NL194652C - Flow water heater. - Google Patents

Description

1 194652

Flow water heater

The invention relates to a flow-through water heater, provided with a burner and with a heat exchanger unit consisting of at least two heat exchangers following one another in the direction of flow of the combustion gases, the first of which is directly in the flame area of the burner and a first quantity is added thereto. extracts heat and the second heat exchanger extracts the residual amount of heat from the combustion gases, a controllable means being provided for distributing supplied circulation water over the first and the second heat exchanger, for which control and control means are provided.

Such a flow-through water heater is known from EP-A-0.315.579. The purpose of the first heat exchanger located in the flame area of the burner is to optimize the combustion process and stabilize the flames, thereby preventing the formation of NO-Xn at the burner. This known water heater uses a throttle valve to control the amount of water that is supplied to the first heat exchanger. How the scheme continues to work and with what means is not indicated. Furthermore, there is also a safety provision for switching off the burner and the fuel supply when the temperature exceeds a certain value or when too little water flows through the device. This can lead to undesired interruptions in the operation of the device.

The invention now has for its object to improve the known water heater in such a way that the efficiency thereof becomes higher, while the device will switch off less quickly.

To that end it is provided that control and regulating means are arranged for controlling and controlling the amounts of water flowing through the first and second heat exchangers, the total amount of water flowing through and the amount of heat supplied by the burner, first amount of heat is between 5 and 50% of the total amount of heat generated by the burner, the control and control means being designed such that the surface temperature of the first heat exchanger is measured and at a temperature at which condensation can be formed the temperature of the water flowing through the first heat exchanger is raised, while at too high a temperature of the water flowing through the first heat exchanger, where evaporation thereof could occur, the temperature of the water is lowered, such as by enlargement of the amount of water flowing through.

The invention is further elucidated on the basis of exemplary embodiments shown in the drawing, in which:

Figure 1 schematically shows a circulation flow-through water heater; Figures 2-6 show different embodiments of means for controlling and / or controlling flow-water heaters.

The flow-through water heater 1 shown in Figure 1 has a housing 2 of plate or the like, which comprises a combustion chamber 3. In the combustion chamber 3 is located the gas burner 4, to which gas is supplied via a gas valve 5 and a pipe 6. The gas valve 5 has a pilot motor 7, which is connected via a pipe 8 to a controller 9.

Above the burner 4 is a heat exchanger unit 10, consisting of a first heat exchanger 12 and a second heat exchanger 11. The first heat exchanger 12 is located directly in the flames 34 of the burner 4. Depending on the type of burner, the flames 34 can have individual 45 flames or a continuous flame fire can be formed. The heat exchanger 12 with its tube or tubes will be arranged such that it extracts heat in the area of the flames 34. Preferably, the tubes of the heat exchanger will pass through the core zones of the flames 34, so that the tubes are completely exposed to the flames.

The flow-through water heater 1 serves for supplying a room heating device 15 and / or a storage reservoir for consumable water, not shown (50). From the heating device 15 a return line 17 provided with a circulation pump 16 runs to the heat exchanger 11. From the heat exchanger 11 a discharge line 19 runs, which is provided with a temperature sensor 18. The temperature sensor 18 is connected to the controller 9. The pump 16 is provided with a motor 21, which is controlled via a line 22 from the controller 9. A sensor 23 measures the outside temperature and via a pipe 55 the measured value is supplied to the controller 9. Between the pressure connection of the circulation pump 16 and the connection of the pipe 17 to the heat exchanger 11 there is a branch 25, from which a pipe 26 runs to the connection of the heat exchanger 12. Located in line 26

Claims (2)

The temperature sensor 27 is connected to the controller 9 through the line 28. . The outlet end of the heat exchanger 12 is connected via the further extending pipe 26 to a branch 29 in the outlet pipe 19, which branch is located between the sensor 18 and the outlet of the heat exchanger 11. At the branch 29 are in the pipe 26 a discharge temperature sensor 30 and a flow meter 31 are arranged, each of which is connected to the controller 9 via a line 32 and 33, respectively. The cross-section of the lines 17, 18, 19 and 26 is dimensioned such that heat exchanger 12 can take from 5 to 50% of the total amount of heat supplied by the burner. With reference to Figs. 4-8, possibilities for checking and controlling the water heater are further explained. Figures 2-6 show exemplary embodiments for controlling the optimum water flow through the heat exchangers 11 and 12. According to Figure 2, a temperature sensor 104 in a discharge line from the heat exchanger 11 supplies a signal via control lines 106 to a solenoid valve 107 with which the flow through The heat exchanger 12 is controlled, depending on the measured temperature. According to FIG. 3, the solenoid valve 107 is controlled by a temperature sensor 104, which is mounted in the combustion chamber. In the embodiment according to Figure 4, a temperature sensor 104 is arranged for measuring the temperature of the flame. According to Figure 5, the flow through the heat exchanger 12 is not influenced by a solenoid valve, but by the speed of a pump 109. Control signals are supplied from the temperature sensor 104 via the lines 106 via the lines 106. By way of example, in this case the temperature sensor is again arranged in the combustion chamber. In the exemplary embodiment shown in Fig. 6, signals are supplied to a microprocessor 110 from a number of temperature sensors 104. For example, the temperature of the heated water, of the water supplied to the heating device, the temperature in the combustion chamber and the temperature at placing the heat exchanger 12, which is in the area of the flames. The microprocessor compares individual temperatures with the desired values, or differences between certain measured temperatures, or temporary temperature gradients or gradients of temperature differences. Desired values may be included as predetermined optimum values in a data storage device, which in turn may form part of the microprocessor. The deviations from the measured values can be used to control the amount of gas, the flow through the heat exchanger 12 for cooling the flame or as a signal for safety monitoring against overheating or subcooling as indicated above. Thus, by processing a number of measured temperatures, determining the gradients and the like thereof, a control range is obtained for quickly controlling the total combustion process. 40 Flow-through water heater, provided with a burner and with a heat exchanger unit consisting of at least two heat exchangers successively following one another in the flow direction of the combustion gases, the first of which is directly in the flame area of the burner and extracts a first quantity of heat therefrom and the second heat exchanger extracts the residual amount of heat from the combustion gases, with controllable means for distributing supplied circulation water over the first and second heat exchangers, for which control and control means are provided, characterized in that control and control means are adapted to control and control the quantities of water flowing through the first and second heat exchangers (11 and 12, respectively), the total amount of water flowing through and the amount of heat supplied by the burner (4) such that said first amount heat is between 5 and 50% of the total amount of heat generated by the burner, the control and control means being designed such that the surface temperature of the first heat exchanger (12) is measured and at a temperature 55 at which condensation may occur, the temperature of the the first heat exchanger (12) 3 194652 water is increased, while at too high a temperature of the water flowing through the first heat exchanger (12), where evaporation thereof could occur, the temperature of the water is lowered, such as by enlargement of the amount of water flowing through. Hereby 4 sheets of drawing>