DE2364358A1 - Temperature dependent control for water heating system - uses two multivibrators connected to comparator - Google Patents

Abstract

An astable multivibrator has an output via a capacitor and there are two further multivibrators connected to temperature sensing devices and connected to the comparator whose output operates switches controlling the heater. There is a motor driven mixing device in the hot water tank and the sensors are installed in the hot water supply and return pipes. The first multivibrator contains a NAND gate and an identity gate and is connected to one of the terminals of a DC power supply. The temperature sensors consist of temperature dependent resistors; the apparatus produces a series of pulses to control the switches for the heater and mixer.

Description

Jon. Vat T.I ant K. G.

DT 684

Dec 14, 1973

Temperature dependent control device

The present invention relates to a temperature dependent Control device for hot water heating with a heat source, a motor-controlled mixer, the one Heat source 1 flow or return 1 on Ie1 direction with a boiler flow or return line according to a regulator connects, whose measuring elements detect a flow temperature as well as room or outside temperature.

Such control devices generally work with analog measured variables, which are transmitted via amplifier circuits and three-point control members are evaluated. Amplifier circuits, especially when transistors do not have 1m saturation range work have various disadvantages, e.g. temperature dependence or changing the gain factors.

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In many cases, temperature-dependent resistances are used for measurement the room and flow temperature use. Since the amplifiers and the temperature-dependent resistors can be spatially differently distant from each other, an adjustment must take place regularly, since all parasitic resistances must be taken into account, such as terminal resistances, line resistances, etc.

With function monitoring, it is a heating engineer in the As a rule, it is not possible to carry out a proper function check, since analog parameters are measured and evaluated Need to become.

The invention is based on the object of creating a control circuit in which no additional adjustment is required for any line lengths between the measurement location and location and service-friendly 1st.

This object is achieved in that the Measuring elements are parts of a monostable multivibrator clocked by a trigger and that the outputs of the multivibrators are fed to a comparator, the actuator of which as Function of the pulse lengths on the output lines actuates the mixer.

The advantages that can be achieved with the invention are that digital signals are applied to the control lines. This means that there is no need for any additional adjustment. In addition, independence from parasitic resistance

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flows in the line from the measuring point to the controller. Further the outside temperature-dependent signal could be issued jointly by a communication point for several control circuits will.

Since the digital signals only know one yes / no statement, it is very easy for a service man to carry out functional checks with the help of e.g. light bulbs.

Further features and advantageous configurations of the invention emerge from the claims, FIGS. 1 to 12 of the drawings and the description below.

Show it .

Fig. 1 shows an exemplary embodiment for an electronic

cal circuit of a temperature-dependent Control device,

the output signal of an astable multivibrator,

the differentiated output signal of the astable multivibrator,

a temperature-dependent output signal of the a monostable multivibrator, a temperature-dependent output signal of the other multivibrators, one output signal of the comparator, another output signal of the comparator, a special embodiment of a resistor combination with field effect transistors,

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9 shows an astable multivibrator with field effect

transistor as setting resistor,

Fig. 10 a resistor combination with temperature sensor

ler and timer contact,

Fig. 11 a heating system with a water heater,

and control device,

Fig. 12 a heating system with a starting thermostat and

Control device.

In all twelve figures, the same reference numerals denote respectively the same details.

An astable multivibrator 1 is formed from a negating one Identity gate 2, at its output 3 via a branch point 4 a capacitor 5 is connected 1st. The resistor 6, which can be designed as a potentiometer or FET, is on the one hand via a branch point 7 to the capacitor 5 and to an input 8 of a NAND gate 9, on the other hand Connected via a branch point 10 to an output 11 of the NAND gate 9 and an input 12 of the negating identity gate 2. A second input 13 of the NAND gate 9 is connected to a positive operating voltage via a branch point 14 and via a resistor 15. At the branch point 14, a switch 16 connected to a negative operating voltage is clamped on. The branch point 4 influences Via a resistor 17, capacitor 18 - the two inputs 19 and 20 of the NOR gates 21 and 22. The NOR gate 21 is coupled to a negating identity gate 25 via a capacitor 23 and a branch point 24. A W1der- connected to positive operating voltage

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stand combination 26, consisting of a series connection a temperature-dependent resistor 27 and a potentiometer 28 and another potentiometer connected in parallel to it 29, 1st connected to branch point 24. A feedback device 31 leads from output 30 to the input 32 of the NOR gate 21. A temperature-dependent resistor 33, which is connected on the one hand to positive operating voltage is, on the other hand, is via a branch point 34 with an input 35 of a negating identity gate 36 tied together. As temperature-dependent resistors, both NTC and PTC resistors in question, only they have to be Resistors 27 and 33 each have the other characteristic have, via a feedback line 37 becomes an input 38 of the NOR gate 22 from an output 39 of the negating Identity gate 36 influenced. A capacitor 40 connects the NOR gate 22 with the negating identity gate 36. The output 30 is via a disjunction gate 41 and a branch point 42 is connected to a conjuncture gate 43. The conjuncture gate 43 influences a relay 44, which in turn receives voltage via a relay contact 45 a winding 46 of a motor 47 applies. The output 39 influences Via a disjunction gate 48 and a branch point 49 a conjunction gate 50, which in turn is a relay 51 controls. The relay 51 applies voltage via its contact 52 to a winding 53 of the motor 47.

Branch point 42 is via a negating identity gate 54 with an input 55 of the conjuncture gate 50

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connected, while branch point 49 has a negating Identity gate 56 influences an input 57 of the conjunction gate 43. An input 58 is via a switch contact 59 and a resistor 60 with negative operating voltage tied together. An input 61 receives a switch contact 62 and a resistor 63 negative potential. A switch 64 can switch contact 59 as well connect the switch contact 62 to positive operating voltage. Its rest position is between the two switch contacts 59 and 62.

During operation of the control device, the switch is on 16 open; at the input 13 of the NAND gate 9 there is thus a positive potential. The astable multivibrator 1 gives Square pulses from, as shown in FIG. Its square wave output is differentiated via the R-C link 17,18, as shown in Fig. 3, and fed to inputs 19 and 20 of NOR gates 21 and 22 to the monostable multivibrators 65 and 66 to trigger. The time constant of the monostable Multivibrator 65 is influenced by that of the capacitor 23 and that of the resistor combination 26. The temperature-dependent Resistor 27 senses the temperature of the supply water. With the two potentiometers 28 and 29, the slope and the sensitivity of the temperature-dependent Control device can be adjusted.

The temperature-dependent resistor 33 depends on the outside temperature or the room temperature. The duration of the pulse time depends on the resistor 33 and the capacitor 40. If the two monostable multivibrators 65 and 66 are

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triggers, both emit a square-wave signal, cf. FIGS. 4 and 5.

The two square-wave signals are compared by a comparator 67. Are the pulse times of the two square wave signals the same size, so neither of the two relays 44 and 51 is energized, if the pulse times are different, either relay 44 or relay 51 is actuated and thus the motor 44 for a mixing valve, not shown, either rotated to the right or to the left. With the invention temperature-dependent control device can be changed by changing the ω values of the resistor 29 or 28, depending on the time, a night lowering of the flow temperature can be carried out. If you replace not only the resistor 6, but also the resistors 28 and 29, through field effect transistors, which are controlled by remote potentiometer, so the Heating users can remotely switch the mixer from their home if switches 16 and 64 are also located in the home.

In FIG. 8, instead of the resistors 26 and 27, field effect transistors are used. '

The same applies to the circuit in FIG. 9, in which the resistor 6 is replaced by a field effect transistor. There is thus the possibility of all parameters from one to influence distant place, so z. B. from the living space.

A further embodiment of the resistor combination 26 is shown in FIG. A series connection of a switching

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contact 70 a timer, not shown, and one

adjustable resistor 71 bridges resistor 29. With this measure, a night reduction can be achieved.

A boiler 101 in F1g. 11 with an oil burner 102 and a boiler thermostat 103 influencing the oil burner 102, a water heater 105 is stored in its upper part 104. A domestic hot water temperature sensor 106 is via a line 107 with point 59 or 62 the temperature-dependent control device 108 is connected.

A boiler return 109 is connected to an output 110, a boiler flow 111 1st at input 112 of a four-way mixing valve 113 connected. An output 114 of the four-way mixer 113 corresponds via a heating flow 115 and a pump 116 with the radiators 117. A heating return 118 is

connected to an input 119 of the four-way mixing valve 113.

Is a temperature sensor 120, consisting of the combination of resistors 26 and the monostable multivibrator 66 def, ^{n has} a heating supply 115 applied influenced via a line 121, the temperature-dependent control device 108th

An outside temperature sensor 122, consisting of the temperature-dependent resistor 33 and the monostable multivibrator 65, which is attached to an outer wall 123, divides the temperature-dependent control device 108 via a line 124 with. If domestic water is drawn off during the heating period,

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23S4358

this is how the 1m hot water heater 105 cools itself Water off. The switching contact of the domestic water temperature sensor 106 closes and applies positive operating voltage to one of the contacts 59 or 62. The mixing valve 113, driven by motor 44, moves into the position in which input 112 is connected to input 110. That This means that domestic water is heated up again very quickly. Does the domestic water have the temperature set on the domestic water thermostat 106 When the temperature is reached, its switching contact opens and the mixing valve 113 moves into its starting position in pulses return.

In FIG. 12, instead of the domestic water thermostat 106, a start-up thermostat 125 is installed, the closer of which is connected one of the contacts 59 or 62 is connected. The starting thermostat 125 takes over the same during the heating-up time Function that the domestic water thermostat assumed in the previous example. It will be a quick drive through of the dew point with subsequent temperature-dependent control achieved.

Claims

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Claims (17)

- 10 - Joh. Vaillant K.G. DT 684 Dec. 14, 1973 Claims 1J Temperature-dependent control device for water heating with a heat source, a motor-controlled mixer that has a heat source flow or return line connects with a heating flow or return line according to a controller whose measuring element detects a flow temperature as well as room or outside temperature, characterized in that that the measuring elements (27, 33) are parts of a monostable, multi-vibrator (65, 66) clocked by a trigger (1) are, and that the outputs (30,39) of the monostable multivibrators (65,66) fed to a comparator (67) whose actuator (44,51) actuates the mixer as a function of the pulse lengths on the output lines. 2. Control device according to claim 1, characterized in that that the measuring elements (27, 33) are temperature-dependent resistances and have opposing characteristics . 3. Control device according to claim 1 or 2, characterized in that the monostable multivibrator (65,66) has a series connection of a NOR gate (21,22) of a capacitor (23,40) and a negating identity gate (25,36), and that the temperature sensitive resistor (27,33) between the capacitor (23,40) and the 509826 / "θ 603 - ".. ■ - 11 negating identity gates (25,36) coupled 1st. 4. Control device according to one of claims 1 to 3, characterized in that the resistance combination (26) consists of a series connection of a temperature-dependent resistor (27) with a variable resistor (28), which is another variable resistor Resistor (29) connected in parallel 1st. 5. Control device according to claim 4, characterized in that the variable resistors (28,29) from Field effect transistors exist. 6. Control device according to claim 1, characterized in that the trigger is designed as an astable multivibrator (1) whose frequency is adjustable. 7. Control device according to claim 1 or 6, characterized in that the astable multivibrator (1) has a series circuit comprising a NAND gate (9) with a negating identity gate (2), the negating one Identity gate (2) bridged by capacitor (5) and resistor (6) 1st, and that one input (8) of the NAND gate (9) is connected to the connection point (7) of capacitor (5) and resistor (6). 8. Control device according to claim 7, characterized in that that the resistor (6) is adjustable. - 12 - 509826/06 03 9. Control device according to claim 8, characterized in that the resistor (6) is formed by a field effect transistor. 10. Control device according to claim 7, characterized in that the output of the astable multivibrator (I) is connected via a differentiator (17, 18) to the two inputs (19, 20) of the monostable multi-vibrators (65, 66). 11. Control device according to claim 7, characterized in that the comparator consists of two conjunction gates (43,50), the two inputs of which are each connected to an output of the monostable multi-vibrators (65,66) are, with a negating identity gate (54,56) being arranged in each of the lines. 12. Control device according to claim 11, characterized in that the outputs of the comparator (67) optionally the Control wiper valve motor, 13. Control device according to claim 11 or 12, characterized in that the comparator (67) disjunction gate (41,48) are connected upstream, the other inputs of which are each connected to reference potential via a resistor (60,63), with the resistor (60, 63) can be bridged by a switch (64). 14. Control device according to claim 13, characterized in that the switch (64) actuator of a utility water 50 9826/0603 - 13 thermostats (106) is. 15. Control device according to claim 13, characterized in that the boiler thermostat (125) the switch (64) actuated. 16. Control device according to one of claims 1 to 5, characterized characterized in that the variable resistor (29) can be bridged by a timer contact (70). 17. Control device according to one of claims 1 to 5, characterized characterized in that the monostable multivibrator (65,66) with the variable resistance (26,33) one Building unit forms. 509826/0603 Empty soap