DE10257309A1 - Processes and devices for frost protection in heating systems - Google Patents

Abstract

Process for frost protection in heating systems with frost-prone parts in a heating system, whereby the frost-prone heat transfer fluid is replaced by a frost-proof fluid in frost-prone heat exchange systems or parts of heat exchange systems. This fulfills the task of being able to design simple and economical heating systems so that regenerative heat generation can be better used.
A device for implementing the method is also described.

Description

The invention relates to a Frost protection method in heating systems with frost risk Share in a heating system.

From the general state of the art are known in heating systems solar circulation systems, which for frost protection use a water glycol mixture. However, this requires that heat exchangers for the solar circuit which must be used the disadvantage of heat exchanger losses, pressure losses and higher Operating costs due to a larger circulation volume cause.

Exchange systems are also known, which be emptied for frost protection and filled with inert gas, whereby the aforementioned disadvantages can be avoided, but filling devices needed become. Which also partially to avoid temperature mixing or for ventilation costly must be controlled.

Based on a procedure according to the generic term of claim 1, the invention is based on the object Avoiding the disadvantages of the known frost protection process To ensure frost protection easily and safely, so that a heating system can be designed without heat exchangers between heat sources and storage and heat dissipation elements gets along. Furthermore, the economy should be used to connect further Exchange systems with frost protection can be increased so that regenerative Energy sources can be used better.

According to the invention, the object is achieved by solved in the characterizing part of claim 1, namely thereby that in frost-prone Heat exchange systems or parts of heat exchange systems the heat transfer fluid at risk of frost is replaced by a frost-proof fluid.

Advantageous further developments of the Heating system are given in claims 2 to 15.

The invention also relates to a device for the exchange of fluids, in particular according to the claims 1 to 15, which is basically the same The underlying task is like the procedure. According to the device, this task is accomplished by solved the features specified in the characterizing part of claim 16, namely by that the exchange device from an emptying container and the heat exchange system pump consists.

Advantageous further developments of this Procedures are in the claims 17 to 18 specified.

The following are the procedure for frost protection with reference to the drawings.

In the drawing shows in part schematic representation:

1 : Part of a heating system with a solar collector and storage.

An execution of a method for frost protection according to the task shows 1 , Here is in the memory ( 7 ) or inert gas container ( 1 ) an oil layer floating on the water in the reservoir ( 3 ). The return ( 2 ) of a solar collector circulation system opens into the oil layer ( 3 ). The replacement shut-off valve ( 12 ) closed and the drain valve ( 11 ) by the control device ( 13 ) open. As a result, the water in the solar collector circulation system can be gravity-fed into the emptying tank ( 10 ) escape, causing the oil from the oil layer ( 3 ) is drawn into the solar collector circulation system.

Through the fluid discrimination sensor ( 8th ) the control device can recognize when the oil has reached this point, and the control device can activate the drain valve ( 11 ) close so that frost protection is guaranteed by the oil in the part of the circulation system.

If the solar controller requests heat exchange with the solar collector, the control unit ( 13 ) the circulation pump ( 9 ) started and the drain valve ( 11 ) open. As a result, the water contained is pumped into the solar collector circulation system and the oil is circulated back into the storage tank. After a defined time or by a level sensor in the drain tank, the drain valve ( 11 ) closed and the replacement shut-off valve opened so that normal circulation can take place through the solar collector.

The frost protection can be triggered by a temperature sensor ( 6 ) take place in the solar collector, which the control device ( 13 ) evaluates.

The antifreeze procedure in Heating systems with frost-endangered Parts in a heating system can be used in addition to solar collector exchange systems also in exchange systems for Solar storage collectors, heat generation from components, heating of rooms or components for temperature difference reduction, outsourcing of Warmth in the controlled ventilation etc. can be applied. This involves heat exchange systems or parts that are at risk of frost of heat exchange systems frosgefährdete Heat transfer fluid replaced with a frost-proof fluid.

Because the frost-proof fluid is lighter than the frost-prone fluid, mainly water and paraffin oil, the exchange can be easily and safely with the described devices in 1 The storage of the frost-proof fluid in the containers through which the heat transfer fluid flows, such as inert gas containers, fluid heat accumulators, fluid storage heat exchangers, boilers, fluid containers, charging devices, supply devices, fluid exchange devices, enables the advantageous and an adapted to different systems fluid exchange.

It is also advantageous that a line of the heat exchange system is immersed in the stored frost-proof fluid or, for example, can be introduced into the frost-proof fluid by a charging device.

The introduction of a line in the stored frost-proof fluid can also be provided by means of a delivery device respectively. For this purpose, there are particularly positionable loading and preparation devices suitable.

The procedure is also special advantageously further developed by the fluid exchange by emptying of the frost-prone Fluids and / or by filling of the frost-proof fluid. For example, the mouth of a Single pipe exchange line in an oil layer for frost protection if the frost protection room is higher than the oil layer, the oil layer rises into the frost protection room and secures the frost protection. With deeper Frost protection room can also be exchanged for single-pipe exchange pipes by means of an emptying container respectively.

The simplicity of the process will by emptying into an emptying container by gravity simple and safe frost protection can be achieved by the filling of the frost protection room with frost-proof fluid due to the buoyancy of the frost-proof fluid in the heat transfer fluid.

By using existing elements and existing energy levels in exchange systems for exchange of the frost-proof fluid through the heat transfer fluid, like with the replacement pump, - like circulation pump or pump, - or through stored energy, - like different fluid levels, pressure or vacuum, - the Efficiency of the frost protection process reached.

The problem of emulsion formation we solved by that the exchange of fluids takes place with a low exchange flow. Residual emulsions are reduced by the rest times in the storage containers.

The process will be further improved by the presence and absence of the fluids for a safe exchange in the heating system, i.e. in exchange systems or in storage or storage heat exchanger monitored becomes. For example, this can be done with a buoyancy sensor, Conductivity sensor, Fluid level sensor, fluid presence sensor.

Also because of the safe fluid exchange redundant elements and / or with repetitions and / or with self-sufficient Additional equipment that ensures exchange is guaranteed, security of exchange can be achieved.

Further improvements in exchange security bring security strategies, such as repeated repetitions, flushing processes, control of redundant drain valves, logging of malfunctions and / or of security strategies, warning messages and / or heating processes.

By means of redundant and / or self-sufficient Elements such as thermostats, temperature sensors, valve-controlled drain lines, Evaluation units of sensors, fluid presence sensors or fluid absence sensors with valve-controlled drain line, and that this is switched are or are evaluated in the event of plausibility errors reliability strategies are also initiated, reliability of the exchange also secured.

Faults in electronic components and sporadic software errors are eliminated by the fact that the Control voltage for the pumps and / or drain valves and / or shut-off valves via one Chain connection via several redundant systems, such as controls, thermostats, evaluation units done, and approval for the control voltage is provided by all of these redundant systems, and the transition in the safe state of the control voltage already when removed approval of one of the redundant systems.

A simple device which the frost protection process is realized by the fact that the exchange device from an emptying container and the heat exchange system pump consists.

Because the emptying container and that Heat exchange system can be separated from the heating system by one valve at a time simple control of the process.

By operating one or more heat exchange systems from an emptying device can be highly economical can be achieved with several frost protection exchange systems.

1

inert gas

2

Return port

3

oil layer

4

solar collector

5

coating facility

6

Frost protection temperature sensor

7

Storage

8th

Fluid discrimination sensor

9

circulating pump

10

emptying containers

11

drain valve

12

Austauschabsperrventil

13

control device

Claims (18)

Process for frost protection in heating systems with frost-prone parts in a heating system, characterized in that in frost-prone heat exchange systems or parts of heat exchange systems the frost-prone heat medium fluid is replaced by a frost-proof fluid. A method according to claim 1, characterized in that the frost-proof fluid is lighter than the frost-prone fluid, mainly water ( 7 ) and paraffin oil ( 3 ). Method according to one or more of claims 1 to 2, characterized in that the frost-proof fluid is stored in the containers through which the heat transfer fluid flows, such as inert gas containers ( 1 ), Fluid heat storage ( 7 ), Fluid storage heat exchanger, boiler, fluid container, charging device, provision device, fluid exchange device. Method according to one or more of claims 1 to 3, characterized in that a line of the heat exchange system ( 2 ) is immersed in the stored frost-proof fluid or can be introduced. Method according to one or more of claims 1 to 4 characterized in that the introduction of a line in the stored frost-proof fluid by means of a charging device and / or Provisioning facility takes place. Method according to one or more of claims 1 to 5 characterized in that the fluid exchange by emptying of the fluid at risk of frost and / or by filling of the frost-proof fluid. Method according to one or more of claims 1 to 6, characterized in that the emptying into an emptying container ( 10 ) done by gravity Method according to one or more of claims 1 to 7 characterized in that the filling with anti-freeze fluid due to the buoyancy of the frost-proof fluid in the heat transfer fluid he follows. Method according to one or more of claims 1 to 8, characterized in that the exchange of the frost-proof fluid by the heat transfer fluid in the heat exchange system with the exchange pump, such as a circulation pump ( 9 ) or pump, or by stored energy such as different fluid levels, pressure or vacuum. Method according to one or more of claims 1 to 9 characterized in that the exchange of fluids with less exchange flow he follows. Method according to one or more of claims 1 to 10, characterized in that the presence and absence of the fluids in the heating system is monitored for safe exchange, as with a buoyancy sensor ( 8th ), Output sensor, conductivity sensor, fluid level sensor, fluid presence sensor. Method according to one or more of claims 1 to 11 characterized in that redundant for safe fluid exchange Elements and / or with repetitions and / or with self-sufficient Additional equipment ensures the exchange safely. Method according to one or more of claims 1 to 12 characterized in that security strategies, such as repeated repetitions, flushing processes, control of redundant drain valves, logging of malfunctions and / or of security strategies, warning messages and / or heating processes become. Method according to one or more of claims 1 to 13 characterized in that redundant and / or self-sufficient elements such as thermostats, temperature sensors, valve-controlled drain lines, Evaluation units of sensors, fluid presence sensors or fluid absence sensors are attached with valve-controlled drain line and this are switched or evaluated so that in the event of plausibility errors security strategies are also initiated as in claim 13. Method according to one or more of claims 1 to 14 characterized in that the control voltage for the pumps and / or drain valves and / or shut-off valves via a Chain connection via several redundant systems, such as controls, thermostats, evaluation units, and approval for the control voltage is provided by all of these redundant systems, and the transition in the safe state of the control voltage already when removed approval of one of the redundant systems. Device according to claims 1 to 15, characterized in that the exchange device consists of an emptying container ( 10 ) and the pump ( 9 ) of the heat exchange system. Device according to claim 16, characterized in that the emptying container and the heat exchange system are each provided with a valve ( 11 . 12 ) can be separated from the heating system. Device according to one or more of claims 16 to 17, characterized in that one or more heat exchange systems from egg ner emptying device can be operated.