RU2012141941A - HEATING INSTALLATION AND METHOD OF OPERATION OF HEATING INSTALLATION - Google Patents

Abstract

1. Heating installation for a building with several heating surfaces (5a, b, c), containing at least one heat generator (1), a circulation pump (2), a central regulator for recording the operating states of the heat generator, as well as for determining the required operating parameters such as the temperature of the forward flow and/or the temperature of the return flow of the heating surfaces, the actuators (6a, b, c) as well as the flow and return pipelines (VL, RL) for hydraulic connection in a circular process between the heat generator and the heating surfaces, as well as at least one device for controlling the temperature in the room, which acts on the actuators, characterized in that the heating surfaces (5a, b, c) are configured to be used as a buffer storage for the heat generator (1), and the actuators ( 6a, b, c) of the heating surfaces allow switching the direction of flow of the heating surfaces, and from the central return pipeline (RL) before entering the heat generator (1), a bypass pipeline (3) branches off, which is hydraulically connected to the one located in the outlet from the generator (1) heat direct pipeline (VL) by a diverter valve (4) to bypass the heat generator (1).2. Heating installation according to claim 1, characterized in that the heat generator (1) is a heat generator modulated in operation with a minimum power, such as, for example, a heat pump, a circulating water heater or a comparable heat generator with a structurally determined minimum mass flow of water in heating system.3. Heating installation according to claim 2, characterized

Claims (15)

1. A heating installation for a building with several heating surfaces (5a, b, c), comprising at least one heat generator (1), a circulation pump (2), a central controller for recording the operating conditions of the heat generator, as well as for determining the required working parameters, such as direct flow temperature and / or return temperature of heating surfaces, actuators (6a, b, c), as well as direct and return pipelines (VL, RL) for hydraulic connection in a circular process between a heat generator and heating parameters, as well as at least one device for controlling the temperature in the room, which acts on actuators, characterized in that the heating surfaces (5a, b, c) are made with the possibility of using heat buffer as a buffer store for generator (1), actuators (6a, b, c) of the heating surfaces allow switching the flow direction of the heating surfaces, and a bypass pipe (3) branches off from the central return pipe (RL) in front of the heat generator (1) d is fluidly connected to the waste disposed in the generator (1) Heat flow pipe (VL) the switching valve (4) to bypass the generator (1) heat. 2. A heating system according to claim 1, characterized in that a heat generator modulated in operation with a minimum power, such as, for example, a heat pump, a circulation water heater or a comparable heat generator with a structurally determined minimum mass flow, is used as a heat generator (1) water in the heating system. 3. A heating installation according to claim 2, characterized in that a heat pump is provided as a heat generator (4). 4. The heating installation according to claim 1, characterized in that the heating surfaces (5a, b, c) are equipped with a large, in the current temperature range, thermally effective heat storage capacity, primarily due to the high water content and large dead weight. 5. A heating installation according to claim 4, characterized in that radiators are used as heating surfaces, preferably tubular radiators and / or panel heating devices, such as floor heating, wall heating or ceiling heating. 6. A heating installation according to claims 4 and 5, characterized in that the heating surfaces, in order to achieve a high thermally efficient heat storage capacity, are equipped with built-in or attached parts made of concrete, magnesite or phase-transition materials (PCM) or completely or partially consist of them. 7. The heating installation according to claim 1, characterized in that a controller is used that, on the one hand, registers and evaluates the operating conditions of the heat generator and, on the other hand, by recording the outdoor temperature and comparing it with the programmed, in most cases time-dependent heating curve, determines the necessary operating parameters, such as direct flow temperature and / or return temperature of heating surfaces. 8. The heating installation according to claim 1, characterized in that the actuators belonging to the heating surfaces, which provide a hydraulic connection between the heat generator and the heating surface, affect the mass flow of the coolant and thereby change the heat transfer of the respective heating surfaces and, based on the control signals, change flow directions through heating surfaces. 9. A heating installation according to claims 7 and 8, characterized in that the room temperature control devices that act on the actuators affect the heat transfer of the heating surfaces depending on the entered set values of the room temperatures. 10. The heating installation according to claim 9, characterized in that the room temperature control devices have a switching hysteresis, in connection with which there is an upper shut-off temperature for heating the room, above which further heating of the room is stopped by closing the actuators of the heating surfaces, and also a temperature is provided, at a decrease below which the room is heated by opening actuators. 11. The heating installation according to claim 9, characterized in that the room temperature control devices are in bi-directional interaction with the controller and control and evaluate the gradients of the room temperature changes in the heating and cooling phases of the room and know the thermally effective heat storage capacity of the (located) in the corresponding the surface of the heating surfaces (surfaces) and / or adaptively determined from an assessment of the behavior of heating and cooling of the heating surfaces. 12. The heating installation according to claim 10, characterized in that the room temperature control devices are in bi-directional interaction with the controller and control and evaluate the gradients of the room temperature changes in the heating and cooling phases of the room and know the thermally effective heat storage capacity of the (located) in the corresponding the surface of the heating surfaces (surfaces) and / or adaptively determined from an assessment of the behavior of heating and cooling of the heating surfaces. 13. A method of operating a heating installation with several heating surfaces in a building, the heating installation being made according to the characteristics of one of claims 1 to 12, characterized in that when the lower limit of the power of the heat generator is reached, heat generation, despite the existing need for residual heating of individual heating surfaces, is stopped by the heat generator regulator and the heat for the required residual heating of the heating surfaces by changing the flow direction and the circulation pump is taken from the return flow of the heating surfaces of those rooms the temperature of which has reached the upper cut-off value, and the heat generator regulator controls the built-in bypass the pipeline by the switching valve, as well as by the actuators of the heating surfaces of those rooms whose temperature has reached the upper shutdown value, and switches the actuators so that the coolant flows through their heating surfaces in the opposite direction of the flow from the drain to the inlet, and bypasses the heat generator through the switch the valve and the bypass pipe warm water in the heating system is supplied for the still remaining residual heating of not yet fully heated heating surfaces. 14. The method according to item 13, wherein the change in flow direction is canceled when the heat generator regulator recognizes that again there are enough rooms or heating surfaces that need heating and this need is at least as large as the minimum power heat generator. 15. The method according to PP.13 and 14, characterized in that the change in flow direction is canceled when the room temperature drops below the switch-on temperature.