NL8702344A - SYSTEM FOR EXTRACTING WASTE GASES AND / OR AIR SUPPLY. - Google Patents

Description

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System for the discharge of waste gases and / or the supply of air.

The invention relates to a system for the discharge of waste gases and / or the supply of air, consisting of a shaft with vertical walls enclosing channels for transporting the gases and closing members closing off the top of the shaft through which the channels are connected via nozzles opening, whereby the shaft can be placed on the roof of a building.

Usually such a shaft consists of masonry bricks, the shaft enclosing one or more channels which open into the atmosphere at the top of the shaft. One or more of these ducts within the same shaft may be connected to a stove and serve as a flue for the exhaust of combustion gases. One or more other channels within the same shaft can serve as a discharge of polluted air from, for example, a kitchen, bathroom or toilet. Yet another channel in this same shaft can serve to supply air to sewer pipes in the building.

It is objectionable that this known shaft is relatively expensive because bricklaying of bricks is time-consuming. In addition, such a shaft is heavy, so that special facilities are required in the building to support the weight of the shaft. It is also not possible to set up an extra channel in an existing shaft.

According to the invention, these and other drawbacks are eliminated in that the closing members consist of modules, with which the horizontal cross-section of the shaft can be closed by arranging the modules next to each other and wherein the modules can moreover be arranged up to floors one above the other. The shaft is preferably a tube with a cross section such that a standard number of modules can fit therein, such as for instance two rows of two or three modules of approximately 25 by 25 centimeters or 3 rows of 3 modules of approximately 25 by 25 centimeters. In addition, 8702344-2 are preferably the walls of the box of easy to cut material, such as plastic sheet, to adapt the bottom end of the box to the shape and slope of the roof of the building.

The invented modules each consist of a horizontally arranged plate with standard dimensions, such as about 25 by 25 centimeters and about 25 by 12.5 centimeters. Each plate is preferably provided at its corners with upwardly extending legs for mounting a module of the next floor or a roof plate on the highest module. Here, a vertical piece of tube is arranged eccentrically in the plate, the tube piece preferably protruding as far below the level of the legs as is necessary for a good discharge of gases between the top end of the tube piece and the bottom side of the following higher empty module or the roof plate, with the pipe section protruding as far below the 15 module as is necessary to connect to the pipe section of the next lower module.

These and other features of the invention are set out in the accompanying claims.

In summary, the invention provides a small number of different standard elements with which shafts can be placed on roofs with very different inclination, while with a small number of different standard modules very different systems of supply channels and discharge channels can be taken into account. The shafts and modules are manufactured centrally in the factory, preferably made of plastic, so that, due to the simple assembly and the small number of different standard parts for shafts and the also small number of different standard modules, an inexpensive shaft with supply and discharge members can be built. In addition, this system of the shaft with the modules has a very low weight compared to the usual masonry shafts, so that no special provisions in the building are required to bear the weight of the shaft, modules and other elements.

The invention will be further indicated in the following description of exemplary embodiments indicated 8702344-3 in the accompanying drawing.

Figure 1 is a diagram of a building with a shaft with modules on the roof according to the invention.

Figure 2 is a diagram as according to Figure 1, where the shaft is adapted to a strongly sloping and high-reaching roof.

Figure 3 is a side view of a module according to the invention.

Figure 4 is a bottom view of the module according to Figure 3.

Figure 5 is a diagram for a possible arrangement of the modules in the shaft section.

Figure 6 is another diagram for a possible arrangement of the modules in the shaft cross section.

Figure 7 is a side view of two modules arranged one above the other with a roof plate on top of which a metal protective plate is attached.

Figure 8 is a perspective view of some modules placed on the shaft and the girders.

Figure 9 schematically shows the invented shaft with a chimney for, for example, a fireplace.

Figure 10 shows a manner in which a draw beam can be attached to the edge of the shaft.

Figure 11 schematically shows part of a labyrinth wall mounted in a partially drawn module.

As can be seen from Figure 1, the invention mainly aims at a system consisting of a shaft 1, a very limited number of types of modules 2 and 10 which can be fixed in levels on the shaft and a roof plate 3 which can be mounted on top of the modules . This system can be placed on the roof 4 of a building.

The shaft 1 is composed of four perpendicularly placed walls of, for example, plastic sheet, which are bonded together in known manner. These plates are the same height, so that the shaft can be placed on a flat roof. By cutting off parts of the shaft, the shaft can be adapted to the slope of the roof of a building 8702344-4, as shown in figures 1 and 2. However, it is necessary that the mouths of the channels through the shaft are clear. accessible to wind, so that with a high roof as according to figure 2 a single shaft piece 1 does not reach high enough 5 relative to the highest part of the roof. For this reason, an additional shaft piece 5 has been placed on the shaft 1, the shaft 5 being otherwise constructed in the same manner as the shaft 1. The walls of the tube are so low that a straight cut with an angle of 55 ° to the vertical is possible. is between two vertical edges of a box wall. This is indicated in figure 2 for the lower shaft piece 1.

The upper end of the shaft can be closed by modules 2 and 10, each of which, according to Figures 3 and 4, is provided with a plate 6 of, for example, 25 by 25 centimeters or 25 by 12.5 centimeters-15 meters. Depending on the location of the channels in the shaft, the top end of the shaft can be closed with these modules, the channels connecting to pipe pieces 9 in the modules. Figure 5 gives an example of an arrangement of the invented standard modules at a shaft diameter of approximately 75 by 50 centimeters-20 meters and Figure 6 gives an example of an arrangement of the standard modules at a shaft diameter of approximately 50 by 50 centimeters. A shaft diameter of 75 by 75 centimeters is also possible.

According to figures 3 and 25, each invented module consists of a plate 6 with an upwardly extending leg 7 in each corner.

Ribs 8 are provided along the edges of the plate at the bottom thereof. The plate can be closed or pierced by a pipe piece 9, which, as can be seen from Figures 5 and 6, has a round cross section with square modules. To connect to a channel with a standard diameter of approximately 12.5 centimeters in the shaft, the diameter of the pipe section 9 is also 12.5 centimeters. However, such a cross-section is too large for a module measuring 25 by 12.5 centimeters, and in order to avoid constriction, the pipe section 9 with oval cross-section, such as 870 2.34 4 - 5, is therefore shown in Figures 5 and 6 in the latter type of modules. .

The pipe pieces 9 are arranged eccentrically in the plate 6, so that the position of the plate can be adapted as much as possible to the position of the channel in the shaft, whereby the channel connects to the pipe piece without too much bending. The position of the modules 2 with pipe piece 9 in the section of the shaft has thus been determined, with figures 5 and 6 giving examples thereof. The rest of the cross section of the shaft can be closed by modules 10 which are the same as modules 2 with the exception that the plate 6 is closed at modules 10. Each module or parts thereof can be manufactured as one piece from plastic.

In order to carry the modules 2 and 10 in the shaft opening, the shaft 1 according to figure 8 is provided with an inwardly extending flange 11 with an upwardly extending rib 12. The wall 15 of the shaft 1 can be arranged with the flange 11 and the rib 12 as be made entirely of plastic. The module 2 or 10 extends with its plate 6 over the rib of the shaft, so that the module rib 8 extends beyond the longitudinal shaft ribs 12, whereby a connection of the module to the shaft is sealed against rainwater penetration.

On the sides remote from the shaft edge, the module 2 or 10 rests on a system of beams 13 with U-shaped cross section. The ribs 8 of the module protrude into the U-shaped space of the supporting beams, whereby rainwater is prevented from penetrating from the plate 6 into the shaft 1.

At their intersections, the girders 13 are welded together as shown in Figure 8 for the intersection 14. The ends of the girders 13 can, according to Figure 10, extend through a recess in the rib 12 at the edge of the shaft 1, so that any rainwater collected in the supporting beams can flow out of the shaft, while the supporting beams are moreover carried by the shaft. The support beam 13 may be provided with a mounting plate 15 which can be bolted to the shaft 1 6702344-6.

When 1 (not shown) channels pass through the same shaft for waste gases and ventilation air, it is desirable to adjust the mouths of those channels at different levels at 5 in order to prevent waste gases from entering the ventilation air. For this purpose the modules 2 and 10 can be stacked on each other in levels as according to figure 7, which shows a lower module, on which a higher module is arranged on its legs 7. The part of the pipe piece 9 of this higher module projecting below the higher module connects to the upwardly projecting part of the pipe piece 9 of the lower module. For a good connection between the two pipe pieces, the top edge of each pipe piece 9 according to figure 3 is provided with a narrowed extension 16 which fits into an internal recess 17 in the wall at 15 the bottom end of each pipe piece 9. Thus a pipe for discharge of connect waste gases to the lower pipe section 9 in figure 7, whereby the gases are released into the atmosphere via the upper pipe section 9 connecting to the lower pipe section 9.

A module (not shown) located next to the bottom module in Figure 7 can also be provided with a pipe piece 9, while a module located next to the top module in Figure 7 has not a pipe piece 9 but a closed plate 6. As a result, a channel for supplying (ventilation) air can be connected to the pipe section of the lower module 25, not shown, and thus connectable to an atmosphere that is free of flue gases, because those gases in the upper module with the pipe section 9 shown in figure 7. be issued. The bottom floor modules can thus be reserved for supply of (ventilation) air and the top floor modules can be reserved for the discharge of waste gases. If desired, a third floor of modules can also be used, with the bottom floor serving for ventilation air supply, the middle floor for extracting ventilation air and the top floor for flue gas discharge. This prevents flue gases from ending up in ventilation ducts and / or aeration ducts, or 35 waste gases from entering the ventilation ducts into the ventilation ducts, while also allowing maximum draft on the flue gas ducts. All these floors can be assembled from the standard modules described above and shown in the drawing. A metal lining may be required for flue gases.

According to figure 7, a roof plate 3 is fixed on the legs 7 of the modules 2 and 10 in the highest floor, wherein a piece of metal 18 can be attached under the roof plate above the flue gas discharge pipe to protect the roof plate from hot flue gases. This metal plate is especially necessary when the roof plate is made of plastic. Such a metal plate can also be mounted on the underside of a higher module if it is to be protected from the heat of gases emitted from the pipe section in a lower module.

As shown in Figures 4, 7 and 8, a passage 19 extends through each leg 7 of each module 2 and 10, with long bolts 20 extending from the roof plate 3 to the shaft 1 projecting in these passages around the roof plate and the modules. fix the floors on the shaft. The dimensions of the roof plate 3 are adapted to the dimensions of the cross section of the shaft 1.

A labyrinth insert 21 can be fitted at the outlet level to prevent rain and birds from entering. An example of such a labyrinth insert 21 is shown in Figure 11.

A chimney for the discharge of flue gases from a fireplace for, for example, logs, must have a larger cross-section that is possible with the pipe pieces 9 in the module 2. In that case, the construction according to figure 9 is possible, wherein the shaft 1 is closed by cover plates 23 with the exception of a (central) opening which opens into a chimney 24 on which a hood 25 is placed. Also in this construction, the shaft is built up from the above-described factory-manufactured standard parts which are therefore inexpensive and have a low weight because they are made of plastic.

8702344

Claims (15)

1. System for discharging waste gases and / or supplying air, consisting of a shaft with vertical walls enclosing channels for transporting the gases and closing members closing off the top of the shaft through which the channels open via nozzles, in which the shaft can be placed on the roof of a building, characterized in that the closing members consist of modules with which, by arranging the modules next to each other, the horizontal cross-section of the shaft can be closed, and in addition the modules are also up to levels above each other be deployable. System according to claim 1, characterized in that the modules each consist of a horizontally arranged plate with standard dimensions, such as 25 by 25 centimeters and 25 by 12.5 centimeters. System according to claim 2, characterized in that each plate is provided at its corners with upwardly extending legs for arranging a module of the next floor or a roof plate on the highest module. System according to claim 2 or 3, characterized in that a vertical piece of tube is arranged eccentrically in the plate. System according to claim 4, characterized in that the pipe section has an oval cross-section with an elongated plate of, for example, 25 by 12.5 centimeters. System according to claim 4 or 5, characterized in that the pipe section protrudes as far below the level of the legs as is necessary for a good discharge of gases between the top end of the pipe section and the bottom side of the next higher module or the roof plate, wherein the tubing extends beyond module 30 as necessary to connect to the tubing of the next lower module. System according to any one of claims 3 to 6, characterized in that a leg extends through each leg for a screw bolt for mounting modules and the roof plate on top of each other and the roof plate together. System according to any one of the preceding claims, characterized in that each module is provided with ribs extending along the edges of the plate at the bottom thereof. System according to any one of the preceding claims, characterized in that the shaft is a tube with a diameter such that a number of standard modules can fit therein, such as, for example, two rows of two or three modules of 25 by 25 centimeters or three rows of three modules of 25 at 25 centimeters. System according to claim 9, characterized in that the walls of the tube are of easy to cut material, such as plastic sheet, to adapt the lower ends of the tube to the shape of the slope of the roof of the building. System according to claim 10, characterized in that the walls of the tube are so long that a straight cut with an angle of 55 ° to the vertical is possible between the two vertical edges of a tube wall. System according to any one of the preceding claims, characterized in that the top edge of the shaft is provided with an inward flange with an upwardly extending rib thereon, such that the ribs can be arranged at the bottom of the modules outside the shaft rib. System according to any one of the preceding claims, characterized by cross-section U-shaped girders supported with at least one end in a recess in the top edge of the shaft and, if necessary, welded with the other end to a perpendicularly intersecting other of these girders, the ribs 30 at the bottom of the module can be inserted into these beams in the U-shaped space. System according to any one of claims 3 to 13, characterized in that a labyrinth wall can be arranged between pairs of legs on one side of a module. System as claimed in any of the foregoing claims, 8702344-10 - characterized by a metal plate which can be arranged on the legs of a module in order to protect the module or roof plate situated above this plate against waste gases originating from the pipe section in the first-mentioned module. -o-o-o-o-o-o-o-o-o- 8702344