NO157675B - PROCEDURE AND DEVICE FOR OPERATION OF A HEATING SYSTEM. - Google Patents

Description

As is known, conventional heating systems for heating premises or buildings and producing hot water for consumption, which systems work with a boiler that is heated with a fossil fuel such as oil, gas or the like, have major disadvantages in that a significant amount of the supplied energy goes lost in heat loss with the exhaust gases through the chimney. In order to improve the economics of heating, heat pumps have started to be used which raise heat at a low temperature to a higher temperature level. The most common heat source has thus become air, partly outdoor air and partly indoor air. When using outside air, the disadvantage arises that the heat pump's efficiency drops drastically at low temperatures, e.g. lower than -5°C, at which temperature problems also arise with frost precipitation on the unit. In the case of heat pumps that work with outside air, an additional energy source must therefore be arranged, such as an oil-fired boiler or electric boiler, which works in the coldest season.

Return air as a heat source is only profitable in such applications where a large part of the air is usually ventilated, but which, when using a heat pump, is recirculated via the heat pump.

Attempts have been made to use outside air as a heat source to fill the heat demand only with a heat pump, but the precautions that must be taken to ensure the heat pump's operation at low outside temperatures mean that the heat pump's structure becomes complicated, so that the heat pump becomes expensive both in installation and maintenance. For example, there are heat pumps that work in several stages and raise the air temperature in each stage.

The purpose of the present invention is to provide a method for operating a heating system and a heating system for carrying out the method, where the above-mentioned disadvantages of previously known solutions are eliminated and where a heating system is provided that provides exceptional operating economy at the same time as its function and high efficiency is ensured by

all outdoor temperatures.

This purpose is achieved by the method and the heating system being given the features specified in the following patent claims.

The invention shall be described below in connection with the drawing. Fig. 1 schematically shows a cross-section through a heating system according to the invention. Fig. 2 shows a principle diagram for the heat pump which is part of the system in fig. 1.

In that in fig. 1 shows the heating system 1 denotes a burner for oil or gas, which is arranged in a water-borne boiler 2, to which a tank or a room 13 for hot water preparation is connected. The boiler 2 and the tank 13 are arranged on a support 11. With a space above the boiler 2 and the tank 13, which space forms an air duct 3, a cross-flow heat exchanger 4 and a circulating air heat pump 5 are arranged. Above the heat exchanger 4 there is an extraction chamber 6 equipped with an evacuation fan 7, which is connected to an exhaust pipe 9 for used air or exhaust gases, as will be described below. Reference number 8 indicates a room containing control equipment for the boiler. The entire heating system is arranged in a closed room or boiler room 10.

Connected to the heat exchanger 4 is an intake duct 12 that comes from the outside for fresh air as well as an intake opening 14 for return air from the boiler room 10, which circulates in the plant via the heat exchanger 4 and the heat pump 5, as will be described in more detail below. The heat pump 5 has an exhaust opening 15 for the mixture of fresh air and return air which circulates after passage through the heat pump. Reference number 16 indicates an intake opening for the supply of air from the boiler room 10 to the air duct 3. In the air duct 3, the exhaust duct 17 also opens out for exhaust gases from the boiler 2.

To control the function of the heating system, a number of sensors are arranged which are connected in a way not shown to the control equipment arranged in room 8. Thus, the boiler 2 is provided with a temperature sensor TC 1, the fresh air intake 12 is provided with a temperature sensor TC 2, and the boiler room 10 with a temperature sensor TC 3. A pressure sensor PD 1 and a temperature sensor TC X are arranged in the extraction chamber 6. The burner 1 of the boiler 2 is started and stopped via a control relay denoted by AY.

The heating system shown in fig. 1 works as follows. The heating system has an air flow that circulates through the heat pump 5 and is the result of fresh air coming in via the fresh air intake 12 and a return air flow that is supplied to the heat exchanger 4 via the intake opening 14 together with the fresh air,

and from there is led to the heat pump's 5 evaporators as a heat-emitting medium. In the example shown, where the heat pump is of a type that heats the water in a water-borne ppp heating system, the circulating air is blown out from the heat exchanger 5 via the exhaust opening 15 in the closed room 10, which in the present case is made up of a boiler room where the heating system is arranged. However, it will be understood that the room 10 can be a larger room where the heating system is arranged, whereby the air that is blown out at 15 constitutes the heating medium for the room. It is also conceivable that the exhaust opening 15 from the heat pump 5 is connected to a heating system which works with blowing hot air into the premises to be heated, whereby the exhaust opening 15 supplies air to said system. This naturally assumes that the return air from the ventilation system is returned to the room 10 where the heating system is arranged.

In the embodiment shown, where the heat pump 5 serves to heat circulating water as mentioned above, the air is thus blown out from the exhaust opening 15 into the room 10. From the room 10, a partial airflow flows via the intake opening 16 and the gas channel 3 to the heat exchanger 4, which is of the cross-flow type, the that is to say with two completely closed channel systems which are separated from each other and run in two mutually perpendicular directions. After passing through the heat exchanger 4, this partial air flow which has entered via the opening 16 from the room 10 is evacuated to the atmosphere through the exhaust pipe 9 located above. When passing through the heat exchanger 4, this partial air flow preheats the mixture of fresh air that enters the channel 12 and return air from the boiler room 10 that enters via the intake opening 14 in the heat exchanger 4. The air flow that circulates via the heat pump must be greater than the amount of air that is evacuated via the exhaust pipe 9 , so that there is a higher pressure in the boiler room 10 or in a similar room than in the extraction chamber 6 in the heating system. The described operating condition for the heating system prevails if the circulation ion heat pump primarily alone provides the energy supply to the heating system. When it becomes necessary to increase the energy content of the circulation air flow through the heat exchanger 4 to the heat pump 5, as e.g. in the hot and humid period of the year when the heat pump is only responsible for the energy supply to the heating system, the evacuation fan 7 is started, which increases the flow through the heat exchanger 4 of both evacuated air and incoming fresh air, which has a higher enthalpy. In the colder period of the year or when the outside temperature is low, which is registered by the temperature sensors to be described below, the burner 1 for the boiler 2 is also started, and the exhaust gases from the boiler 2 are supplied through the outlet pipe 17 to the channel! 3. to mix with the evacuation air from the opening 16, whereby the energy content of the air flow from the heat exchanger 4 t'M. heat pump 5: is increased further..

It will be understood from the above description that the combination of; The boiler i2: the heat exchanger 4 and the heat pump 5 result in a system where the heat pump 5 always works under favorable conditions. When the temperature at TC -1 has fallen below a preset value, the heat pump starts, and when the outside temperature -tur.eniived;-TG. 2<.exceeds the preset value, the evacuation fan starts./fbr .to' increase the energy content of the air flow to. Lvarmep.umpenr.3 When in the temperatures- at; TC 1, TC' 2' and- TC 3 at the same time as:'Liggeri.underv the:-respectively set, values,- starts the evacuation vi ften;, and in mar. det1, partial vacuum at, PD' 1-" in ex-suction-ings'chambereti'6i is fell below the set value, the boiler's 2i burner 1 is started by the control relay AY. When the temperature in the boiler room 10 at TC 3 has exceeded the set value, the burner 1 stops, and the evacuation fan 7 and the heat pump 5 consume the accumulated heat in the boiler room and start again when the temperature has fallen below the set value. When the temperature of the water flow at TC 1 has exceeded the set value, the burner and the evacuation fan are stopped, but the heat pump continues to work until a slightly higher temperature is reached at TC 1, and when the temperature drops, the burner and the evacuation fan are restarted.The temperature sensor arranged at TC X in the extraction chamber prevents the burner from starting as long as the temperature is higher than the set value.The circulation pump for the heat pump 5 works continuously.

Due to the feature that the heat pump 5 for the circulation air, the evacuation fan 7 and the boiler 2 are started in series one after the other when the energy demand increases, the most advantageous operating conditions for the plant are achieved. In connection with a water-borne boiler 2 and a heat pump 5 with heating using water, it is appropriate that the water systems for the boiler 2 and the pump 5 are connected in series to achieve a higher output water temperature from the heating system. The combustion air for the burner 1 for the boiler 2, which consists of room air, is dried by condensation by the circulation air heat pump 5, which is why no condensation occurs on the cold duct surfaces.

All condensation of moisture in the fresh air which is introduced through the intake 12 takes place in the heat pump's 5 evaporator section, where the clean condensation water can be collected and removed.

The heat pump that forms part of the system can be of a conventional type, such as e.g. is shown in fig. 2. From the evaporator 30, the working medium flows via a heat exchanger 31 to the compressor 22 equipped with a pressure switch 21 via a non-return valve 32 to a coaxial condenser 24 for heat exchange with water in a water-borne system with inlet and outlet channels 27. From the condenser 24, the working medium flows via a collection tank 25 and a filter 26 back to the heat exchanger 31 and via a thermostatic valve 28 to the evaporator 30. Reference number 29 denotes a rotating fan placed in the evaporator unit. A branch line 33 leading to the evaporator 30 is regulated by a solenoid valve 23. In a heating system that works with hot air, the condenser unit 24 will naturally be given a corresponding shape.

The moisture that occurs during the combustion process condenses in the heat exchanger and releases its condensation energy to the circulating air stream. The acidic condensate with pH on

about. 2.5 is drained off through a neutralization system and led to the drain, giving an acidity of approx. 6 pH.

It is clear that the preceding description does not represent anything other than an advantageous embodiment of the invention and that changes and modifications thereof can be made within the scope of the following claims.

Claims (10)

1. Procedure for operating a heat collection system in a heating system that works with air circulation, which system comprises a heat pump for air circulation, a heat exchanger from an air-gas mixture to air, a boiler for fossil fuel and an evacuation fan, characterized in that a partial flow of the air used in the heating system is led to the heat exchanger as exhaust air from the heating system for heat exchange with supply air from outside and with a return flow of circulation air, as the air flow supplied to the heat pump's evaporator as a heat-emitting medium is made to pass through the heat exchanger and new heat energy is supplied there, and as the air flow in the system that passes through the heat pump is kept greater than the flow of exhaust air or the mixture of fresh air and gas that is evacuated from the heating system through the heat exchanger. 2. Method according to claim 1, characterized in that in the event of an increased need for energy, the partial flow is evacuated by means of the evacuation fan. 3. Method according to claim 1 or 2, characterized in that in the event of an increased need for energy, the partial air flow is mixed with exhaust gases from the boiler. 4. Method according to claim 2 or 3, characterized in that the increased supply of energy is controlled by means of predetermined temperature values for the air in the system. 5. Method according to claims 3 and 4, characterized in that the boiler's burner is only started when the temperature of the consumption air in the heating system is lower than a predetermined value. 6. Method according to any one of claims 3-5, characterized in that the boiler's burner is only started when the evacuation fan has created a predetermined minimum negative pressure between the evacuation fan and the heat exchanger. 7. Method according to any one of claims 2 - 6 in water-borne heating systems, characterized in that the boiler's burner is only started when the water temperature in the water stream leaving the heating system has fallen below a predetermined value and/or the outside temperature has fallen below a predetermined limit value. 8. Heating system for carrying out the method according to any one of claims 1-7, characterized in that the heating system includes a boiler (2) for burning oil, gas or other fossil fuel, a circulating air heat pump (5) for supplying heat to a water or air-borne heating system, a heat exchanger of the cross-flow type (4) for heat exchange between incoming fresh air and return air from the heating system with air that is evacuated from it, and an evacuation fan (7) that evacuates cooled gases from the heating system, and a supply duct (3) to the heat exchanger with inlet openings (16, 17) for evacuation air from the system and exhaust gases from the boiler, which channel (3) is connected to the heat exchanger on the opposite side of the evacuation fan (7). 9. Device according to claim 8, where the boiler (2) and the heat pump (5) are water-borne, characterized in that the water system of the boiler (2) is connected in series with the water system of the heat pump (5) in order to achieve a higher outgoing water temperature from the plant. 10. Device according to claim 8 or 9, characterized in that each unit, such as the air circulation heat pump (5), the heat exchanger (4) of the cross-flow type, the boiler (2), the burner (1) for the boiler (2), the evacuation fan (7) and a control unit (8) for the system, is designed as easily replaceable device modules mounted on a common stand (11) to an integrated unit that is ready for function.