FI96988C - Method and apparatus for monitoring and regenerating fluid flow in heating and cooling systems - Google Patents

Abstract

A method for continuously monitoring and reconditioning the liquid flow in heating and cooling systems, wherein the system liquid, for instance water which may possibly contain standard additives, such as alcohol or glycol, is monitored and reconditioned in several mutually sequential steps within an apparatus unit integrated with the system, by taking from the total or main liquid flow a part flow which is returned to the main flow subsequent to reconditioning. The reconditioning process includes the following steps - subsequent to viewing the liquid by means of a viewing glass: magnetic filtration for removing magnetite particles; filtering-off solid particles (fine particles); removing corrosive gases; deaerating the system; measuring pH, oxygen content and conductivity, wherein an optical and/or electrical alarm signal is given in the event of deviations from mutually related liquid control-values inserted in the apparatus, or in the event of disturbances in operation. Apparatus for carrying out the method consists of a system-integrated unit which includes auxiliary devices for carrying out said part-operations successively.

Description

96988

The present invention relates to a method and apparatus for controlling and regenerating a liquid flow in heating and cooling systems. The present invention relates to a method and an apparatus for controlling and regenerating liquid flow in heating and cooling systems. for monitoring and regenerating the liquid flow in heating and cooling systems, the method being characterized by continuously pouring and regenerating the system fluid in a partial flow removed from the system and restoring said partial flow to the system after regeneration. Examples of heating systems are radiators, while air conditioning systems are examples of cooling-15 systems. The term system fluid primarily comprises system water, which may optionally contain standard chemicals such as glycol or alcohol.

System water recirculation in heating and cooling systems in this context means treating the liquid mechanically, chemically or physico-chemically in such a way as to stop corrosion in the system, remove mucus, deposits and deposits, and prevent any future corrosion, mucus formation and deposition.

• I

Problems normally encountered in heating and cooling systems can be divided into the following groups: 30

Acute problems: - Leaks and blockages in the circulation can be included in this category.

35 Malfunctions: - Continuous need to replenish the system with 2 96988 diluents.

- Repeated need to repair corrosion damage.

- One-size-fits-all replacement of worn seals in the system.

5 - The system is unable to cope with peak loads.

- Circulation faults occur in the system.

Higher energy costs: 10 - Production of overtemperatures.

- Poor heat output on heat transfer surfaces.

Repeated complaints to the heating and cooling producer: 15 - Uneven air conditioning distribution.

- High operating costs.

- Repeated interruptions.

- Too cold in winter or too hot in summer.

20

All of the above problems can in many cases be due to the poor chemical or physico-chemical state of the system fluid, i. the composition of the liquid is such or has such properties that corrosion may occur, which in turn may cause leakage. For example, the liquid may have an inappropriate pH, i.e. A pH value that is not within the recommended range for heating system water, which is 8.5 to 9.5, or may have too high a conductivity (salinity), which is not less than the recommended value for heating system water of 200 MS / cm, as recommended for heating system water. water, or too high an oxygen content, i.e. an oxygen content not less than the recommended value of 0,05 mg / l at 95 ° C.

Another problem is that the formation of mucus in the liquid can cause malfunctions, while the deposits and deposits cause energy losses.

Another common problem is the presence of large or small air bubbles in the system fluid, which reduces heat production.

To date, methods and apparatus have been described and used to avoid at least some of the above problems. For example, NO 160546 10 discloses an apparatus for venting or removing air from a closed liquid system to remove small air bubbles or vapor bubbles by agglomerating the bubbles into larger bubbles having a higher buoyancy and then removing the bubbles from the system by said apparatus.

In this case, the entire fluid flow passes through the device.

U.S. Patent No. 4,413,675 discloses a filter and inspection glass that are incorporated into a cooling system and are located in the total direct flow between the motor and the radiator. The transparent line, which includes double conical screens or filters, is designed to prevent clogging of the radiator, and the system also allows visual inspection of the operation of the cooling water pump and thermostat and indicates corrosive liquid and relative flow. The system is said to be suitable for an attitude-30 cooling system for internal combustion engines. The total flow of coolant passes through the system before said flow is directed to the condenser. It is necessary to remove and clean the filters as needed, during which time the system will inevitably be out of order.

U.S. Patent No. 4,793,403 discloses a method for cleaning an internal combustion engine cooling system 4 96988, wherein all of the coolant is directed to a zone (apparatus) outside the cooling system where the fluid is treated to remove rust particles, deposits and slime. This treatment includes filtration of contaminants, addition of chemicals such as corrosion inhibitors, pH adjuster and corrosion inhibitor, return of coolant from the treatment zone to the engine cooling system, and filtration of the recoverable coolant.

As in the previous case, this system must also be dismantled for cleaning, during which time the system must be switched off.

15

Finally, ASEA-ATOM BWR 75 discloses the purification of turbine condensing water by filtering water before returning said water to the reactor, and also the purification of reactor water by removing anionic and Lei-20 impurities so that water in the reactor vessel reaches a specified purity from two parallel ion exchangers. layer filters for

In contrast to the prior art described above, in which certain conditioning steps are performed inconsistently, i. together with system interruptions, and with respect to total system water, this invention relates to a method and apparatus for continuously monitoring and improving system fluid 30 by removing a partial flow of system fluid, e.g., heating or cooling system fluid, and monitoring and then conditioning the fluid to said system. within one and the same device unit, said steps comprising: il, 5 9698b - measuring the instantaneous fluid flow and checking the appearance of the system fluid by means of a sight glass; - for example, filtering off the magnetite by means of a magnetic filter; - optimal filtration of the particles up to a particle size of 0,5 μg; 10 - removal of all corrosive gases; - ventilation of the entire system; - measurement of pH, oxygen content and conductivity.

15

The regeneration system also includes alarm devices that produce an optical and / or electrical signal in the event of a malfunction and / or when the system fluid condition is poor, such as when filtering out 20 particles, measuring fluid flow, and measuring pH, oxygen content, and conductivity.

The device according to the invention is installed both to facilitate maintenance and to avoid the need for it, and is used as mentioned above without interrupting the normal operation of the system fluid, for example the necessary cleaning or replacement of filters is performed in a branched partial flow.

30

The conditioning steps mentioned above may not apply. need to be performed in the above order, and the relative order of the steps can be changed if necessary. The individual steps are carried out by means of known auxiliaries which do not form part of the invention as such. An essential feature of the present invention is that the various, individual conditioning steps are performed sequentially without interrupting the operation of the system as a whole. Experiments have shown that the device according to the invention and the method according to the invention are capable of improving the state of water 5 in a "physico-mechanical" manner to such an extent that previously used chemical treatment can be omitted, even in systems with very poor system water quality.

The accompanying drawing schematically shows a preferred embodiment of the invention, i. successive regeneration steps are performed in a partial flow of a liquid-filled feed system. The drawing shows: 15 1. Flow meter with control glass (system fluid in poor condition) 2. Magnetic filtration 3. Particulate filtration (fine filtration) 4. Degassing / deaeration or purification 20 5. a. PH, b. Oxygen content, c. conductivity measurement / adjustment.

6. Alarm and monitoring unit (system fluid in good condition)

Claims (2)

96988 A method for controlling and regenerating a fluid flow in a heating or cooling system in which the system fluid has been inspected and foreign, harmful solid and gaseous substances have been removed, characterized in that the system fluid is continuously monitored and regenerated without interrupting normal operation of the system. in a successive step within a device unit included in the system and for the sub-flow separated from the main fluid flow, and said sub-flow is returned to the main flow after re-flow, said re-flow steps comprising: , incorporated in said unit of equipment; - magnetic filtration of any magnetite particles present; 20. solid particle filtration (fine filtration); - removal of corrosive gases; - deaeration of the system; - a measurement of pH, oxygen content and conductivity, in which the order of said different sub-phases can be reversed if necessary, and in which the device generates an optical and / or electrical alarm signal when there is a deviation from the interrelated holding values fed to said device, indicating these deviations, that the system fluid is in poor condition or has been interrupted. Apparatus for carrying out a method for monitoring and regenerating the liquid flow of a heating or cooling system according to claim 1, characterized in that the apparatus comprises an integrated unit connected from a main flow to a branched partial flow and comprising the following successive auxiliary devices: together with an inspection glass for visually inspecting the system fluid in poor condition; - a magnetic filter groove (2) for removing magnetite particles; - a filter (3) for removing solid particles (fine filtration); 10. a device (4) for removing corrosive gases and removing air from the system; - an apparatus (5) for measuring the oxygen content and conductivity; and - an alarm device (6) for generating an optical and / or electrical alarm signal in the event of a deviation from the interrelated holding values entered into the device or an interruption in operation. li »· 9 96988