozzle 23 provided therein. Such spraying is necessary if the steam emerging from the heat-storing unit is superheated for one reason or another. For instance, when the dimen¬ sion temperature of the condenser is exceeded, the de¬ gree of superheating can be reduced by spraying, thus causing the steam to be saturated to the right tem¬ perature.

The heating device of the invention has been described above only by way of example by means of one specific example and it is to be understood that it can be substantially modified structurally without deviating from the scope of protection defined in the attached claims and from the procedure of the inven¬ tion by means of which a fully controlled discharge of the heat-storing unit can be effected. Accordingly, several "parallel" heat exchangers could be attached to the heat-storing unit for simultaneous heating of tap water and circulation water in a central heating system.

Claims

Claims :

1. A heat-storing heating device comprising a heat-storing unit (1) and a heat exchanger (2) serving as a condenser for discharging stored heat by means of a heat transfer medium, such as water, circulated through an evaporation space (3) provided within the heat-storing unit (1) and the heat exchanger (2) by means of a circulation pump (4), the heat-storing unit (1) comprising a frame (5) of a material of high ther¬ mal conductivity, such as iron, for use as heat- storing material, and at least one electric resistor (6) arranged to heat the frame (5), c h a r a c t e r¬ i z e d in that the evaporation (3, 7) space adjoins directly the heat-storing material, whereby the heat- transfer medium is evaporated on to the surface of the heat-storing material.

2. A heating device according to claim 1, c h a r a c t e r i z e d in that the frame comprises at least two structural members, whereby the evapor¬ ation space is formed by an interspace (3) between the structural members (10) of the frame.

3. A heating device according to claim 1 or 2, c h a ra c t e r i z e d in that the evaporation space is sealed by means of weld joints.

4. A heating device according to claim 1, c h a r a c t e r i z e d by a valve (9) provided in a pipeline (8) between the circulation pump (4) and the heat-storing unit (1) .

5. A heating device according to claim 2, c h a r a c t e r i z e d by a guide groove (24) pro¬ vided for the heat transfer medium on the surface of the structural member (10) on the side of said inter¬ space (3) .