DE2638357A1 - Central heating system with three different heat sources - connects each required source to system through two three=way valves in series - Google Patents

Abstract

The central heating system is supplied through a mixer valve, from either a solar energy collector, a heat pump, or an auxiliary heater. Two three-way valves in the return pipe select among these heat sources. When the solar heating proves insufficient, the first three-way valve transfers, directing the return flow through the second valve. This directs the flow in the first instance through the heat pump, and a relay circuit containing a timer comes into action. If, after a certain time, the heating is still insufficient, the second three-way valve also transfers, and directs the flow through a conventional heater.

Description

Multivalent heating system with

a solar collector, a heat pump and an additional heater The invention relates to a multivalent heating system with a solar collector, a heat pump, an additional heater and one in the flow line of the System arranged mixing valve, which is operated by a servomotor, whose It is controlled by a controller that controls the outside temperature and the flow temperature measures, compares both temperatures with each other and according to a given heating curve the flow temperature controls.

The invention is based on the object for such a heating system To create a control system that stands out for its particular simplicity, value for money and? unction security.

According to the invention, this object is essentially achieved in that there are two multi-way solenoid valves in the return line of the heating system in series are arranged, the first of which by a pipeline rit en mixing valve and the second connected by a pipe to the heat pump is, and that the temperature-dependent controller has a reversible timer as well a relay equipped with a self-holding contact are arranged downstream, wherein this relay when the mixing valve is fully open and the flow temperature is falling switching off the mixing valve by reversing the output pulses of the controller actuating servomotor, switching on the heat pump and the timer and reversing the direction of flow from the first solenoid valve to the second Solenoid valve causes the flow temperature set on the controller to be reached again the time switch comes to a standstill if the flow temperature continues to fall the timer, however, reaches the end position that causes its forward movement, in which it turns on an auxiliary relay via a switch, deqien a contact switching on the additional heater and its second contact reversing the direction of flow of the second multi-way solenoid valve on the additional heater causes.

The timer is also equipped with a switch that in the case of backward movement, the timer when it reaches its start end position a wiping relay arranged in the circuit of the self-holding contact of the relay is actuated, which interrupts the relay's self-holding circuit.

The control device designed in this way is not only characterized by special simplicity, value for money and functional reliability, but offers Furthermore the possibility of using all three energy sources (solar collector, Heat pump and additional heating device) to be connected to a heat storage tank. Through this solar energy can also be harnessed in the colder months of the year as soon as di. Collector temperature is slightly higher than the storage tank temperature. Further the amount of water in the storage tank acts as a buffer against overshooting the su regulating temperature, what happens when switching on the heat pump and the additional heating device because of its two-point character, it would otherwise hardly be avoidable.

In the drawings, the invention is based on an exemplary embodiment Fig. 1 shows the scheme of a heating system with a solar collector dk, a heat pump Wp and, for example, an oil or gas-fired auxiliary heating device Z, all of which are connected to a common heat accumulator Sp. With H is a space heater and R denotes the control device as a whole. These According to FIG. 2, the control device consists of a temperature-dependent one which is known per se Controller R ', which measures the outside temperature and the flow temperature, both temperatures compares the flow temperature with each other and according to a specified heating curve regulates continuously. A mixing valve is designated by Mv, which is controlled by a valve shown in FIG with M designated servomotor is controlled. This Stelinotor ES and the timer Zw a relay equipped with several contacts is arranged upstream. Furthermore are in the return line coming from the radiator H, two multi-way solenoid valves V1 and V2 arranged in series.

A pipeline coming from the heat accumulator Sp is connected to the mixing valve Mv 11, a pipe 12 leading to the room heater H via a circulation pump U1, a pipe 13 and a pipe leading to the nozzle 2 of the multi-way solenoid valve V1 Pipeline 14 connected, which is connected to one of the heat pump Wp to the storage tank Sp leading pipe 15 is in communication.

A return pipe 16 coming from the space heater H is connected to the Connection 1 of the multi-way solenoid valve V1 connected. The nozzle 3 of this valve stands through a pipe 17 with the nozzle 1 of the multi-way solenoid valve V2 in Link. A pipe 18 leads from the nozzle 3 of the valve V2 to the additional heating device Z, while the nozzle 2 of the multi-way solenoid valve V2 through a pipe 19 with a pipe leading from the additional heating device Z to the heat pump Wp 20 is connected.

On the solar collector Sk is via two pipes 21 and 22 one in the heat accumulator Sp provided coil 23 or the like. connected. In the dated Storage Sp in the solar collector Sk leading pipeline 21 is a circulation pump U2 arranged. This pump is switched on and off by a known controller, which does not belong to the invention.

The following is the control of the multivalent shown in FIG Heating system based on the circuit diagram shown in Fig. 2 of an inventive Control device described in more detail, When the sun is shining, the memory is opened Sp supplied from the solar collector Sk from heat and thus the temperature in the storage tank Sp. Increased. Since the need for heating is usually relatively low when the sun is shining the temperature in storage tank Sp will be higher than that for space heating required flow temperature. As a result, the designated M in FIG Servomotor of the mixing valve Mv switched by the temperature-dependent controller R 'so that that the valve Mv moves into a position in which that coming from the memory; 3p hot water plit through the return pipe 13 supplied water mixed in this way is that in the pipe 12 one of the outside temperature required accordingly Flow temperature is reached.

Now lets out the solar radiation acting on the solar collector Sk after, the temperature in the storage tank Sp drops. At the same time, the heat demand also increases in the room. As a result, the controller R 'gives a "warmer" pulse via the line 71 on the servomotor M, so that the mixing valve Mv is opened further and with further increasing heat demand finally reaches its end position. Once the mixing valve Mv has reached this position, the limit switch 4 switches over and outputs a Line 73 sends a pulse to a relay r1, whose contacts r11 and r12 from the in Fig. 2 is moved into the other end position and thus the two pulse lines 71 and 72 of the controller R 'to the input lines 74 and 75 of a reversible Time switch Zw are switched. A third contact r13 of relay r1 switches the heat pump Wp on while a fourth contact r14 as a holding contact for the relay r1 is used because the controller R 'only pulses of different lengths gives away. A fifth contact r15 switches the excitation coil V11 of the solenoid valve V1 on and causes this valve to switch from the direction of passage 1-2 on the passage direction 1-3.

The heat pump Wp, which is now switched on, now increases the temperature in storage tank Sp and thus also the flow temperature due to the open mixing valve Mv elevated.

The consequence of this is that the controller R 'via the line 71 now does not "warmer" pulses emits more and that time.

switchgear Zw stops.

If the flow temperature continues to rise, the controller outputs via the Line 72 "colder" pulses from, so that the timer Zw is moved backwards. When the start position is reached, the switch 5 of the timer Zw is off the position shown in Fig. 2 and thereby switched via a line 76 the Excitation coil r3 of a wiping relay r31 switched on, which holds line 77 of the Relay r1 interrupts briefly and thus a switchover of contacts r11, r 12, causes r13, r14 and r15 to be in the position shown in FIG. As a result, the The heat pump is switched off and the solenoid valve V1 returns to its initial position, i.e. moved back to the 1-2 direction. Furthermore, the controller R 'upper the line 72 "colder" pulses given to the servomotor M, so that the mixing valve Mv is moved in the closing direction in order to avoid fluctuations in the room temperature.

In the event that the line of the heat pump Wp alone not is sufficient, the controller R 'via the line 71 as long as "warmer" pulses on the Timer Zw until it has reached its end position. This gets over a switch 6, an auxiliary relay r4 switched on, the contact r41 of which is switched on the additional heater Z causes, while the second contact r42 this relay the excitation coil V21 of the second solenoid valve V2 turns on, which thereby from the Through direction 1-2 is switched to through direction 1-3.

If the temperature in the storage tank Sp increases further, the controller R ' after a short time no more "warmer" impulses via line 71 are given. Much more if the flow temperature increases further, it gives "colder" pulses for line 72 which let the timer Zw run back again.

This return of the timer Zw causes the switch to open 6 and thus switching off the auxiliary relay r4. As a result, the additional heating switched off again and the solenoid valve V2 in its initial position (passage 1-2) moved back. The repetition of this process depends on the level of each Heat demand.

Claims (2)

a t e n t a n s p r ü c h e 1. Multivalent heating system with one @onnenkollektor, a heat pump, an additional heater and one in the Mixing valve arranged in the flow line, which is operated by a servomotor, it is controlled by a temperature-dependent controller that controls the outside temperature and measures the flow temperature, compares both temperatures with each other and afterwards continuously regulates the flow temperature according to a specified heating curve, d ad u r c h g e k e n n n z e i c h n e t that in the infiltration line (16, 17, 18) of the heating system two @ ehrweg solenoid valves (V1 and V2) are arranged in series, of which the first (V1) through a pipe (1 @) with the mixing valve (Mv) and the second (V2) is connected by a pipe (19) to the heat pump (Wp), and that the temperature-dependent Controller (@@) a reversible timer (Zw) and one with a self-holding contact (r14) equipped relay (r1) are arranged downstream, this relay (r1) at fully open mixing valve (Mv) and falling flow temperature by reversing the output impulses of the controller (R ') switch off the one that actuates the mixing valve (Mv) Servomotor (M), switching on the heat pump (Wp) and the timer (Zw) and a reversal of the flow second direction of the first solenoid valve (V1) the / solenoid valve V2 causes, while when the controller (R ') is reached again set flow temperature d @@ time switch (Zw) comes to a standstill at However, if the flow temperature continues to fall, the timer (Zw) in which reaches its end position limiting its flow, in which it is via a switch (6) an auxiliary relay (r4) switches on, one of which contacts r41 on the additional heater (Z) and its second contact (r42) a reversal of the Direction of flow of the second multi-way solenoid valve (V2) on the additional heating device (Z) causes. 2. Heating system according to claim 1, characterized in that dnß d? S Time switch (Zw) With a switch (5) is equipped, the with declining Movement of the timer on reaching its start end position in the circuit the wiping relay (r31) located on the latching contact (r14) of the relay (r1) is activated, which interrupts the self-holding circuit of the relay (r1).