AT398125B - TEMPERATURE CONTROLLER WITHOUT AUXILIARY ENERGY - Google Patents

Description

AT 398 125 B

The invention relates to a temperature controller without auxiliary energy for hot media, in particular for heating systems with a heat exchanger or the like connected downstream of the furnace, with a thermostat actuating an actuator, the heat sensor of which operates as a function of the media temperature, and a distributable bypass flap or the like arranged in the flue gas discharge line , which directs the hot flue gases either directly or via the heat exchanger into the chimney, whereby the actuator or the bypass flap is adjustable by a thermostat, the heat sensor of which is exposed to a sensor temperature that is reduced in a certain ratio to the higher medium temperature.

Modern space heating systems with solid fuel control usually consist of two assemblies with different thermal functions. The first assembly - usually called a furnace - is used to hold the furnace and to release part of the heat generated by the furnace. The second assembly - often called the post-heating box - is a heat exchanger through which the hot flue gases give off their heat to the room to be heated.

Parallel to the flue gas path through the post-heating box, a flue gas path is always provided, which is provided with a bypass valve (heating flap) that can be opened and closed.

The post-heating box can be provided with a heat store. With the help of the bypass flap, the flue gases escaping from the furnace can either be directed directly to the chimney or passed over the post-heating box. The flue gas duct, which is throttled by the bypass flap, can often be found in the post-heating box itself. In newer heating systems, the post-heating box and the furnace are often housed in a single housing.

The invention is intended to automate the adjustment of the bypass flap, each flue gas temperature being assigned a specific bypass flap position. When the flue gases are cold, the flap should be open, when the temperature rises it should gradually close within a range and the flap should be completely closed above a defined and adjustable flue gas temperature. This task must be solved without auxiliary energy, because in many heating systems of the type described, the use of electric motors or the like is. undesirable.

It might seem obvious to solve the problem with a conventional temperature controller without auxiliary energy, as is known for example from the generic DE-OS 31 51 169. However, this is not possible without further ado, because the fillers of the controllers without auxiliary energy or the associated heat sensors, regardless of whether they work according to the principle of vapor expansion or liquid expansion or gas absorption or gas pressure or a similar principle, are used with the high ones Temperatures up to 700 ° C and above, the flue gases under unfavorable circumstances, e.g. if the heating flap is opened accidentally or if the fire output is too high, chemically modified.

From US Pat. No. 4,375,872 it is known to regulate the flue gas temperature by means of a bimetal sensor. German patent application 206 634, published on October 18, 1951, indicates that safety measures must be taken when regulating particularly hot gases so that the bellows of liquid-cooled sensor systems are not damaged.

The invention is based on the object of developing the known temperature controller in such a way that hot media, in particular flue gases, can also be controlled without adverse effects with regard to their temperature if the temperature of the media or flue gases to be controlled is clearly above the stability limit of the fillers or of the filler, whereby no bimetal sensors should be used for this purpose.

According to the invention, this object is achieved in a generic temperature controller in that the heat sensor of the thermostat is supplied with the energy necessary for its adjustability by the thermal radiation of a radiation source, the temperature of which is almost the same as the media temperature to be controlled, the radiation source being from a hot medium heated housing, in which the heat sensor of the thermostat is arranged at a radiation distance from the inner housing wall, and that the interior of the radiation housing or the heat sensor containing the heat sensor of the thermostat can be cooled by a cooling air flow.

With the invention, a temperature controller is created which, without auxiliary energy, permits temperature control of hot media, in particular flue gases, even without disadvantageous effects if the temperature of the media or flue gases to be controlled is above the stability limit of the filler of the heat sensor.

The heat sensor area of the temperature controller according to the invention is therefore not directly exposed to the high temperature of the flue gases or other hot media, but rather to a lower temperature, which is, however, in a fixed relationship or specific relationship to the temperature of the flue gas or other hot media. Air cooling, the cooling capacity of which depends on the temperature of the hot medium or flue gas, is used in a special embodiment of FIG

AT 398 125 B

Invention ensured that part of the radiated energy is dissipated so that the heat sensor temperature does not exceed the desired limits.

In the invention, the heat sensor or thermostat is not arranged in a branch line of the main discharge of the hot media or flue gases, so that the transfer of the correspondingly reduced heat to the heat sensor of the thermostat proceeds without undesirable delay. Rather, according to the invention, the heat sensor of the thermostat is supplied with the energy required for its positioning work by heat radiation from a radiation source, the temperature of which corresponds to the medium temperature to be regulated.

It can advantageously be provided in the context of the invention that the housing consists of a radiation and cooling tube which contains the thermostat and with which the space containing the hot medium, e.g. is connected to a flue gas pipe, wherein at least the pipe wall zone surrounding the heat sensor of the thermostat with radiation spacing essentially assumes the temperature of the hot medium and radiates inwards.

By means of air cooling, the cooling capacity of which depends on the temperature of the hot medium or flue gas, in a further embodiment of the invention it can be ensured that part of the radiated energy is dissipated so that the heat sensor temperature does not exceed the desired limits. For this purpose, it can be provided in one embodiment of the invention that the radiation and cooling tube extends with its lower, open end approximately to the floor near the heated building space.

In one embodiment of the invention it is also provided that the housing or the radiation and cooling tube is at least partially provided with thermal insulation. This makes the control more stable.

The heat transfer by radiation and thus the function of the temperature controller according to the invention is improved if the opposite surfaces of the housing or tube wall and the heat sensor are blackened.

Finally, it can be provided in the context of the invention that the housing or radiation and cooling tube is at least partially arranged in the space containing the hot medium or in the flue gas tube of the heating system.

Further advantageous features of the invention are explained in more detail in the following description.

The invention is illustrated in the drawing, for example. It shows: FIG. 1 schematically, in a vertical longitudinal section, a heating system with a furnace and heat exchanger and radiation and cooling tube of the temperature controller, and FIG. 2 the arrangement of the thermostat and its power transmission means.

In a furnace 1 burns e.g. a solid fire. The flue gases are led to a post-heating box 3 via a flue pipe 2. A bypass flap 4 is provided therein, which in the position shown leads the flue gases directly via a flue pipe section 5 to the chimney inlet 10. The flue gases leave the house via the chimney.

The bypass flap 4 can be closed and opened by means of a lever 7 with the aid of a coupling rod 6. The lever 7 is actuated by a thermostat 8 working with a heat sensor, which is arranged in a radiation and cooling tube 9. Details of this arrangement are shown in the enlarged sectional view of FIG. 2.

The radiation and cooling tube 9 passes through the smoke tube 5. However, the radiation and cooling tube 9 could also be connected to the smoke tube 5 in a way that conducts heat. It is only important that the radiation and cooling tube 9, in the area in which the thermostat 8 is attached, assumes the flue gas temperature as far as possible.

In the arrangement shown in FIGS. 1 and 2, the radiation and cooling tube 9 within the smoke tube 5 almost takes on the smoke gas temperature and radiates the energy thus absorbed inwards. Here, the expansion thermostat 8 is arranged, which is attached with its lower end in a cooler area of the radiation and cooling tube 9. The upper part of the thermostat 8 is led out of the radiation and cooling tube 9 and acts on the lever 7.

The assignment of the position of the bypass flap 4 to the temperature of the thermostat 8 can be changed by turning a setpoint adjuster 11.

Cooling air can move between the thermostat 8 and the radiation and cooling tube 9. The smaller the distance between the thermostat 8 and the radiation and cooling tube 9, the higher the temperature of the thermostat 8 and vice versa. The radiation and cooling tube 9, which is open at the bottom, draws the cooling air preferably from a zone just above the floor of the boiler room, because there the air temperatures are generally more constant than at other heights. 3 AT 398 125 5

It can be advantageous to isolate the radiation and cooling tube 9 in whole or in part, so that changing temperatures in the vicinity of the radiation and cooling tube 9 do not influence the cooling air flow as far as possible.

The minimum length of the radiation and cooling tube 9 depends on the length of the thermostat 8. In 5 the radiation and cooling tube 9 is generally at least three times longer than the thermostat 8.

From Fig. 2 it can also be seen that the upper part of the radiation and cooling tube 9 is connected to a circuit board 12 on which a pivot bearing 13 is fastened, in which the lever 7 is pivotally mounted.

By turning the set point adjuster 11, the temperature can be set at which the thermostat 8 starts to pivot the lever 7 and thus the bypass flap 4. From a certain w deflection of the thermostat 8, the bypass flap 4 has reached the position shown in dashed lines in FIG. 1. In this position, the hot flue gases entering the afterheating box 3 through the smoke pipe 2 are directed downwards via the heat exchange surfaces on the left side of the afterheating box 3 in FIG. 1 and upwards on the right side in FIG. 1 and then via the pipe section 5 directed into the chimney inlet 10. The flue gases give off heat to the room to be heated via the post-heating box 3.

In order to achieve the most constant possible heat radiation from the radiation and cooling tube 9 on the thermostats 8 at each flue gas temperature, the opposite surfaces thereof can be blackened. In this way, the heat radiation energy transferred is relatively independent of whether these surfaces have their radiation and absorption properties through deposition, dust 20 or the like. change. Polishing the inner surface of the pipe would increase the amount of energy transferred, but the amount of energy that is decisive for the temperature of the thermostat 8 would change more in percentage terms due to dust and dirt deposits than when the surfaces of the thermostat 8 and the radiation and cooling tube were blackened 9.

The operation of the arrangement described above is as follows: 25 After a fire has been ignited in furnace 1 and the flue gases of this fire move towards the chimney, the walls surrounding the flue gas flow begin to heat up. As long as the wall temperature of the flue gas path is lower than the flue gas dew point, flue gases will condense. The condensation zone will initially be found in furnace 1. If the temperature of the walls surrounding the flue gas path rises, the condensation zone shifts over the flue pipe 2, 30, the post-heating box 3 and the pipe section 5 into the chimney inlet 10 and gradually rises up to the chimney crown as the chimney heats up. When the condensation zone reaches the upper edge of the chimney, the bypass flap 4 should be closed. If the chimney temperature is so low that the condensation zone is always below the chimney crown, the masonry can become damp, or in the case of clay pipe or metal pipe chimneys 35, the condensation products flow down the chimney and exit there.

This condition of condensation inside the chimney should be avoided. The temperature of the walls at the chimney top must be above the dew point. On the other hand, the flue gas temperatures at the chimney head should not get higher, because otherwise the flue gases would uselessly release energy into the free atmosphere. The chimney is at the correct temperature if, on the one hand, the condensation limit is close to the edge of the chimney and, on the other hand, there is sufficient draft in the chimney to discharge the gaseous combustion products of the stove into the atmosphere. Depending on the chimney situation, this correct flue gas temperature will correspond to a specific temperature of the flue gas in the flue section 5. By means of the thermostat 8, this temperature can be kept constant in that the flue gases in the afterheating box 3 would be cooled by heat. -45 to the surrounding space or a surrounding heat store just enough that the correct temperature prevails in the pipe section 5.

With the energy given off or stored in the after-heating box 3, the surrounding space is heated immediately or after a certain time. This energy depends on the position of the flap 4. Regardless of this flap 4 is the energy that is supplied directly from the furnace 1 and the flue pipe 2 to the environment.

The correct temperature at the chimney inlet depends, among other things, on the height and cross-section of the chimney or also whether other fireplaces are connected to the chimney and the like. It is therefore necessary, when setting the thermostat 8, to measure the chimney so that on the one hand it does not scotch and on the other hand does not dissipate unnecessary energy into the free atmosphere. 55 Unfavorable circumstances, e.g. sticking of the bypass flap 4 or an incorrectly dimensioned furnace 1 can lead to very hot flue gases flowing through the flue pipe section 5. In the invention, it is ensured that the thermostat 8 is not destroyed thereby, since the thermostat 8 is not in direct connection with the flue gas pipe section 5, but rather through heat radiation 4

Claims (6)

AT 398 125 B is heated by the radiation and cooling tube 9. This energy transfer from the radiation and cooling tube 9 to the thermostat 8 takes place at the speed of light. Therefore, in the case of a sufficiently thin radiation and cooling tube 9, the energy required for heating the thermostat 8 is transferred extremely quickly, in any case much faster than by simple heat conduction. If you imagine 5 that the temperature in the smoke tube section 5 quickly increases from the temperature of the surrounding space to a higher value, then the thin wall of the radiation and cooling tube 9 will also heat up with little delay and practically at the same time thermal energy on the surface of the Transfer thermostats 8. The thermostat 8 thus reacts almost as quickly to changes in temperature in the flue pipe section 5 as if it were directly exposed to the flue gases. Because of the absorbed radiation energy, the thermostat 8 and thus also the gap between the thermostat 8 and the radiation and cooling tube 9, which can be approximately 5 to 20 mm in size. Since the air inside the radiation and cooling tube 9 is now lighter than outside the radiation and cooling tube 9, an air flow is created which cools the thermostat 8. The speed of this air flow and thus the cooling capacity depends on the temperature in the gap between the 75 thermostats 8 and the radiation and cooling tube 9 and the size of this gap. The higher this temperature, the greater the buoyancy within the radiation and cooling tube 9 and the more energy is dissipated. By properly dimensioning the gap between the thermostat 8 and the radiation and cooling tube 9 it can be ensured that each smoke gas temperature is reproducibly assigned a lower sensor temperature, and that even at high temperatures in the smoke tube section 5 the thermostat 8 is not overloaded, although it Temperature changes in smoke pipe section 5 follows very quickly. The arrangement of the thermostat 8 in the cooling and radiation tube 9 thus causes a reduction in the temperature signal. A change of e.g. 700 ° C of the flue gas is a change of e.g. only assigned 25 200 * C of the thermostat. Similar to the space heating systems with solid fuel firing described at the beginning, hot water heating systems are also possible which consist of a normal hot water boiler and a downstream hot water heat exchanger. Using a bypass flap, the flue gases generated in the boiler can be led directly to the chimney at a low temperature, analogous to the air heating described, and can be cooled to a specified value via the exhaust gas heat exchanger at a high temperature. With the heat exchanger e.g. Industrial water is generated, the heating water is preheated or the like. The temperature controller described above can also be applied to the control of other hot media if their temperature exceeds the permissible operating temperature of the thermostat 35. 1. Temperature controller without auxiliary energy for hot media, in particular for heating systems with a 40 heat exchanger downstream of the furnace or the like, with a thermostat actuating an actuator, the heat sensor works depending on the media temperature, and an adjustable bypass flap arranged in the flue gas discharge line or the like , which directs the hot flue gases either directly or via the heat exchanger into the chimney, whereby the actuator or the bypass flap is adjustable by a thermostat, 45 whose heat sensor is exposed to a sensor temperature that is reduced in a certain ratio to the higher medium temperature, characterized that the heat sensor of the thermostat (8) the energy necessary for its adjustability by the heat radiation from a radiation source, the temperature of which is almost the same as the media temperature to be supplied The radiation source consists of a housing heated by the hot medium, in which the heat sensor of the thermostat (8) is arranged at a radiation distance from the inner housing wall, and that the interior of the radiation housing or the heat sensor of the thermostat (8) contains the heat sensor can be cooled by a flow of cooling air. 2. Temperature controller according to claim 1, characterized in that the housing consists of a radiation 55 and cooling tube (9) which contains the thermostat (8) and with which the hot medium containing space, e.g. is connected to a flue gas pipe (5), with at least the pipe wall zone surrounding the heat sensor of the thermostat (8) with radiation spacing essentially assuming the temperature of the hot medium and emitting it to the inside. 5 AT 398 125 B 3. Temperature controller according to claim 1 or 2, characterized in that the radiation and cooling tube (9) extends with its lower, open end approximately to the floor near the heated building room. 4. Temperature controller according to one of claims 1 to 3, characterized in that the housing or the radiation and cooling tube (9) is at least partially provided with thermal insulation. 5. Temperature controller according to one of claims 1 to 4, characterized in that the opposite surfaces of the wall of the housing or the radiation and cooling tube (9) io and the heat sensor are blackened. 6. Temperature controller according to one of claims 1 to 5, characterized in that the housing or radiation and cooling tube (9) is arranged at least partially in the room containing the hot medium or in the flue gas pipe (5) of the heating system. is 1 sheet of drawings 20 25 30 35 40 45 SO 6 55