DE3132554C2 - Method for operating a network acted upon by a fluid under pressure, in particular a district heating network and arrangement for carrying out the method - Google Patents

Abstract

So far, in networks acted upon by fluid, pressure maintenance pumps have been used, which work with a constant delivery rate during the operating time of the network, although load fluctuations occur in the network. Overflow valves are assigned to the pressure maintenance pumps, which immediately reduce the pressure that has built up to the extent that is not required so that the network is not subjected to excessive pressure. According to the invention it is provided that the delivery rate of the pressure maintenance pump (8) and the switching state of the overflow valve (13) are regulated according to the pressure to be maintained in such a way that the overflow valve only opens when the delivery rate of the pressure maintenance pump is reduced to zero. In this way, energy is not used unnecessarily to maintain pressure in the network. r gas pressure over the connection point is maintained until the inside of the

Description

55

The invention relates to a method according to the preamble of claim 1 above.

In district heating networks, in addition to the circulation pumps that circulate the district heating medium in the network, at least one pressure maintenance pump is used. The pressure maintenance pump runs all year round with a constant Speed with. Normally, three-phase AC motors are operated with 380 V constant speed pressure maintenance pumps driven. To enable operation at constant speed, overflow devices are provided, which ensure that the remote heating medium, preferably water, in a Storage tank can flow off.

Such pressure maintenance pumps are also used in others used with a fluid pressurized networks such. B. nets for deletion of fires.

It is the object of the invention to provide a method in which the destruction of excess Energy as a result of the constant delivery rate of the pressure holding pump is avoided.

This object is achieved in that the delivery rate of the pressure maintenance pump and the switching status of the overflow valve are regulated in accordance with the pressure to be maintained in such a way that the overflow valve only opens when the delivery rate of the pressure maintenance pump has been reduced to zero.

By regulating the delivery rate of the pressure maintenance pump, which is preferably a speed control of a three-phase motor, the running time is reduced when the network is operating and the energy consumption is reduced accordingly decreased. Experiments with speed control of the pressure maintenance pump in a remote heating network have shown that only about 20% of the previous running time is required to stabilize the required network pressure are, d. This means that in the previous operation, the network water was recirculated during 80% of the running time into the feed water tank holding the mains water took place.

The invention is also directed to an arrangement for carrying out the method according to the preamble of claim 2. According to the invention it is provided that the pressure maintenance pump also has a pressure change in the network responsive controller is switched on, which increases the delivery rate of the Pressure pump reduced to zero before the overflow valve is opened.

The subclaims 3 and 4 are directed to advantageous embodiments.

With an arrangement for use in a district heating network with a device for heating the district heating medium, ζ. Β. a boiler at least one Circulation pump in the flow and / or in the return, it is useful if the pressure maintenance pump controller and the overflow valve controller, the signal corresponding to the inlet pressure in the return, which the half the difference between outlet pressure in the flow and inlet pressure in the return corresponding signal and a target value signal can be supplied in each case, the target value signals by a predetermined amount are different.

The invention will now be described in more detail with reference to the figure in connection with a district heating network in which the use of the invention is to be preferred.

In the figure, the district heating network 1 is shown symbolically as a closed curve, with the individual Customers have not been represented with. The curve is a pressure curve and the amount of pressure is as Plotted on the ordinate. The delivery head of the circulation pump 2 in the flow and the circulation pump 3 in the return are here, for example, 11 bar. Between Circulation pumps 2 and 3 are located in a boiler 4. The delivery pressure drops until the heating water emerges from the Heating plant, which is identified in the symbolic representation according to the figure by the line 5, in the specified Way off. After exiting the heating plant, the pressure in the district heating network drops to the specified level Minimum pressure for customers. Then a

further pressure drop until the returning heating water enters the heating plant and a further pressure drop up to the inlet to the circulation pump 3. This pressure curve is assigned an ideal mean pressure line 6, their location by maintaining pressure when operating the district heating network with the consumption of heat the customer is to be regulated depending on the load.

As can be seen from the figure, the network between the boiler outlet 4a and suction inlet 2b of the circulating pump 2 is connected to a retaining line 7, 'n the pressure-maintaining line 7 is a pressure-maintaining pump 8 which can suck in heating water from a storage tank SB and pump it into the network 1 . The pressure maintenance pump 8 is driven by a three-phase motor 9 which z. B. can be a squirrel cage motor. The three-phase motor 9 is excited by a static frequency converter 10 which is connected to a 380 V network

Between the pressure maintenance line 7 and the storage container SB there is an overflow line 11 in which an overflow valve 13 driven by a motor 12 is arranged.

The outlet level 5 is assigned a pressure sensor 23 in the flow la and a pressure sensor 14 in the return \ b.

The output signals of the pressure sensors 23 and 14 are fed to a transducer 15, at the output of which an electrical signal corresponding to the difference Δρ between the pressure in the flow p and the pressure in the return flow p _{r is present.} The output signal of the pressure sensor 14 is fed to a measuring transducer 16, at the output of which an electrical signal corresponding to the pressure p _{r is present} in the return line. The output of the transducer 15 is followed by a halving resistor 17.

The electrical signals are fed to a pressure pump controller 18 together with the output signal of a setpoint adjuster 19. The output signal of the controller 18 controls the frequency converter 10. Furthermore, the signals are fed together with the output signal of a further setpoint adjuster 20 to an overcurrent switching regulator 21, the output signal of which controls the excitation of the drive motor 12 of the overflow valve 13. The setpoint Si ₉ for the pressure maintenance pump is smaller by a predetermined value than the setpoint S20 for the overflow valve. With the delivery head of pumps 2 and 3 of 11 bar selected in the example, it is sufficient for the arrangement to function satisfactorily if S19 is approximately 0.2 bar lower than S20. A signal corresponding to the mean pressure, a signal corresponding to the pressure in the return and a setpoint signal are thus supplied to the controllers.

It is assumed that the pressure maintenance pump 8 runs at a certain speed and the overflow valve 13 is closed. If the consumers take less heating water from the network 1, the pressure in the network increases; The actual signals Jp / 2 and p _r fed to the two controllers change accordingly. It is assumed that the pressure increase is initially insufficient to trigger the overflow switching regulator 21. The increase in pressure then only causes a control of the frequency converter 10 in such a way that the speed of the three-phase motor 9 is reduced and thus the delivery rate of the pressure maintenance pump 8 is reduced, bi

If the pressure in the network 1 continues to rise, the pressure maintenance pump 8 is finally switched off. In the event of a further increase in pressure, which corresponds to the setpoint difference 5m - S \% between the two controllers, the motor 12 of the overflow valve 13 is excited by the overflow switch controller 21 and the valve is opened, so that the pressure is reduced via the overflow line 11 can. When an amount of heating water sufficient to reduce the pressure specified by the setpoint regulator 20 has flowed into the feed water tank SB , the overcurrent switching regulator 21 de-excites the motor 12.

If the consumers now draw heating water from the network 1 again, the pressure drops. The overflow valve 13 remains closed and the pressure maintenance pump starts up and continues to work at a speed that keeps the network pressure at a value that corresponds to the amount of heat requested from the network. The difference between the two setpoints Sx and S19 ensures that the pressure maintenance pump 8 and overflow valve 13 cannot be excited at the same time. Overall, the arrangement ensures that the pressure maintenance pump only works when the required operating pressure is maintained. Water must be taken from the tank SB , ie it does not work if, with the required network return, operation of the pump would only lead to a circulating delivery of heating water in the system feed water tank SB, D.-uckhaltepumoe 8 and overflow valve 13, as is the case with the known ones Arrangements is the case.

The regulation ensures that the network is not exposed to overpressure and that the pressure is not so drops far enough for steam to form in the network.

For the sake of completeness, there is one in the figure on the left another ordinate is entered, which is assigned to the geodetic height, which of course when operating a district heating network is to be considered. The geodetic height is usually in m above sea level. NN (meters above sea level) measured.

1 sheet of drawings

Claims (5)

Patent claims: 1. A method for operating a network acted upon by a fluid under pressure, in particular district heating network in which the fluid is conveyed by at least one feed pump and that is fed to maintain a pressure from at least one pressure maintaining pump, and be relieved via at least one overflow valve depending on a predetermined pressure can, characterized in that the delivery rate of the pressure maintenance pump and the The switching status of the overflow valve can be regulated according to the pressure to be maintained in such a way that that the overflow valve only opens when the delivery rate the pressure maintenance pump is regulated down to zero. 2. Arrangement for carrying out the method according to Anspnaih 1, with at least one feed pump, one between a fluid carrier and the pressure maintenance pump located in the network, at least one overflow valve between the fluid container and network and at least one regulator responsive to pressure changes in the network for the overflow valve, characterized in that that the pressure maintenance pump (8) is also a regulator which responds to pressure changes in the network (18), which reduces the delivery rate of the pressure maintenance pump to zero when the pressure rises, before the overflow valve (11) is opened. 3. Arrangement according to claim 2, characterized in that the Drucfchaltef> dmpenmotor (9) Three-phase motor is connected to a frequency converter (10), which in turn is connected to the Pressure maintenance pump assigned Regier (18) is connected. 4. Arrangement according to claim 3, characterized in that that the frequency converter is a static frequency converter. 5. Arrangement according to one of claims 2 to 4 with a device for heating the district heating medium, at least one circulating pump in the flow and / or in the return, characterized in that the pressure maintenance pump regulator (18) and the overflow valve regulator (21) each correspond to the inlet pressure in the return (pr) corresponding signal, the half the difference between the outlet pressure in the flow (p _y ) and the inlet pressure in the return (pr) corresponding signal and each a setpoint signal (Sw, S20) can be supplied, the setpoint signals by one predetermined amount (S20 - S19) are different.