EP0195335A3 - Device for pressure compensation in heating installations or the like - Google Patents

Abstract

With a pressure compensation device for heating systems an expansion tank is provided, inside it there is a bubble (11). Excess water can come out the system via lines (15, 16) into the bladder will. At negative pressure, water comes out of the compensation container into the system via lines (15, 17, 18). There are an overflow valve (2) and a pump (4) are provided. If there is overpressure in the system, the overflow opens valve (2) and lets water into the expansion tank (14). If there is negative pressure in the system, a pressure switches switch (3) on the pump (4), the water from the off pumps the surge tank into the system. At the same time in the electronics control device (5) a time pulse triggered and causes the pump (4) no longer depending on pressure, but is switched off depending on time.

Description

The invention relates to pressure compensation Direction for heating systems or the like, with the heating medium absorbing, sealed off from the outside air NEN expansion tank, which is connected via lines to the heating plant is connected, being within the compensation area holder closed off from the expansion tank ne chamber with variable volume is provided, the communicates with the outside air, and the compensation container via a pressure regulating the heating system Pump and an overflow valve with the heating system in Ver binding is established, with one attached to a pressure sensor closed electronic control device for the pump.

In itself, such a pressure compensation device can be used in any system where there is a Medium volume changed, so also with cooling systems.

It is known that in large heating and cooling systems by heating or cooling the heating medium water there is a change in volume. The more volume must be from the System removed and when cooling and therefore volum reduction in the water in the system same pressure conditions back into the system be performed.

It is known in such heating systems that by Excess water arising from an open expansion Feed storage tanks and reduce volume via a pump of the system from this same container again To supply water.

The disadvantage here is that in the open storage container the heating fluid comes into contact with the outside air,   which is the main risk of corrosion within the system enlarged.

A pressure compensation device is now known at the abge the heating medium water against the outside air remains closed.

This pressure compensation device essentially consists from a pressure vessel and an automatic compressor group, for smaller units directly on the container is mounted. For larger systems, the parts of the Automatic placed separately.

There is a flange on the lid and on the bottom of the container welded on, with a between the two flanges rubber extending across the height of the container hose is clamped directly with the system in Connection is established and the heat that occurs absorbs additional water caused by the volume expansion.

The structure of the container is such that between the Rubber hose and the container wall there is an air space, which is under pressure by its own compressor, namely under the pressure of the system. An adjustable bares piston manometer with limit switches controls the Compressor and opens a solenoid valve in the event of overpressure, so that the pressure is kept constant at approximately ± 0.2 bar can be.

The function of the pressure compensation device is as follows:
If more water is fed into the hose from the system, air is let out from the space between the tank wall and the hose to keep the pressure constant. When the heating medium flows out of the hose, the resulting additional space in the ring gap is filled up with air pumped in by the compressor.

The disadvantage of the known pressure compensation device is now to see that the container is the same Pressure as the system itself shows.

This will make the container according to those in Austria the provisions subject to inspection.

Of course, this leads to an essential ver expensive equipment and maintenance.

In another known pressure compensation device it is intended that the chamber with the outside air in Ver bond is established, and the expansion tank over the pressure the pump and valve devices regulating the heating system is connected to the heating system, the Volumsver Change the chamber depending on the inside of the out equal container prevailing, generated by the pump Vacuum occurs.

This pressure compensation device has the advantage that the Containers only a small fraction of the pressure of the Heating system must record. So it can't with one reservoirs subject to inspection must be worked.

So far, such pressure compensation devices have been used the switching commands directly to the relief valve or on the pump.

This principle holds for some types of plants and plants with significant pressure fluctuations the problem that that intended for damping pressure fluctuations Buffer vessel not always out in the event of extreme fluctuations enough, or represents a component that a certain Maintenance required.

The object of the invention is a pressure compensation device to improve the generic type in such a way that due to slight pressure fluctuations in the system   loosened rattling of the pump is avoided.

This is achieved in that the Electronic control device the pump depending on pressure switches on, but regardless of the pressure after one before given time period switches off.

Since the pressure vessel of the control device only for Turning on the pump is used, the pump runs too not affected by the fact that the pump temporarily more Water supplies the system than it can absorb.

It is advantageously provided that after falling below a predetermined negative pressure of the system Pump in the system builds up an overpressure, and that at then the pressure relief valve is opened and pressure is released until the desired operating pressure of the system is reached.

The time period for the pump run is preferably 2 minutes.

The invention will now be described with reference to the drawings described, but without the shown off leadership examples to be limited.

1 schematically shows a pressure according to the invention Compensating device under construction, and Fig. 2 shows schematically a pressure compensation device in plan view.

The actual heating system is shown in the drawings not shown since it is not the subject of the invention and the self-evident knowledge of every subject heard it. Likewise, the printout according to the invention equal device in the most diverse heating systems Find use.

In the drawings, the actual compensation is at 14   container and with 5 an electronics arranged in front of it Designated control device. The pressure equalization Direction is via a line 15 with the actual Heating system in connection.

The additional water created by the expansion of volume is via line 15 through a pressure valve 2 the line 16 is fed to the expansion tank 14.

When the pressure or volume in the heating system is reduced, a pump 4 is automatically activated via a pressure switch 3 and pumps water back into the heating system via lines 15, 17, 18. The function of the pressure compensation device according to the invention is as follows:
The heating system is filled up to its static pressure, taking into account any evaporation pressure in systems with over 100 ° C. In the expansion tank 14, water in the order of 20% of the vessel volume is filled via a fill and drain tap. Reaching the 20% can be seen on the water level indicator 6 The pressure switch 3 is set to the setpoint, ie static height plus 5 m. In systems for over 100 ° C, the evaporation pressure must also be added. ie the setpoint would then be static height plus 5 m plus evaporation pressure.

If the system is heated up, this creates more volume of water. This also means one Pressure rise indicated by the manometer l. At The overflow opens when the pressure rises by 0.2 bar valve 2 and leaves the additional water volume via the line 16 flow into the bladder 11 of the expansion tank 14. The Bubble 11 forms the variable volume chamber. By overflowing the water, the pressure in the Plant kept constant.

When the heating system cools down, pressure builds up lust because the water volume decreases. When falling   the pressure by 0.2 bar, the pressure switch 3 closes the Circuit for the pump 4. This promotes missing Water from the expansion tank 14 into the system back. The resulting increase in pressure below does not break the circuit for pump 4.

At the same time as the pump 4 is switched on Electronics controller 5 triggered a time pulse, the be acts that the pump 4 is no longer dependent on pressure, but is switched off depending on the time.

As a result, the system pressure would exceed the selected maximum system pressure (e.g. 2.5 bar) would increase. To prevent this from opening pressure-dependent overflow valve 2 and directs it too much conveyed heating medium back into the expansion tank 14. After the set time has elapsed (e.g. 2 min.) the pump 4. The minimal excess built up in the system pressure is released via the overflow valve 2 and closes without generating pressure surges in the system 2.2 bar.

As a safeguard against dry running of the pump 4 in the vessel, a probe 7 is used, which is too low Water content when the pump is switched on or continued to run 4 prevented.

As a protection against overpressure when the overfill is overfilled equal container 14 is a safety valve 8 with a Blow-off pressure of 0.5 bar is provided. This security valve is used to drain excess water, which is closed off from the atmosphere in which Bubble 11 is located.

The pressure compensation vessel 14 is open to the atmosphere. The vent 9 is with the overflow of the safe safety valve 8 connected so that an overflow funnel 10th must be installed.  

1, the bladder 11 is at the top and held down by a flange 12. It is there of particular importance that the air with the heating medium Water does not come into contact.

The overflow valve 2, the pressure switch 3, the pump 4 and the electronics control 5 are in a maintenance friendly control box 13 housed in the Figures of the drawings for clarity is drawn separately.

It has proven to be particularly advantageous that in the electronic circuit 5 incorporates a switching function is that causes the pump to move outside of the Heating period switches on for five minutes every five days. This will cause the pump to dry out avoided.

It should be mentioned that the invention itself understandably not be on the specified switching values is limited, but that these according to the ent speaking requirements can be selected.

Claims (3)

1. Pressure compensation device for heating systems or the like, with a heating medium, opposite the Outside air sealed expansion tank, the over Lines connected to the heating system, where within the expansion tank one against the Expansion tank closed chamber with change bar volume is provided, which with the outside air in Connection is established, and the expansion tank via a pump regulating the pressure of the heating system and a Overflow valve is connected to the heating system, with an elec. connected to a pressure sensor tronic control device for the pump, characterized records that the electronic control device (5) Pump (4) switches on depending on pressure, but independently switches off from pressure after a predetermined period of time. 2. Pressure compensation device according to claim l, characterized characterized in that after falling below a before given vacuum of the system switched on pump (4) builds up excess pressure in the system, and that there opened by the overflow valve (2) and pressure in the Expansion tank is drained. 3. Pressure compensation device according to claim l, characterized characterized in that the time period between 1 and 5 Minutes, preferably 2 minutes.