DE19526419A1 - Heater pump duty allocation - Google Patents

Abstract

During operations, the speed of the pump (16) is raised smoothly or in stages to a higher value once the actual feed temperature approaches the ideal temperature by 1-3 K, and during standstill the pump is driven at lower speed for a preset period. The pump is run at low speed during heater start-ups regardless of the ideal/actual temperature mismatch. Pump speed is reduced at the same time as the heater is cut out. Thus with the burner (2) cut out at ideal temperature, the pump is run at a higher speed for a few seconds to remove the exchanger (3) heat and is (16) then slowed down or cut out to save energy, storing all these period times in the ideal transducer (27). When heat is required, the pump is run slow during burner start-up (2) and continued until the ideal/actual temperature mismatch has been reduced to a preset level.

Description

The invention relates to a method for operating a Heating system according to the preamble of claim 1.

When operating such a heating system, the Circulation pump with constant speed constantly in operation If necessary, the circulation pump is switched off during burner downtimes during lowering times or while provided during summer operation.

However, this still results in the disadvantage of an ent speaking high proportion of auxiliary energy that is necessary for the operation the circulation pump must be provided.

The aim of the invention is to avoid this disadvantage and a To propose the procedure of the type mentioned at the beginning, in which only a small amount of auxiliary energy must be provided. According to the invention, this is done in a method of the beginning mentioned type by the characterizing features of claim 1 reached.  

The proposed measures ensure that the circulation pump during most of the operation time of the heating system is operated at a low speed or stands still and therefore only a correspondingly low lei must provide.

When the heater is in operation, the circulation pump is switched on as long as the Difference between the target flow temperature and the actual flow running temperature is above a specified value, with low engine speed, regardless of the operating state of the Heater, that is, regardless of whether the heater with Is operated at full load or with partial load.

The increase in the speed of the circulation pump shortly before it is reached the target flow temperature increases the switching capacity ability of the heater. So through the increase the speed of the circulation pump the water temperature spread reduced on a heat exchanger of the heater. Thereby becomes the upper switching point, that is the target flow temperature ture achieved later due to the smaller spread and thereby more energy is inserted into the entire heating system per burner run brings, which even after switching off the heater lower switching point at which the heater starts again tes takes place, is achieved later.

When the target flow temperature is reached, the heater switches discourages. The speed of the circulation pump will be until the next Start the heater or up to the otherwise specified Ab Circulation pump circuit reduced.  

Due to the features of claim 2 results from the predominantly low pump speed in addition to reducing the Auxiliary energy needs the benefit of a reduction or wise avoidance of condensation when starting a burner-operated heater and a reduction avoidance of flow noises.

With a modulating heater based on "high Deviation between actual and target flow temperature = full load " and "small target-actual temperature deviation = partial load" results due to the low speed of the circulation pump during operation the heater also has the advantage that it is correspondingly fast there is a high flow temperature and therefore the heater, longer than this at higher speeds of the circulation pump would be operated in the partial load range. It comes under other continue to reduce the switching frequency of the heater.

The features of claim 3 give the advantage that the speed of the circulation pump with decreasing differences difference between the target and actual flow temperatures more and more is increased, which continues to save on aid result in energy.

The features of claim 4 ensure that the Residual heat from the heater quickly disappears after it is shut down can be performed and that it does not lead to the training of Boiling noise comes.  

Due to the features of claim 5, the advantage arises very low or nonexistent heating medium flow through the heating network, for example when the thermostat is closed valves that quickly turn off the heater leads.

In order to minimize the switching frequency of the heater and to increase its efficiency and reduce the emission of harmful substances, it is advantageous to carry out the method according to the invention in accordance with the features of claim 6. The proposed measures ensure that on the one hand, by increasing the speed of the circulation pump from, for example, 750 min ^-1 to, for example, 1850 min ^-1 , more heating energy is fed into the heating system during the burner runtime and by the reduction the speed of the circulating pump from, for example, 1850 min ^-1 to 750 min ^-1 during the rest of the time, the energy is drawn from the heating system accordingly slowly and the auxiliary energy requirement is minimized. Overall, this results in a considerable reduction in the switching frequency of the heater.

Due to the features of claim 7, due to the predominantly low pump speed of, for example, 750 min ^{-1, in} addition to the reduction in the auxiliary energy requirement, there is the advantage of a reduction in the switching frequency of the heating device. In addition, the low speed of the circulating pump prevailing at the start of the heating device in a new cycle largely prevents condensation from forming in a burner-driven heater and reduces or prevents flow noise.

The invention will now be explained in more detail with reference to the drawing.

Show:

Fig. 1 shows schematically a heating installation,

FIG. 2a is a diagram of the course of the flow temperature of the heating pump at a low speed operation of the circulation, for example, 750 min ^-1,

Fig. 2B is a diagram of the switching behavior of the heating device of the heating system at a low speed operation of the circulation pump in order,

Fig. 2c is a diagram of the pump operation,

Fig. 3a is a diagram of the course of the flow temperature of the heating system in an operation of a heater after which he inventive method,

Fig. 3b is a diagram of the switching behavior of the heating device of the heating system during operation according to the inventive method and

Fig. 3c is a diagram of the pump operation according to the inventive method with a low speed of, for example, 750 min ^-1 and when approaching the upper switching point with a higher speed of, for example, 1850 min ^-1 .

A heating system 1 has a heat exchanger 3 acted upon by a burner 2 , which is connected via a feed line 4 to a heating system 5 , which has radiators, for example. This heating system 5 is connected via a return line 6 to the inlet of the heat exchanger 3 , the return line 6 from a lead to a circulating pump 16 , the connecting line 7 and one of the circulating pump 16 to the connecting line 10 is formed, which is the connection to the heat exchanger 3 manufactures.

The burner 2 can be supplied with gas via a gas line 15 in which a proportionally working gas valve 18 provided with a drive 17 is arranged.

The drive 17 of the valve 18 is connected to a control unit 19 via a line 23 . A flow temperature sensor 20 , which is arranged in the flow line 4 , is also connected to the control unit 19 via a line 21 . Next, a motor 22 , which drives the circulation pump 16 and its speed can be changed, is connected via a line 25 to the control unit 19 , which in turn is connected via a line 26 to a setpoint generator 27 .

The control unit 19 determines the difference between the actual flow temperature detected by the temperature sensor 20 and the set value of the flow temperature determined by the setpoint generator 27 . The circulation pump 16 is operated during operation of the burner 2 at a low speed of, for example, 750 min ⁻¹ , as long as the difference between the target value of the flow temperature and the actual flow temperature does not fall below a certain minimum value, approximately 1 to 3 K.

If this point is reached, the pump is operated at a higher speed, for example 1850 min ^-1 . The performance of the burner 2 can also be reduced by throttling the valve 8 .

If the burner 2 is turned off when the desired flow temperature is reached, the pump is operated for a predetermined short period of time, for example a few seconds, at high speed in order to remove the heat from the heat exchanger 3 . After that, the circulation pump 16 is operated for a certain time at a low speed and / or stopped to save energy. These times are stored in the target value transmitter 27 .

If there is a heat request again, the circulation pump 16 is operated at low speed during the start of the burner 2 . This operation of the pump 16 is maintained until the difference between the actual flow temperature and the target value of the flow temperature has dropped to a predetermined low value.

The speed of rotation of the circulation pump 16 can be increased in stages or continuously.

Fig. 2a shows the course of the flow temperature in a heating system according to FIG. 1, which is operated with a continuously low speed of, for example, 750 min ^-1 running circulation pump 16 . It can clearly be seen that there is a frequent oscillation of the flow temperature between a cut-off temperature and a switch-on temperature for the heating device.

This can also be clearly seen from FIG. 2b, and from FIG. 2c it can be seen that the circulation pump 16 is continuously operated at a low speed.

Fig. 3a shows the course of the flow temperature at an operation of a heater according to the invention. In this case, the heating device is switched on when the burner has reached the switch-on temperature, and, as can be seen from FIG. 3c, the circulation pump 16 is operated at a low speed.

If the actual temperature of the flow temperature approaches 3 to 1 K of the target temperature or the switch-off temperature, the speed of the circulation pump 16 is increased to, for example, 1850 min ^-1 , as a result of which the flow temperature drops somewhat and then slowly rises again, until the switch-off temperature is reached.

If this is the case, the burner is switched off and the speed of the circulation pump 16 is reduced to the low speed. After that, the flow temperature briefly exceeds the switch-off temperature and then slowly drops until the switch-on temperature is reached. If this is reached, the switching cycle is repeated and the burner is started, but the circulation pump is operated at the low speed.

Claims (7)

1. A method of operating a heating system ( 1 ) with a stage or continuously modulating heater and an at least two-stage switchable circulation pump ( 16 ) which is arranged in a line ( 6 ) connecting the heater to a heating system ( 5 ), as characterized by that when the heater is operating, the speed of the circulation pump ( 16 ) is increased from a low value to a higher value when the actual value of the flow temperature approaches a set value of, for example, 1 to 3 K, the target value of the flow temperature Has. 2. The method according to claim 1, characterized in that the circulating pump ( 16 ) during the standstill of the heater for a predetermined time at low speed be driven. 3. The method according to claim 1 or 2, characterized in that the speed of the circulation pump ( 16 ) is increased in several stages or continuously. 4. The method according to any one of claims 1 to 3, characterized in that after the Errei Chen the target flow temperature and thus the shutdown of the heater, the circulating pump ( 16 ) is operated for a predetermined short time at high speed before the order circulating pump ( 16 ) stopped or their speed is reduced. 5. The method according to any one of claims 1 to 4, characterized in that the circulating pump ( 16 ) during the starting process of the heating device, regardless of the difference between the desired flow temperature and the actual pre-running temperature, is operated at a low speed. 6. The method according to claim 1, characterized records that the pump speed at Errei the set temperature of the flow temperature the pump speed to the lower Value is lowered.   7. The method according to claim 6, characterized in that the reduction in the speed of the circulating pump ( 16 ) takes place simultaneously with the shutdown of the heater, the circulating pump being approximated up to 1 to 3 K to the target temperature -Temperature of the flow temperature is operated in a subsequent cycle at the low speed.