SE503763C2 - Heat storage heater - 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

503 765 10 15 20 25 30 35 2 of the system includes heaters for individual rooms or central units in central heating systems operated by means of water or air heating systems. This is achieved by means of a heat-storing heating apparatus according to the invention, which is characterized in that the evaporation space adjoins directly the heat-storing material, the heat transfer medium being evaporated on the surface of the heat-storing material. Thus, the best possible heat transfer from the heat storage material to the heat transfer medium is achieved. The invention also makes it possible to effectively regulate the discharge rate by simple means since the discharge is directly dependent on the amount of water fed into the heat storage unit. The amount of water to be fed into the heat storage unit can in turn be easily controlled by either varying the rotational speed of the circulation pump or by setting a valve arranged in a pipeline between the circulation pump and the heat storage unit. Iron that has good thermal conductivity is used as heat-storing material, which ensures * that the temperature gradients. as. occurs in. the heat-storing material is only in the size class a few degrees even if the discharge were to take place with full effect. Due to this, the heat storage unit can be discharged with very even power. Since the heat-storing material is ordinary iron, it is easily weldable so that the evaporation chamber can be easily sealed with welds.

In the following, the construction of a specific embodiment of the heat storage apparatus according to the invention is described by means of an example and in more detail with reference to the accompanying drawing, where Figure 1 is a cross-section of a specific embodiment of the heater according to the invention, and Figure 2 shows a layer of the heat storage unit body from above from above.

Figure 1 shows a specific embodiment of a heat storage heater according to the invention by means of an example. The heating apparatus comprises a heat storage unit 1 and a heat exchanger 2 which are connected by means of a steam duct 11 which conveys steam from the heat storage unit to the heat exchanger acting as a condenser. the heat storage unit and the heat exchanger are also connected to each other by means of a condensate pipe 12 from the condenser, a condensate container 13, and a pipeline 8 which runs from the condensate container through the circulation pump 4 to the heat storage unit. In this way a closed circulation loop is formed, in which heat transfer medium, preferably water, is circulated through the heat storage unit 1, the heat exchanger 2 and the condensate container 13. From the heat exchanger 2, which in the case according to the invention is always a condenser, heat is transferred to the point of consumption, such as to room air, supply air for an air heating system, or circulating water in a central heating system. It is essential for the invention that the heat transfer medium, such as water, is allowed to evaporate freely immediately after it has reached an evaporating chamber 3 in the heat storage unit. In the evaporation chamber, water is evaporated directly on the surface of the heat-storing material. The steam is then fed to the condenser 2 through a vertical discharge channel 7 and the steam channel 11 arranged inside the heat storage unit. Since the temperature of the steam introduced into the condenser is relatively constant, at least when the temperature of the heat storage material in the heat storage unit is substantially above 100 ° C, the amount of heat dissipated from the heat storage unit depends solely on the amount of water passed through it. Consequently, the heat dissipation from the heat storage unit can be controlled very simply and accurately by varying the amount of water passed through it. The amount of water can be easily varied either by controlling the circulation pump 14 or by setting a valve 9, which is arranged between the circulation pump and the heat storage unit. Thus, the heat dissipation from the heat storage unit 1 can be controlled as desired in a very simple manner.

The heat storage unit 1 shown in Figure J. comprises an iron body: 5 which functions as heat storage material. The frame consists of several plates 10 stacked on top of each other as shown in the figure. Electrical resistors, such as pipe resistors 6, are arranged in every other space between the plates for heating the material, while the other spaces form the evaporation space 3. By means of the electrical resistors 6 the temperature of the heat storage material can be raised to about 600 °. C. To provide good contact between the resistors 6 and the plates 10, the plates can be stacked substantially directly on the resistors 6. Thus, the resistors 6 are pressed against the relatively heavy plates 10 from two directions. To avoid flattening of the resistors 6, support pieces 14 can be placed between the edges of the plates 10, as shown in figure 1. In addition, the plate gaps of the resistors 6 are separated from the diverter channel 7 by means of a ring 15 formed by the support pieces and a seal. The ring also prevents steam from coming into direct contact with the resistors 6. The evaporation spaces 3, which are also formed in the plate gaps, are formed in the same way by arranging support pieces 16 on the outer periphery of the plates 10. The plates can be at a desired distance from each other with the aid of the support pieces. To prevent steam from flowing out through the support pieces 16, these are provided with suitable seals. Since the heat-storing material is iron, the evaporation chamber could easily be sealed even with welds. The first layer on the outer side of the body 5 consists of a heat-resistant insulation 17 which is further surrounded by a relatively thick insulation 18 to prevent heat dissipation in the form of heat radiation from the heat storage unit to the surroundings.

Figure two shows a plate 10 in the body 5 of the heat storage unit from above. From this figure it can be seen that a guide groove 24 is formed on the upper surface of the plate, on which water is evaporated. The guide track directs the water along a suitable path before it is diverted in the drainage channel 7. The intention is that the heat in the plate is diverted evenly, and on the other hand, to ensure that the water is evaporated before it is introduced into the drainage channel 7. enters the drain channel, it can be introduced into the condensate container 13 through a pipeline 19 arranged in the bottom of the drain channel 7.

The heat storage heater according to the invention operates as follows. First, the core of the heat storage unit is electrically heated to a desired temperature, e.g. 600 ° C, preferably at night. Of course, it is also possible to use lower temperatures, especially since the daily heat demand is lower than the heat storage unit's capacity. When the discharge of the heat storage unit begins for the first time, the gaps 3, the discharge duct 7 and the steam duct 11 are filled with air. The air can be removed easily. When water is introduced into the evaporation chamber, it evaporates, and with a sufficient amount of feed water, so much saturated steam is formed in the spaces that it forces the air in front of it into the condensate tank 13. From the condensate tank 13 the air can be removed by means of an aeration valve 20.

This aeration measure makes it possible to use the appliance even when the temperature of the heat-storing material is below 100 ° C. This is because the pressure in the evaporation chamber and the vapor duct falls below the atmospheric pressure, which still enables the evaporation of water in the space and heat emission from the heat-storing material 505 763 10 15 20 25 30 35 6. After air has been removed from the circulation loop, the discharge of the condenser 2 can begin, ie. the transfer of heat from the heat storage unit 1 to where it is needed. The heat dissipation from the various parts of the heat storage unit is controlled by setting the valves 9 e.g. using control based on temperature measurements. Temperature sensors 21 may be located in the vicinity of each heating resistance layer 6.

By installing the valves 9, the diversion can be initiated e.g. from the upper part of the core 5, from where it continues evenly downwards so that the temperature throughout the heat-storing material remains substantially constant.

Constant temperature, which is generally typical of the heat storage material in the heat storage unit according to the invention, increases the service life of the resistors 6 considerably. This is because they are not exposed to rapid temperature changes.

Alternatively, in the device according to Figure 1, it is also possible to spray water from the condensate container 13 by means of a pump 22 into the steam channel 11 through a nozzle 23 arranged therein. Such spraying is necessary if the steam coming from the heat storage unit is overheated for any reason. For example. when the dimensional temperature of the condenser is exceeded, the degree of overheating can be lowered by spraying, and the steam is thus saturated to the correct temperature.

The heater according to the invention has been described above only as an example by means of a specific example and it is obvious that its construction can be modified substantially without deviating from the scope of protection as defined in the appended claims and the method according to the invention by means of a completely controlled discharge. of the heat storage unit can be achieved. Consequently, several "parallel" heat exchangers can be connected to the heat storage unit 503 763 7 for simultaneous heating of tap water and circulation water in a central heating system.

Claims (3)

10 20 25 503 763 Claims A heat storage heater comprising a heat storage unit (1) and a heat exchanger (2) which acts as a condenser for dissipating stored heat by means of a heat transfer medium, such as water, which is circulated through an evaporating chamber (3) arranged inside the heat storage unit (1) and the heat exchanger (2), by means of a circulation pump (4), the heat storage unit (1) comprising a body (5) of a material with good thermal conductivity, such as iron, for use as heat storage material, and at least one electrical resistor (6) arranged to heat the body (5), characterized in that the evaporation chamber (3, 7) adjoins directly the heat-storing material and is sealed by means of welds, the heat transfer medium being evaporated on the surface of the heat-storing material . Heating device according to Claim 1, characterized in that the frame comprises at least two structural elements, the evaporation space consisting of a space (3) sealed by means of welds between the structural elements (10) of the frame. Heating apparatus according to claim 2, characterized in that a guide groove (24) is provided for the heat transfer medium on the surface of the structural element (10) on the side of said gap (3).