DE2950782C2 - - Google Patents

Description

The invention relates to a system for gas supply of buildings with the features of the preamble of the claim 1.

At the beginning of the municipal gas supply, that was about Chamber gas generated at atmospheric pressure by a Low pressure pipe network (50 kp / m² ≈ 4.9 mbar) to the consumers headed.  

This pressure value was mainly for safety reasons chosen so low after initially in Relation to the reliability of the piping materials and the pipe connections some uncertainty prevailed. This low pressure later became minor increased (to 80 kp / m² ≈ 7.85 mbar), and as claims and consumption have increased further, it became with the promotion of gases of higher pressures started in the power line, the supply pressure for the individual consumer districts with the help was set by so-called district pressure regulators.

The natural gas supply has been there from the beginning to a much higher pressure (275 kp / m² ≈ 26.96 mbar) is used.

Today's gas distribution system was actually trained with the expansion of natural gas pipelines, which are operated with a pressure of 40-60 at. Today's gas distribution network essentially exists from high pressure pipelines (20-60 at), from medium pressure Distribution lines (up to 6 at ≈ 5.88 bar) and from low pressure supply lines. Between the gas pressure regulators are installed in individual line systems, those with different, other supply functions exercising devices (such as filters, heating or odorization devices etc.) so-called supply substations form. The constant increase of gas consumption contributed to the gradual reduction of the large-diameter low-pressure distribution network  at which in certain areas (e.g. in public areas) has completely disappeared is, and with the help of consumer units from so-called "house pressure regulators" directly to the Medium pressure network can be connected.

However, this development was only outside to watch the buildings. Inside the building the permissible pressure drop on the connection line (including the house connection and distribution line here as well as the risers are understood) as a result of the low supply pressure at a very low Worth keeping, hence the diameter the piping used is quite large. this fact has a significant amount of building materials (before all metals) and considerable installation costs required and also had a along of the walls running, clearly visible and the aesthetics pipeline network that interferes with living spaces. The for mechanical fastening of the pipes Fasteners had to be labor-intensive to be chiseled into the wall and the flyover the pipeline through the wall levels needed quite a bit large wall openings. Above all, these problems with log houses and with tunnel formwork technology manufactured buildings means considerable difficulties. The cost was high and the installation work was very time consuming.

The low supply pressure has of course also determines the design of the gas consumer devices.  As a result of the low pressure, the dimensions are of the devices and thus their space and material requirements quite large. Beyond that due to the low supply pressure (after the air necessary for the combustion of the gas through the Energy of the gas conveyed to the combustion site must be) the circle of usable gas burners highly limited. Several, otherwise extremely advantageous So far, gas burners with properties have been able to are therefore not used in household appliances, because a higher gas pressure is necessary for their operation than the current supply pressure (e.g. the gas burner according to HU-PS 1 56 316). While the development industrial burner systems have become numerous such solutions worked out that also for household appliances could be used to advantage if there the necessary higher gas pressure is available would. In this way, a basic solution was created for such a generation of household gas appliances that in addition to the substantial reduction in dimensions and the simultaneous increase in specific services enable space and material to be saved would and at the same time the comfort of gas households could increase.

With the spread of industrial construction technologies the time spent on the actual Construction work on the construction of new buildings significantly reduced, but at the same time the implementation is the technological following the construction work Installation work (such as water, sewer, electrical  and gas installation) has become much more difficult. The production of grooves, wall and ceiling openings is difficult to mechanize and very time consuming. So So the time spent on installation work after completion of the actual construction work in absolute scale increased, he even compared already increased to such an extent that this Circumstance the timely implementation of the construction programs prevented.

For these reasons it is understandable that attempts to modernize this installation work to be received with great interest. The Water pipe and sewer installation work was done through the use of pipeline shafts relieved, especially in blockhouses with large panels and in those manufactured using tunnel formwork technology Buildings after this solution the ceiling openings superfluous. During the electrical installation work have z. B. the glued lines that Cable ducts made of plastic and the suspension of Ceiling lights proven with the help of hanging cord.

At the same time, also in the field of Gas supply trials conducted to a new and less material and time consuming process for Elaborate installation of domestic gas supply systems. To the dimensions and material of the Pipelines (and in connection with this the means and the technology of fixing them) , it was necessary to adjust the pressure to the new one  Reshaping plans accordingly, primarily because thus a larger one on the lines within the building Pressure drop can be allowed. This problem could clearly only be achieved by increasing the Building incoming pressure can be solved. The increase of the inlet pressure was also made possible by that the maximum value of the low pressure, which in the building may now be introduced at 100 mbar was set.

Fig. 1 shows the pressure conditions in variously installed domestic gas supply systems. The actual domestic gas supply system is connected to the distribution network 1 and consists of a house pressure regulator 2 , a connection line 3 (which could actually be divided into house connection, distribution and riser lines), a shut-off valve 4 , a gas meter 5 and a consumption line 6 (which term in this case also includes the branch and device connection lines). 8 consumer devices 9 and 10 are connected to this gas supply system directly or with the involvement of a device pressure regulator.

The curve "A" shows the pressure conditions in the gas supply systems which are generally used and are built using conventional methods. Here, the pressure drop p ₂- p ₁, which may occur between the outlet pressure of the house pressure regulator 2 connected to the distribution network 1 and the inlet pressure at the consumer device 9 on the entire domestic gas supply system, is extremely low, as a result (especially when gas heaters are switched on at the same time) Dimensions of the connecting line 3 at least 1 1/2 ″ to 2 ″ and that of the consumption line 6 at least 3/8 ″ to 1 ″. This is the reason why such a gas supply system requires a material-intensive pipe network and why the labor-intensive technology already mentioned must be used to lay or fasten this pipe network.

An attempt was made to reduce the cross section of the lines used by increasing the pressure introduced into the building and by allowing a larger pressure drop across the gas supply system. An attempt was made to increase the pressure introduced into the building in a gas supply system constructed according to curve "B" in FIG. 1 up to the value p ₄ and after a significant pressure drop P ₄- P ₃ using a device pressure regulator 8 a pressure drop p ₃- p ₁ to generate and stabilize. However, this solution had several disadvantages.

On the one hand, the wire cross-sections proved to be too small, since a reduction in dimensions only up to is rational to a certain limit. On the other hand had to have a device pressure regulator in front of every consumer device be installed, which made the system quite expensive is.

An attempt was therefore made to design the gas supply system according to curve "C" in FIG. 1, where a pressure p ₅ is introduced into the building, the value of which exceeds the pressure p ₂ used in the conventional gas supply systems, but it is still so low that it does not pose any security problems yet. The pressure drop p ₅- p ₆ permitted on the line system is greater than the value permitted in conventional gas distribution systems, which enables a reduction in the line cross-section. After device pressure regulator 8 is also used here to generate and stabilize the pressure drop p ₆- p ₁, the pressure drop is distributed harmonically between the line section and its fittings and the device pressure regulator 8 .

This solution (for example with an inlet pressure p ₅ = 50 mbar and a pressure drop p ₅- p ₆ = 20 mbar) has enabled a reduction in the pipe dimensions (to 1/2 or 3/8 ″), but no changes in the pipe material and the technology for laying and assembling the pipes. Another disadvantage of this solution is that the device pressure regulator 8 must be installed before each consumer device, which is a significant cost factor in the installation of the gas supply system, but also a further source of error.

Another disadvantage of the previous solutions consists in the fact that a certain (by overpressure of the devices allow, but none (caused by the pressure drop) Under pressure. The reason for this is that  So far, the avoidance of the nominal pressure under all circumstances lower pressure (a pressure drop) has been. The currently valid standards determine the degree of Heat overload in 15%, at which the device is still reliable has to work, even if with a declining Efficiency. Based on measurements on consumer devices it was found that an underload of 10% or the pressure drop associated with this underloading operation noticeably affected by the devices.

The limitation of the permissible pressure fluctuation only to between the nominal pressure or the one by 15% higher pressure associated area resulted in such a one-sidedness, that in the line cross-section had to be lost.

The aim of the invention is to remedy the disadvantages mentioned.

The invention is based, taking advantage of the task  of the permitted maximum operating pressure the supply lines to be dimensioned such that an optimum in the behavior of the Gas appliances is reached.

This object is achieved with a system solved the features of claim 1.  

The solution according to the invention enables one Significant metal savings, an aesthetic design of the piping system, a simpler and time-saving Installation work, a substantial reduction in costs, the exploitation of the pressure energy of the transmission lines incoming natural gases and finally the possibility of Introduction of a more economical new generation of household gas appliances.

The invention will be explained in more detail with reference to the Drawing explained. It shows

Fig. 1 shows the basic pressure conditions in a domestic gas supply system constructed according to the invention in comparison to the previous solutions, along the more important elements of the gas supply system, and

Fig. 2 shows the pressure conditions at the main points of measurement in a concrete application example of the method according to the invention as well as the variations of the pressure values of the nominal pressure.

When carrying out the method according to the invention, a house pressure regulator 2 is connected to the medium pressure distribution network 1 , the outlet pressure of which comes close to the maximum value of the pressure that can be introduced into the building in accordance with the applicable regulations (the so-called low pressure) or even expediently reaches it ( p ₇ in FIG. 1). Conventional pipe material (steel pipe with welded or socket connections) is used in the construction of the connecting pipe 3 , but with a reduced cross-section (this value can be 3/4 ″ for apartments with a floor area of up to 130 m²). The greatest pressure drop ( p ₇- p ₈) on the connecting line 3 corresponds in this way approximately to the full pressure drop of the gas supply system built by the conventional method. The shut-off valve 4 and the gas meter 5 are in devices known per se, in which the pressure drop ( p ₈- p ₉) is negligibly small. Cold-drawn steel pipes or copper pipes are used as the consumption line 6 , the outer diameter of which is similar to the electrical cables, 8 to 25 mm, expediently 12 and 16 mm. The tubes are connected to each other with the help of silver-containing solder by capillary brazing and / or metal gluing. The pipes are fastened to the wall with the aid of well-known cable clamps, and they are passed through the wall planes in a bore whose diameter is at most 30 mm, advantageously 20 mm, and which are manufactured with the aid of impact drills.

The occurring on the consumption of the line 6 formed by this process gas supply system pressure drop (p ₉- p ₁₀) is at full load at least 15, but not more than 30% of the output pressure of the pressure regulator house. 2 Heating devices provided with a throttling element or gas stoves provided with a throttling element installed in the gas tap are predominantly used as consumer devices. So z. B. in the figures, the heaters 9 with pre-throttle element, the heaters 11 and the gas stoves 12 are provided with a throttle element installed in the gas tap, only when the continuous water heater 10 is a device pressure regulator 8 used if necessary. Accordingly, the incoming pressure to the heaters 9 and 11 as well as to the gas cooker 12 ( p ₁₀) can significantly exceed at least twice the current supply pressure and only the incoming pressure ( p ₁) to the input of the once-through water heater 10 becomes with the current supply pressure to be equivalent.

While performing the procedure of the tools is the one provided with rock drill Impact drill most commonly used with which you can work very easily and productively. For assembly can also be used in tube bending pliers known per se be used, with which the profile pieces without prefabrication can be trained on the spot, and the pipeline can be dismembered in this way be avoided.

None is used to manufacture the pipe connections Welding machine used, since the with the help of hard solder made connections with such liquid gas soldering device are manufactured using an injector gas burner  has and without oxygen or compressed air tank or air compressor works. When gluing together the pipe section is in addition to that known per se Tube no longer requires any other tools.

The pipeline through the invention Process trained domestic gas supply system "doesn't" dominate the walls as conspicuously as the earlier lines, even after the painting of the Cables are hardly noticeable anymore and they are disturbing much less the interior design of the living spaces than the now common pipe network.

The application of the method according to the invention is presented using a specific embodiment.

example 1

With the help of the method according to the invention, a domestic gas supply system was installed in a family home, where the building consists of a central living room, three bedrooms, a bathroom, a kitchen, a pantry and a toilet, with a total area of 130 m². In Fig. 2 the longitudinal profile of the gas supply system of this building was shown. A house pressure regulator 2 with an outlet pressure of 100 mbar was connected to the medium pressure distribution network, the pressure of which is 3 bar. The connecting line 3 was made of welded steel tube with a diameter of 3/4 ″. A gas meter 5 , which can be used up to 200 mbar, was connected to the connecting line. The consumption line 6 was made of cold drawn steel tube with a diameter of 12 or 16 mm and a wall thickness of 1.5 mm. As a test, a copper pipe with a diameter of 12 mm and a wall thickness of 1 mm was also installed in one section. The pipe connections were made by capillary brazing, for the steel pipes using an acetylene-air burner and for the copper pipe using a liquid gas-air burner. The nominal value of the connection pressure for the consumer devices was set in 85 mbar, which resulted in the following pressure ratios:

p _max = 100 mbar; p _nominal = 85 mbar; p _min = 73 mbar.

Some of the heaters 9 were replaced by the corresponding setting of the pre-throttle element of the automatic system and by replacing the pilot burner nozzle, others by adjusting the built-in pressure regulator, the wall heaters 11 and the gas stoves 12 by installing pre-throttle elements in the gas taps for operation at the higher level Nominal pressure made suitable. In the once-through water heater 10 alone, a device pressure regulator 8 had to be installed.

To install this gas supply system would have a lead mass according to the conventional method of 93 kg must be installed, whereas the Line mass, in the method according to the invention  was used was only 30 kg. That means one Metal savings of 68%. With the consumption lines the material saving was even more, even 75%. The installation work was productive, the measure of Destruction insignificant and the pipe network appealing.

The pressure values effectively measured at the same time as the maximum load were recorded in FIG. 2. The figure shows that the pressure at every measuring point remained within the pressure range of -10 to + 15%, which still guarantees normal operating conditions.

The advantages of the method according to the invention are even more evident in log houses and in Buildings made by tunnel switching technology were. Here the strength of the walls is very high high, it can even have a compressive strength of 240-400 kp / cm² reach, but at the same time the walls are quite thin. This makes it difficult to manufacture Wall breakthroughs, but favors the use of Impact drills after the wall breakthroughs relatively small holes can be replaced, and these holes with the tools mentioned very much can be easily manufactured. In such buildings can therefore the time required for the gas installation work be reduced significantly. This procedure is however also with the subsequent gas supply of old buildings of great advantage since the installation can be done without great destruction.

Further advantages of the method according to the invention  are the following.

There are only slight pressure fluctuations with the gas meter on. That's a reliable measurement simply calibrated for the given pressure Gas meter or with the help of a constant correction factor possible.

The conversion of the currently manufactured Gas appliances on the larger port pressure is relative easy. The load must be exchanged per burner the nozzle or by installation or by adjustment of pre-throttle elements can only be set a device pressure regulator must be installed for older device types will.

Made possible for a new generation of gas appliances the connection pressure of 85 mbar good chances in improving device properties. At a larger connection pressure can namely the nominal size of the gas-carrying parts chosen smaller and a full one Primary air supply to the burner can be realized. Smaller fittings can save costs, enable the over-stoichiometric burner good efficiency in a wide load range and the flame burns out in one smaller volume, correspondingly smaller combustion chambers are necessary.

The pressure drop at the consumption line can by the method according to the invention at the time usual value from 0.5 mbar to 19 mbar, for example increase. This enables the use of pipes  with a maximum nominal width of 13 mm for the Consumption line and after it in the apartments the climatic conditions also allow the wall thickness of these lines can be significantly reduced, whereby the significant already mentioned several times Metal savings result.

Claims (1)

System for the gas supply of buildings from known system parts, such as connecting lines, shut-off valves, gas meters and consumption lines, in which the fuel gas leaves the last required pressure regulator (operating, house or meter pressure regulator) with a maximum operating pressure permitted in buildings, characterized in that the nominal heat load of the gas devices is set for a connection pressure that is 85 to 90% of the operating pressure and that the minimum connection pressure of the least favorably located gas device in the apartment while operating all gas devices is at least 73% of the operating pressure.