EA027321B1 - Pump arrangement for operation of a storage element in a heat supply system - Google Patents

Abstract

The invention relates to a pump arrangement for operating a storage element in a heat supply system. The pump arrangement according to the invention consists of a controllable pump, a 4/2 valve, and a non-return valve in the pressure conduit of the pump. The components of the pump arrangement cooperate in such a way that the pumped stream can flow in different directions in the associated conduit loop while the direction of flow in the pump is always the same, and the pump output can be simultaneously adjusted to existing requirements.

Description

The invention relates to a pumping device for operating a storage element in a heat supply installation.

It is known that heat generators, such as a boiler, must have a higher heat output than the predicted total heat consumption in the corresponding heat supply system. This is because the heat generators in such heat supply systems must always be designed for maximum heat demand.

When a heat supply system, the performance of which is set in accordance with the indicated rule, is driven by a solid fuel boiler, difficulties arise when balancing heat fluxes within such a device.

As proposed in SN 342354, for this reason, a heat accumulator must be connected to such a heat supply system, which is connected in parallel to existing heat consumers (heaters). Connection to the heat supply system is carried out through the supply and return lines of the heat supply system by means of a three-way valve in each case, as well as by forced circulation of the heat supply system in the consumer circuit using a thermostat-controlled circulation pump.

Depending on the position of the three-way valves, either a consumer circuit or a heat accumulator, or both can be in operation.

When the consumer circuit is functioning in conjunction with a heat accumulator, a functioning mode is implemented in which the necessary volumes of liquid are withdrawn almost forcefully either from a solid fuel boiler, or from a heat accumulator, or from both of them. Hydraulic equalization is not provided. Therefore, the proposed system can only be rationally driven in such a way that the water heater, with the corresponding position of the solid fuel boiler valve, is loaded directly, and with this switching option, the consumer circuit and the circulation pump are turned off. The resultant pump-free circulation increases the loading time.

Therefore, the most significant drawback of this heat supply system is that hydraulic equalization and loading of the heat accumulator by the flow of the working medium under pressure are impossible.

First of all, an excessive supply of heat quantities can also be realized by the fact that additional heat sources, such as solar thermal collectors, are connected to such a heat supply system. In this case, first of all, there are significant discrepancies between the receipt of heat quantities and their consumption. In addition, the processes of heat production and its consumption do not coincide with each other in time.

To eliminate this, heat supply systems are available in heat supply systems, which offer the possibility of storing these amounts of heat during temporary excessive supply of heat quantities and provide the possibility of their subsequent demand. To provide such an opportunity, a heated working environment with excessive supply should be pumped out towards the storage element. In case of uncovered demand, the same working medium must be pumped in the opposite direction from the storage element back to the heating circuit.

Due to the reduction at a high temperature of the working medium, the resource of the circulation pumps, it is introduced from some time only into the pipeline, which constantly has a lower temperature. As a result, two different flow directions are necessary for loading or unloading a heat accumulator.

This need cannot be met with a circulation pump, which is usually represented by a centrifugal pump capable of operating in only one direction of flow. Therefore, heat supply systems have already been implemented in which two pumps are connected in parallel in the circulation circuit between the heat source and the heat accumulator in each case with the opposite supply direction. In any case, such pumps must be equipped with shut-off valves that ensure the flow of the medium only in a given direction.

It is also known to introduce an electrically controlled two-way servo valve into such parallel-connected pump devices on each pump line to prevent a short circuit in the flow of the medium through a correspondingly located simple pump.

Such devices are expensive, and in addition, they require the use of additional control devices, which, on the one hand, open and close routes and, on the other hand, control both pumps.

IE 4409883 C2 proposes a device with two pumps connected in series, both of which are connected by their suction sides to the return line of the heat consumer. In this device, the flow of the working medium in the return line of the heat consumer can be connected by means of a pump to a heat generator (heating boiler) or by means of another pump with a heat accumulator. To avoid feedback in the return line of the heat consumer and in the supply line of the heat generator, one check valve is proposed.

This system is disadvantageous in that in the case of connecting additional heat sources, as well as in the case of introducing several circuits of heat consumers, in each case the same device should be provided as a part of pumps and non-return valves. Consequently, the costs for complex systems increase very significantly.

A device is known from EP 1906101 A1, in which two pumps are connected to the line in each case by their pressure sides in such a way that a predetermined flow direction is specified by turning on one of these pumps in each case. At the same time, a flow of the working medium flows through the pump that has been decommissioned accordingly.

A comparable device is known for the heating system Eso 2eyy I 555 of the company STS AB, 34 126 Lyngby, Sweden. In this device, check valves are additionally provided between the two connected pressure sides of the pumps.

Despite the simplified construction, this device has the disadvantage that in each case the decommissioned pump represents a significant active resistance in the line, which entails the need to increase the performance of the pumps. In addition, it is possible that a correspondingly increased flow of the working medium when flowing around the impeller of an inactive pump can cause damage due to corrosion and cavitation. These drawbacks are further exacerbated if, in addition to the pump, the flow must also flow through check valves.

Along with the demonstrated individual, existing in the prior art solutions to overcome some of the disadvantages, there are also other disadvantages. So, for example, systems that use two pumps that are independent of each other require separate control, as a result of which control costs increase in such heat supply systems.

If a device equipped with two circulation pumps is also equipped with controllable valves, the control overhead is further increased.

In addition, there is no synchronization in the individual components of prior art devices. Controlled valves or pumps strike in circulation circuits. Several solutions lack hydraulic leveling.

In plants, the main task of which is to obtain renewable energy using solar thermal sources, devices known from the prior art cannot meet the requirements for maximizing the production of energy from these sources. For this, it is necessary to integrate the secondary heat accumulator in conditions of balancing the amounts of heat within the heat supply system in such a way that it is able to supply heat quantities to the consumers circuit or remove them from the production circuit as needed and without inertia. Known from the prior art and integrated as a heat sink into the heating circuit, a combined storage ring with a large-capacity heat buffer also cannot properly meet the requirements. Such devices have too much inertia. On the other hand, a heat sink with less significant inertia requires a quick reaction from the secondary hot water storage tank to compensate for the excess or lack of heat in relation to the heating circuit of the heat supply system. This cannot be achieved by prior art pumping devices.

Therefore, the aim of the invention is to propose such a pumping device, which provides at low costs for the manufacture, installation and management of the loading and unloading of at least one heat accumulator in heat supply systems, which operates optimally in energy and cost, avoids pressure shocks, makes hydraulic adjustment and can be adapted in various aspects to integration into existing installations.

The aforementioned goal has been achieved with a guiding device with features of the characterizing part of claim 1 in combination with the features of the restrictive part of this claim. Additional independent and dependent claims describe embodiments of the device of the invention.

In the following description, embodiments, and claims, the following concepts are used in the following meanings:

A heat supply installation is a device that has at least a heat generator, a heat consumer, and a heat accumulator that is loaded and, accordingly, discharged by means of a pump.

A pumping device is an assembly of at least one pump of arbitrary design, pipelines and valves, designed to solve the problem of loading or unloading a storage element through a pumping unit.

The storage element is a capacitive storage of arbitrary size and design, which can be loaded with a carrier amount of heat by the working medium and unloaded again.

Return flow interrupter - a structural element or structural unit that provides stable unhindered transmission of the working medium flow of the pump and, nevertheless, closes the pipeline during a prolonged or pulsed countercurrent in the pump line.

Managed - means that based on arbitrary decisions and interventions in the heat supply system, both the commissioning of the pumping device and its stop can be called.

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Adjustable - means that the actuation or shutdown of the pump depends on the parameter values registered in the installation, the set controlled values or on the basis of the programs of operation of a higher regulating device. This type of control device can be integrated into the pumping device or be made in the form of a central control device of the heat supply system.

According to the invention, the prerequisites for further optimization of the use of thermal energy in heat supply plants are that the storage element additionally placed in such a system is subjected to loading or unloading with low inertia and using only one pump. Until now, used devices with two pumps become therefore unnecessary.

In this case, the invention considers, first of all, such heat supply systems that are equipped with heat generators that receive heat from renewable energy, and in which the so-called heat sink performs the task of providing heat to the heating circuit. However, in this case, the pumping device according to the invention is also applicable in conventional heat supply systems if a secondary heat accumulator is additionally placed in them.

The additional resistance of the second pump to the flow through it is eliminated as well as the costs of installing and maintaining the second pump. In addition, possible damage is prevented for cavitation, corrosion, and wear of the pumps that have been decommissioned accordingly.

According to the invention, the pumping device must be designed in such a way that, by means of valves or taps, it is possible to alternately connect the inlet or outlet parts of the pipelines, and thus, a change in the direction of the pump's flow is possible within short time intervals. According to the invention, there is the advantage that for controlling valves or cranes, only a control impulse is required with a small expenditure of energy, while a pump can pump a working medium even after switching in each case in an optimal operating mode.

To provide energy-optimized pump actuation, they are controlled optimally in performance. That is, the pump is constantly provided with the amount of energy that is necessary to maintain the desired parameters.

Most preferred is the control of the amount of energy on the circulation pump by controlling the pump drive motor by a pulse width modulation method, which is controlled by analog signals and sets on their basis the amount of energy for the operation of the circulation pump.

Moreover, it is most preferable that the analog signals are set by placing the temperature sensor in that place in the consumer circuit of the heat supply system, which is accepted as preferred for determining the proper temperature. Due to this, the loading and, correspondingly, the unloading of the connected heat accumulator can be controlled almost without inertia and, at the same time, provide a simple way to comply with the specified heat engineering parameters.

Such control of the circulation pump can be performed in parallel with the control of the heat supply system or be integrated into it.

Moreover, the control of the amount of energy through the so-called pulse-width modulation is preferred, since it can be performed on the basis of inexpensive structural elements or blocks or control modules.

Most preferred is pulse width modulation using a so-called pulse regulator or a so-called controlled pulse modulation module in the form of an electronic component.

In this case, the use of the electronic standard node §03524 is particularly preferred, since it is controlled by an analogue control signal. This creates the prerequisite for the direct connection of a temperature sensor operating in analogue mode to the control unit of the circulation pump.

Obviously, such control can also be carried out through the analog output of the central control of the heating system.

In cases where longer travel routes to the storage element are found within the heat supply systems or higher supply pressures in the storage element are required, a multistage pump or a cascade of pumps can be used, and control can be performed as described above.

The switching device required within the limits of the pumping device is preferably made in the form of a four-way on / off valve. It connects in one switching position the suction side of the pump with a heat generator and the pressure side of the pump with a storage element. In the second switching position, the suction side of the pump is connected to the storage element and the pressure side with a line to the heat generator.

Most preferred is as a four-way on-off valve so

- 3 027321 called a ball valve, which has at least two necessary switching positions and is controlled by auxiliary energy.

Instead of a four-way on-off valve, two three-way on-off valves, four two-way on-off valves or also devices with ball valves can be used.

To protect the heat supply system and the pump, a return flow interrupter is connected in front of or after it. In this case, it is preferred to place it after the connecting flange on the discharge side of the pump.

The pumping device can be made depending on the implementation of the heat supply system in a dispersed construction method with intermediate connected pipelines or in the form of a pumping device of a compact design or in the form of a pumping device of a block design.

The invention is explained below in more detail by means of several embodiments and drawings. It is shown in FIG. 1 is a schematic representation of a heat supply system with one storage element located therein.

FIG. 2 is a schematic representation of a pumping device according to the invention when applying a four-way on-off valve in a switching position, in which the pump pumps the fluid flow towards the heat source.

FIG. 3 shown in FIG. 2 is a schematic representation in a switching position of a directional valve in which a pump pumps a flow of a working medium towards an attached storage element.

A heat supply system of known design consists of a heat generator 1, a heat consumer 2 and lines 3 connecting them for the hot area (summing up) and 4 for the cold area (leading).

Additionally, a circulation pump 5 of the heating system can be integrated into the heating system.

From line 4 pipelines 6 and 7 are passed to the storage element 8. Between the pipelines 6 and 7, there is also a pumping device 9, which, depending on the need, loads or unloads the storage element 8.

By means of the connecting pipe 10, the storage element 8 can be connected to the line 3 so that the heated working medium can be supplied directly to the consumer circuit from the storage element 8.

The pumping device according to the invention within pipelines 6 and 7 consists of a pump 11, a four-way on-off valve 12, a return flow interrupter 13 and connecting pipelines 14, 15 and 16.

In FIG. 2, the four-way on-off valve 12 is in the first switching position, which may also be referred to as the 0 ° position. In this case, the switching element 17 directs the medium from the pipeline 7 through line 14 to the pump 11, and then through line 15, the backflow interrupter 13 and line 16 to line 6. Thus, the heat consumer 2 due to the unloading not shown in FIG. 2 of the storage element may be provided with a heated working medium.

In the embodiment of FIG. 3, the switching position, which corresponds to the 90 ° position, the four-way on-off valve 12 is connected in such a way that loading not shown in FIG. 3 storage elements. From the heat generator 1 through line 6, a four-way on-off valve 12, pump 11, line 15, return flow interrupter 13 and line 16, the heated working medium 1 is pumped into line 7. The working medium removed from the storage element is pumped through line 10 towards consumer 2 heat.

The return flow interrupter 13 is located on the pressure side of the pump 11 and is connected to it via a line. Due to this, backflows in the circulation loop are prevented, moreover, regardless of whether a backflow has formed in the form of a pulse or on the basis of a long back pressure.

For the invention it does not matter in what way and with what types of connecting devices the pumping device is connected to the heat supply system. This applies, first of all, to the power supply points, to which the pipeline 6 and line 10 are connected. It is also of little significance for the invention whether line 10 is available in the system.

Pump 11 is preferably a performance controlled pump. Most preferred is a pump control that uses pulse width modulation and is able to provide pump 11 with the amount of energy that is needed to complete the task.

The control of the pump 11 can be implemented through its own control module or central control of the heat supply system. It is also possible to influence control interventions on the energy flow to the pump 11.

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The pump 11 is driven by an analog signal in such a way that on its basis the control module or central control can produce pulse-modulated oscillations.

The pulse-modulated oscillations are produced by an integrated pulse regulator or controlled by a pulse-width modulator, and in the case of a modulator, preferably, switching circuits of group 803524 or their derivative models are used.

The control of the standard structural unit is preferably carried out using analog signals in the voltage range between 0 and 10 V. The pulse regulator or the modulator operates, preferably with a frequency of 4 kHz.

The four-way on-off valve 12 can be replaced by other valve devices operating in a similar way, taking into account certain disadvantages. So, for example, a device with two three-way on-off valves, a device with four two-way on-off valves or also a device consisting of several ball valves. In this case, ultimately, it all comes down to the fact that it must be possible to change the suction side and the pressure side of the pump 11 with respect to pipelines 6 and 7.

Most preferred, however, is a four-way on-off valve 12 in the embodiment in the form of a ball valve due to its simple design and reliability.

Equally a four-way on-off valve 12 or other switching devices are controlled in each case by means of control commands and power supply and do not require manual maintenance.

The return flow chopper 13 may be implemented in various ways. Thus, it can be, for example, represented by a device that operates using a floating element, or a device that is equipped with a rotary back flap. Another embodiment is that the shutter body is loaded with a spring, and the return flow interrupter 13 is made, accordingly, in the form of a check valve.

The pumping device made according to the invention is capable of efficiently controlling both in cooperation with a heating boiler and in cooperation with a heat sink of a heating circuit.

First of all, the known fluctuations in the energy production of the solar collectors integrated into the heat supply systems can be aligned using the pumping device according to the invention and controlling it due to the fact that depending on the heat influx or the heat dissipation, the pump is connected in the feed direction in such a way that he either removes the excess heated working medium from the heating circuit or supplies the excess heated working medium to the heating circuit from the buffer tank.

At the same time, the pulse-width modulated power supply of the pump ensures its operation with a constantly optimized volumetric flow rate, as well as preventing deviations from the set temperature value in the heating circuit.

It is possible to place the temperature sensor, which delivers the analogue measuring signal, in that place of the heating circuit, which is recognized as optimal, in order to realize, therefore, the functioning of the heating circuit under optimal conditions. The above-described pumping device has the advantage that it makes possible a simple way to operate the pump in two directions of flow, and at the same time allows you to optimize the cost of structural elements, as well as the hydromechanical layout. In addition, the energy consumption is minimized by the solution according to the invention in such a way that hydraulic losses are kept low, valve control is supplied with energy only when necessary, and the pump contained in the device receives only the amount of energy that is absolutely necessary for the task.

Reference List

- heat generator

- heat consumer

- line

- line

- circulation pump of the heating system

- pipeline

- pipeline

- cumulative element

- pumping device

- connecting pipe

- pump

- four-way on-off valve

- return flow chopper

- line

- 5,027321

- line

- line

- switching element

Claims (9)

CLAIM 1. A pump device for operating the storage element (8) in a heat supply installation comprising a first circulation circuit in which a heat generator (1) is connected to a heat consumer (2) and heat medium circulation is achievable between the heating pump (5) and the second circulation circuit, which serves to connect to the first circulation circuit of the storage element (8) and the pumping device (9), characterized in that the pumping device (9) is configured to provide on demand a circus the flow of the working medium from the heat generator (1) to the storage element (8) or from the storage element (8) to the heat consumer (2), and the storage element (8) located in the second circulation circuit is either loaded or unloaded, the pumping device (9) is a device comprising a pump (11), a switching device and a return flow interrupter (13), which interact with each other in such a way that in the first position of the switching device, the pump (11) is connected on the suction side to the accumulator coping (8), and on the discharge side - with the first circulation circuit, and it receives a working medium with a low temperature from the storage element (8), in the second position of the switching device, the pump (11) is connected on the discharge side to the storage element (8), and on the suction side, with the first circulation circuit, and a working medium with a low temperature is taken from it and fed to the storage element (8) using a pump (11). 2. The device according to claim 1, characterized in that the pump (11) with respect to its performance is controllable or adjustable by pulse width modulation (PWM) depending on the magnitude of the analog input signals. 3. The device according to claim 2, characterized in that the control or regulation of the pump (11) occurs by supplying at least one analog signal to it. 4. The device according to one of claims 1 to 3, characterized in that the pump (11) is multistage or in the form of a cascade of pumps with at least one other pump. 5. The device according to one of claims 1 to 4, characterized in that the switching device is a device that, without changing the direction of rotation or supply of the pump (11), makes it possible to switch the flow of the working medium in the second circulation circuit for loading or unloading the storage element. 6. The device according to claim 5, characterized in that the switching device is made with a four-way on-off valve (12) or a four-way on-off valve. 7. The device according to claim 6, characterized in that the switching device is made with two three-way on-off valves, two three-way on-off valves or with four two-way on-off valves or four two-way on-off valves. 8. The device according to one of claims 1 to 7, characterized in that the return flow chopper (13) is connected to the front or rear of the pump (11) or the cascade of pumps. 9. The device according to claim 8, characterized in that the return flow interrupter (13) is made with a flow-controlled floating element, and / or with a flow-controlled damper, and / or with a controlled flow and spring loaded element.