DE3446167C2 - - Google Patents

Description

The invention relates to a control device according to the Ober Concept of claim 1.

With regard to the most economical use of energy and The lowest possible production costs are oil-fired steel Boilers for heating systems have been developed characterized by a small kettle content. Such cauldrons may not be below a certain temp operating temperature, otherwise there is a risk of con formation of condensate in the furnace, which leads to destruction corrosion of the boiler.

With such boilers, it is therefore necessary to also only low heat requirements, for example at the time of night setback, to keep the boiler temperature at a certain value, for example 45 °.

This is e.g. B. achieved (DE-PS 29 19 751) that the Burner is turned on as soon as the boiler temperature falls below this value. Lies for maintenance flow temperature required at a certain room temperature temperature lower than the boiler temperature, so the flow temperature by means of a downstream of the boiler Mixing valve regulated. Will the setpoint for the lead temperature increases, for example by switching from Night reduction to normal operation, the controller will open it  of the mixing valve. But it can happen that so large amounts of cooled return water in the boiler inflow that the boiler temperature below the required Minimum temperature drops.

This problem is solved in that in the loop a special thematic thermostat is installed, which when it drops the temperature in the boiler return closes the mixing valve, so that the amount of from the heater return to the boiler flowing water is restricted. This solution sets that a forced circulation of the water from Boiler flow to the boiler return takes place, and conditionally usually an additional circulation pump (technical Rundschau October 1968, pp. 3-7, 15).

It is also known (DE-PS 32 35 364), with a warm water heating system to regulate the flow temperature so that the difference between the flow and return temperatures is kept at a setpoint. When using a This setpoint should rise so that the condensation boiler the return temperature is one below the condensation limit temperature does not exceed. To Maintaining the setpoint is on the mixing valve acted.

The invention has for its object to a controller develop compliance with a minimum boiler temperature without an additional boiler return thermostat or similar guaranteed additional facility.  

According to the invention, this object is achieved by means of the in the mark of claim 1 specified features solved.

An embodiment of the invention is shown in the drawing represents and is described in more detail below. It shows

Fig. 1 is a functional diagram of a heating system to be controlled and

Fig. 2 shows an electrical schematic diagram of a Regelge device.

A heating system shown schematically in FIG. 1 has the following structure:
A boiler flow 3 leads from a boiler 1 with a burner 2 to a mixing valve 4 . A heating flow 5 leads from the mixing valve 4 to radiators 6 . The heating circuit is closed by a heating return 7 connected to the radiator 6 with a circulating pump 8 , which branches in front of the boiler 1 into a boiler return 9 leading to the boiler 1 and a valve 10 leading to the mixing valve 4 . There is a boiler sensor 11 measuring the boiler temperature in the boiler 1 , and a flow sensor 12 measuring the flow temperature at the heating flow. Another temperature sensor, the outside sensor 13 , measures the outside temperature. The mixing valve 4 is actuated by a drive 14 .

In the heating system shown in Fig. 1, a three-way mixer is installed as a mixing valve 4 . In a somewhat modified structure of a heating system, a four-way mixer is used, where the heating return 7 and boiler return 9 are then connected directly to the four way mixer and the bypass 10 is omitted.

To a control device 15 shown in FIG. 2, three temperature sensors are connected on the input side, namely the boiler sensor 11 , the flow sensor 12 and the external sensor 13 . Outputs of the control device 15 lead to the burner 2 and the drive 14 .

In a control circuit 16 , the command values for the heating system are formed from the temperature measured by the external sensor 13 on the one hand and the signal emitted by a setpoint generator 18 containing a time switch 17 , namely the normalized voltage applied to a line 19 corresponding to the setpoint temperature for the boiler 1 and the normalized voltage present on a line 20 corresponding to the target temperature for the heating flow 5 . In the line 20 leading from the control circuit 16 to a first differential amplifier 21 there is a resistor 22 , the effect of which will be described later. The Diffe ence amplifier 21 compares the voltage applied to the line 20 clamping voltage for the set temperature of the heating-forward 5 with the controls from the submitted to flow sensor 12, the temperature measured at Heating flow 5 Tempera ture representing voltage and a Schalteinrich tung 23 of the drive 14 of the mixing valve. 4 This control operation causes the opening of the mixing valve 4 when the measured temperature of the heating-forward is smaller 5 than the target temperature for the heating flow 5, and closing of the mixing valve 4 when measured at the heating flow 5 temperature is greater than the target tempering temperature for the heating flow 5 . Opening the mixing valve 4 means that the opening cross-section between the boiler flow 3 and the heating flow 5 is increased and the opening cross-section between the bypass 10 and the heating flow 5 is reduced, so that more hot water from the boiler flow into the heating circuit ( 4, 5 , 6, 8, 7, 10 ) is fed. Accordingly, closing the mixing valve 4 means that the opening cross section between the boiler flow 3 and the heating flow 5 is reduced and the opening cross section between the bypass 10 and the heating flow 5 is increased, so that less hot water from the boiler flow 3 is fed into the heating circuit.

The voltage emitted by the boiler sensor 11 and representing the temperature in the boiler 1 is compared by means of a further differential amplifier 24 with the voltage present on the line 19 and representing the target temperature of the boiler 1 , and also by means of a further differential amplifier 25 with that from a setpoint generator 26 emitted voltage, which - adjustable bar - represents the limiting temperature for the boiler 1 . At the output of the differential amplifier 24 there is then a voltage which corresponds to the difference between the actual and target temperature of the heating element 1 , and at the output of the differential amplifier 25 a voltage which corresponds to the difference between the actual temperature of the heating boiler 1 and the limiting temperature .

From these two voltages, the value corresponding to the higher temperature is selected with the aid of a linkage of 27 , which then influences a flip-flop 28 . The flip-flop 28 controls a burner relay 30 via a transistor 29 , which switches the burner 2 on and off. The flip-flop 28 is dimensioned such that the switch-on and switch-off point for the burner relay are at a certain switching difference of, for example, 6 degrees apart. The lowest possible switch-on temperature for boiler 1 , the minimum boiler temperature, is the difference between the limit temperature and half the switching difference.

In order to achieve the effect according to the invention, the circuit elements for generating a signal for closing the mixing valve 4 influencing the flow temperature are also required in the event of a drop in the temperature in the boiler 1 triggering a switching-on process for the burner 2 below the minimum boiler temperature influenced by the setpoint generator 26 . These circuit elements can be, for example: A transistor 31 , with its base via a resistor 32 to the output of the flip-flop 28 , with its emitter via a resistor 33 to the output of the differential amplifier 25 , and with its collector via a diode 34 to the non-inverting input of the differential amplifier 21 is connected.

An undesirable operating state, because the boiler 1 is at risk from corrosion, occurs, for example, when the following initial state is present at the end of a period of time with a reduced room temperature, for example in the early morning: the heater sel 1 is at a temperature of 46 degrees, the temperature in the heating flow 5 is 25 degrees, the setpoint for the flow temperature is 25 degrees, the set limiting temperature is 45 degrees with a switching difference of 6 degrees.

Is now, controlled by the timer 17 , the setpoint for the pre-run temperature to the prevailing weather corresponding daily normal value of, for example, 40 degrees, the controller 15 causes the differential amplifier 21 , the switching device 23 and the drive 14 to open the mixing valve 4 . Since on the one hand hot water from the boiler 1 passes through the boiler flow 3 and the mixing valve 4 into the heating flow 5 , and on the other hand cooled water from the heating return 7 through the boiler return 9 into the boiler 1 . In the case of a boiler 1 with a small boiler content, this would lead to the boiler temperature only rapidly falling significantly below the minimum boiler temperature being promoted. To prevent this is the job of transistor 31 and resistors 32 and 33 . Once through the influent into the boiler 1 cooled water of the switch-on point for the boiler 1, - beispeilsweise 42 degrees, corresponding to 45 degree limiting Tempera ture minus half the switching difference of 6 degrees - is reached, the gate 27 and the flip-flop circuit is via the differential amplifier 25, 28 the transistor 29 is conductive and therefore also the burner 2 is switched on via the burner relay 30 . At the same time, the transistor 31 becomes conductive via the resistor 32 , and as a result the voltage level at the non-inverting input of the differential amplifier 21 becomes lower, from the ratio of the two resistors 22 and 33 and the voltage level at the output of the differential amplifier 25 , which is the difference between the instantaneous Boiler temperature and set limit temperature represented, dependent value shifted. This shift causes the differential amplifier 21 to close the mixing valve 4 via the switching device 23 and the drive 14 . The shift of the voltage level at not inverting the input of the differential amplifier 21 has within the control device 15 the effect that the target temperature for the heating run 5 is corrected in the direction of a lower temperature as long as the temperature of the boiler 1 is lower than that on Setpoint generator 26 set limit temperature. The size of the correction of the target temperature for the heating flow 5 is determined by the size of the difference between the limiting temperature set on the setpoint generator 26 and the temperature of the heating element 1 on the one hand and by the ratio of the values of the two resistors 22 and 23 on the other hand.

The closing of the mixing valve 4 in turn leads to the fact that the temperature in the boiler 1 rises because of the burner 2 being switched on. Characterized the Differenzver produced at the output 25 stärkers a higher positive level, which via the resistor 33 and the transistor 31 again passes to the noninverting A reacts the differential amplifier 21st As a result, the mixing valve 4 is opened again. A shift in the level at the non-inverting input of the differential amplifier 21 , and thus an apparently lower target temperature for the heating flow 5 , only occurs as long as the boiler temperature is below the required limit temperature.

A shift in the level at the non-inverting input of the differential amplifier 21 in the positive direction, corresponding to a pretense of a higher setpoint for the temperature of the heating flow 5 , which would occur if the boiler temperature is higher than the minimum boiler temperature and also higher than that Desired value for the temperature of the heating flow 5 is prevented by the diode 34 . Such a setpoint shift would impair the control function.

If the burner 2 is switched off, the transistor 31 is also blocked. Influencing the level at the non-inverting input of the differential amplifier 21 is then excluded. A pe gel displacement with the burner 2 switched off could result in the burner 2 not being switched on, although the actual value of the temperature of the heating flow 5 is below the setpoint.

The principle described for preventing the formation of condensate in the boiler 1 can also advantageously be used in the case of control devices comprising a microprocessor circuit, a memory and interface components for connecting the components ( 11, 12, 13, 26 ) influencing the control and those to be actuated Components ( 2, 14 ) exist. In such control devices 15 , a signal for closing the mixing valve 4 is generated when, with the burner 2 switched on, the temperature in the boiler 1 falls below the switch-on point for the boiler 1 influenced by the setpoint generator 26 . As long as the boiler temperature is higher than the switch-on point for the boiler 1 and is lower than the limit temperature set on the set point transmitter 26 , the degree of opening of the mixing valve is also influenced by the fact that the set temperature for the heating run 5 by one of the difference between the boiler temperature and the Limiting temperature proportional amount is shifted in the negative direction. It is particularly advantageous that weden the fact that 15 such changes in the control program can be realized with little effort in such programmable control devices, an adaptation to special conditions is easily possible. For example, the influence of the degree of opening of the mixing valve 4 can be made variable by the difference between the boiler temperature and the minimum boiler temperature acting on the setpoint temperature for the heating pre-run 5 , and thus the properties of a particular heating system can be optimally adapted.

A prerequisite for an optimal function and thus for the reliable prevention of the formation of condensate in the boiler 1 is that the drive 14 reacts quickly. An electric motor drive can be used with advantage.

Claims (5)

1.Control device ( 15 ) for a weather or room temperature-controlled and time program-controlled flow temperature control of a heating system with a setpoint device ( 26 ) for setting a limiting temperature for a boiler ( 1 ) to be protected from operation below a minimum boiler temperature, characterized by circuit elements ( 31, 32, 33, 34 ) for generating a signal for closing a mixing valve ( 4 ) influencing the flow temperature in a switch-on process for a burner ( 2 ) triggering the drop in temperature in the boiler ( 1 ) below one by means of the setpoint generator ( 26 ) influenced switch-on point for the boiler ( 1 ). 2. Control device ( 15 ) according to claim 1, characterized in that the signal for the closing of the mixing valve ( 4 ) is derived from a correction caused by the temperature falling below the setpoint generator ( 26 ), the correction of the target temperature for the heating flow ( 5th ). 3. Control device ( 15 ) according to claim 2, characterized in that the size of the correction of the target temperature for the heating flow ( 5 ) is determined by the size of the difference between the limiting temperature set on the setpoint generator ( 26 ) and the temperature of the boiler ( 1 ). 4. Control device ( 15 ) according to claim 3, characterized in that the output of a burner ( 2 ) on and off flip-flop ( 28 ) via a resistor ( 32 ) at the base terminal of a transistor ( 31 ) and this turns on and off , so that a resistor ( 33 ) between the emitter connection of the transistor ( 31 ), the collector of which is connected via a diode ( 34 ) to the non-inverting input of a differential amplifier ( 21 ) acting on the drive of the mixing valve ( 4 ), that when the transistor ( 31 ) is switched on, the potential of the non-inverting input of the differential amplifier ( 21 ) is shifted in the negative direction. 5. Control device ( 15 ) according to claims 1 to 3, characterized in that there is a microprocessor circuit, a memory and interface components for connecting the control influencing components ( 11, 12, 13, 26 ) and the components to be actuated ( 2, 14 ) containing device, in which a signal to close the mixing valve ( 4 ) is generated when, with the burner ( 2 ) switched on, the temperature in the boiler ( 1 ) below the switch-on point for which is influenced by the setpoint generator ( 26 ) Boiler ( 1 ) falls, and as long as the boiler temperature is higher than the switch-on point for the boiler ( 1 ) and lower than the limit temperature set on the setpoint device ( 26 ), the degree of opening of the mixing valve ( 4 ) is influenced by the fact that the setpoint temperature for the heating pre run ( 5 ) is shifted in the negative direction by an amount proportional to the difference between the boiler temperature and the limiting temperature.