SE528030C2 - Pressure equalizer for district heating system - Google Patents

Abstract

The excess pressure compensation device is located in a pipe (6), which feeds cold water via a back pressure valve (11) from the water supply mains to the secondary side of the domestic water heat exchanger. The device consists of a cylinder (4) connected to the pipe, and containing a sealed piston (7) and a helical spring (9), which charges the piston in direction of the pipe. The cylinder fastened to the pipe via a T-shaped fitting (5). The spring is a pressure spring located at the outer end of the cylinder between the piston and a plug (10). The piston has two pref. O-shaped sealing rings.

Description

528 030 10 15 20 25 30 35 2 apartments, where there is at least one tap water heat exchanger in each apartment.

It is therefore desirable to provide a device to meet this relief function without the need to establish a connection to a drain, which is at the same time inexpensive and easy to install.

A combined non-return and pressure relief valve is known for this use, in which there is no need for drainage to a drain. The non-return valve is formed with a piston-shaped valve body, which enters a corresponding cylindrical part and seals radially against it.

Behind the seal, the valve body has a slotted part, which allows the passage of water when the valve is opened. In the event of overpressure on the tap water heat exchanger side, this valve body is pushed further into the cylindrical part, thereby providing the necessary space for volume expansion.

This combined non-return and pressure relief valve is a relatively complicated construction with the slotted valve body and a fitting cylinder that is part of the flow path for the cold water. In use, part of the pipe connection, if the pressure relief function occurs, can be alternately connected to clean tap water from the network and the water on the tap water heat exchanger side, which is not suitable.

In connection with large heating systems with heat exchangers, such as water heaters or boilers, it is customary to use pressure relief devices which comprise a pressure accumulator with a diaphragm or a flat piston-like body, which delimits a gas-filled pressure chamber. GB-A-2 391 588 describes such an arrangement, in which a kettle for drinking water is provided with a standard safety valve and in addition has an additional safety valve, which is opened at a lower pressure.

The waste water from the latter valve is led into a pressure accumulator with a piston, which delimits a gas-filled pressure chamber. When the pressure has dropped again, the water is led back into the system through a non-return valve. With 10 15 20 25 30 35 528 030 2 apartments, where there is at least one tap water heat exchanger in each apartment.

It is therefore desirable to provide a device to meet this relief function without the need to establish a connection to a drain, which is at the same time inexpensive and easy to install.

A combined non-return and pressure relief valve is known for this use, in which there is no need for drainage to a drain. The non-return valve is formed with a piston-shaped valve body, which enters a corresponding cylindrical part and seals radially against it.

Behind the seal, the valve body has a slotted part, which allows the passage of water when the valve is opened. In the event of overpressure on the tap water heat exchanger side, this valve body is pushed further into the cylindrical part, thereby providing the necessary space for the volume expansion.

This combined non-return and pressure relief valve is a relatively complicated construction with the slotted valve body and a fitting cylinder that is part of the flow path for the cold water. In use, part of the pipe connection, if the pressure relief function occurs, can be alternately connected to clean tap water from the network and the water on the tap water heat exchanger side, which is not suitable.

In connection with large heating systems with heat exchangers, such as water heaters or boilers, it is customary to use pressure reliefs which comprise a pressure accumulator with a diaphragm or a flat piston-like body, which delimits a gas-filled pressure chamber. GB-A-2 391 588 describes such an arrangement, in which a kettle for drinking water is provided with a standard safety valve and in addition has an additional safety valve, which is opened at a lower pressure.

The waste water from the latter valve is led into a pressure accumulator with a piston, which delimits a gas-filled pressure chamber. When the pressure has dropped again, the water is led back into the system through a non-return valve. With this device, the safety valve is prevented from being activated too often with water spillage as a result.

Such devices are dimensioned for systems with high pressure and high water consumption and include large pressure accumulators and pressure and non-return valves. DE-U-29 910 386 discloses a gas water heater with a heat exchanger and a device for relieving the pressure which may occur when heating the water on the secondary side of the heat exchanger. The device consists of a cylinder with a piston, which communicates with the secondary side of the plant. In the event of overpressure, the piston is moved into the cylinder against the action of a spring and, after a certain movement, exposes an outlet opening, whereby excess water from the volume increase is released to the surroundings. As with other valves that enable water to be discharged, access to a drain with the problems and inconveniences mentioned above is required.

Summary of the invention The object of the invention is to propose a pressure relief unit which does not require access to a drain, which is easy to manufacture and install and which is arranged so that all water on the tap water heat exchanger side remains on the same side of the non-return valve. This is achieved according to the invention by means of a device of the above-mentioned kind, which, as stated in claim 1, is characterized by a closed cylinder connected to the pipeline with a piston tightly fitting therein and a helical spring, which acts on the piston in the direction of the pipeline. With this simple device with only one cylinder with an associated piston and a helical spring which can be arranged between the piston and a helical plug at the end of the cylinder, and in which there are no valves or other flow- or pressure-influencing elements, the stated object is achieved . During a pressure increase and volume increase in the tap water heat exchanger, the piston moves outwards in the cylinder against the action of the spring until the volume is occupied. With the tap water heat exchangers used today and which contain as little as half a liter of water, this volume has a limited size and the cylinder can therefore be made small, less than 10 cm long. All water remains during any function within the non-return valve's hot water heat exchanger side, and there is thus no part of the piping on the mains side that can come into contact with water from the tap water heat exchanger.

By mounting, as stated in claim 2, the cylinder on the pipeline by means of a T-shaped coupling, and designing the spring as a compression spring mounted between the piston and a screw plug at the outer end of the cylinder, a good practically useful embodiment is obtained.

The piston can be designed as stated in claim 3, with two sealing rings, preferably O-rings, whereby the control and movement of the piston in the cylinder becomes stable and safe.

The non-return valve can suitably, as stated in claim 4, be integrated in the unit, in that it can be fitted in the inlet nozzle of the unit. In this way, a compact unit is achieved with both pressure equalization and non-return valve function.

Brief description of the drawings The invention is explained in more detail in the following with reference to the drawing, in which: Fig. 1 schematically shows a district heating plant with the device for pressure equalization according to the invention and Fig. 2 shows a view of the device for pressure equalization partly in section.

Description of preferred embodiments Fig. 1 schematically shows a district heating system with inlet and return for the water from the heating plant and a tap water heat exchanger 2, which on its primary side receives the water from the inlet and delivers it to the return. The secondary side of the tap water heat exchanger receives cold water from the water supply network via a 528 030 10 15 20 25 30 5 non-return valve ll. The pressure equalization device is shown at 3.

Fig. 2 shows, partly in section, an embodiment of the device itself 3. A cylinder 4 is by means of a T-coupling 5 mounted on the pipeline 6 which connects the secondary side of the tap water heat exchanger to the water supply network. In the cylinder there is a tight-fitting piston 7 with two O-rings 8. A compression spring 9 between the piston 7 and a threaded plug 10 in the top of the cylinder acts on the piston in a direction towards the T-coupling. The non-return valve to be located in the pipeline 6 is built into the inlet nozzle 12 of the device. ' If the pressure in the tap water heat exchanger rises due to heating and the consequent thermal expansion of the water, the piston 7 is moved outwards against the action of the spring, until the increased water volume has been taken up. When the temperature returns to normal, the piston has moved back to its original position.

During this process, all water has remained on the tap water heat exchanger side of the non-return valve. There is thus no possibility for water from the tap water heat exchanger to come into contact with clean water in the water supply network.

The domestic hot water heat exchangers are relatively small, with a water content of less than half a liter.

The volume increases that occur during overheating are therefore also small and you can easily adjust the cylinder volume and the properties of the spring so that the pressure increase that occurs when the piston travels outwards is very limited.

The device has few, simple components and is easy to assemble.

Claims (4)

528 030 10 15 20 25 6 PATENT CLAIMS Device (3) for equalizing overpressure in a district heating system, more specifically the overpressure that can occur in the event of overheating of the system's tap water heat exchanger, which device is arranged in the pipeline (6) (ll) leading cold water from the water supply network to the tap water - characterized in that it consists of a closed cylinder (4) connected to the pipeline (6), with a piston (7) tightly fitted therein and a helical spring (9) which acts on the piston in the direction of (6). Device according to claim 1, characterized in that the cylinder is mounted on the pipeline (6) by means of a T-coupling (5) and that the spring is a compression spring (9), which is mounted between the piston (7) and one which via a non-return valve the secondary side of the heat exchanger, the pipeline screw plug (10) at the outer end of the cylinder (4). Device according to claim 1 or 2, characterized in that the piston (7) is provided with two sealing rings, preferably O-rings (8). Device according to one of Claims 1 to 3, characterized in that the device (3) is arranged in the device (12). t e c k n a d a v that the non-return valve is integrated in the inlet connection