NL1017351C2 - Combustion system comprises combustion air feed pipe for boiler and combustion gas feed pipe, with corresponding roof inlets for them - Google Patents

Abstract

The system comprises a combustion air feed pipe for a boiler and a combustion gas feed pipe, with corresponding roof inlets for them. Where a corrugated roof is concerned (6), two roof inlets (1) are positioned between two roof plates (2) provided with corrugations, on a horizontal line with a center to center spacing of three roof plate widths. The left roof inlet is connected via an air feed conduit (3) to the burner of an interior boiler (5). The burner is connected via a gas outlet conduit (4) to the right roof inlet.

Description

Roof transit system

The invention relates to a system of a combustion air supply pipe for a boiler and a combustion gas discharge pipe therefor, with associated protruding roof passage means for a flat roof or sloping roof.

Such systems are widely known as concentric, vertical discharge structures, wherein the discharge pipe is received in the supply pipe and ends in a discharge cap which is located above a supply cap connected to the supply pipe. The inlet is here -in projection on the horizontal plane- in the same place as the outlet. There is, however, a difference in shape and in vertical position, so that with pressure changes on the sloping roof, such as with falling winds or gusts, the pressure change at the inlet is different from that at the outlet side. As a result, the pressure difference across the burner in the boiler changes, which is detrimental to the efficiency and the operation of the boiler.

A further disadvantage is that the placement axially consecutively of the mouths of the drain and the feed results in the environment of the drain being formed / limited differently from that of the feed, in other words that the drain influences the feed, which causes further differences in pressures.

A further disadvantage is that recirculation can occur between discharge and supply. When measures are taken against this, they increase the differences between the environment of the supply and the discharge.

The invention now has for its object to improve this, and for this purpose provides a system of a combustion air supply pipe for a boiler and a combustion gas discharge pipe therefor, a roof passage for the supply pipe and a roof passage for the discharge pipe, the two roof passages being provided with means for placing on a roof with a normal having a vertical directional component and having an upper roof part, wherein the roof passages for the upper roof part thereof are externally substantially uniformly shaped and aligned.

The upper roof portions of the drain and the feed are hereby pulled apart, from a concentric arrangement to a separate parallel arrangement, so that the position with respect to the roof is the same. Due to the same design, combined with the same orientation, relative to the roof, the aerodnamic conditions are substantially the same for both roof penetrations. As a result, a dynamic pressure difference occurring on the roof will have an equal effect on the discharge and the supply, the pressure difference across the burner not being changed.

The two roof passages are preferably provided with means for placement on a sloping roof.

In a further development of the system according to the invention, the two roof passages have a substantially horizontally directed outlet.

In order to keep pressure changes on both penetrations as much as possible even in more extreme wind conditions, it is preferable that when placed on a sloping roof the two roof penetrations are placed at a center-to-center distance of more than approximately 0.2 meters.

In that case, if the sloping roof is a tile roof, the center-to-center distance is preferably at least one pan width, in particular a multiple of the pan width.

The two roof penetrations can be positioned straight or diagonally above each other in (along) the roof surface. For optimizing the equalization of the aerodynamic conditions at the outlet and the supply, it is preferable that the two roof penetrations are placed at a distance from each other in one horizontal line.

The invention furthermore relates to a system as described above, including a boiler connected to the supply and discharge.

The invention will be elucidated on the basis of an exemplary embodiment shown in the accompanying drawings. The following is shown in: figure 1 a view of a part of a tiled roof, in which an exemplary embodiment of the system according to the invention is arranged; figure 2 shows a vertical section through a roof terminal used in the system of figure 1; and figure 3 is an isometric view of the roof outlet of figure 2.

Figure 1 shows a sloping roof with tiled roof 6, wherein two roof ducts 1 in the system according to the invention are placed between the two-tiled roof tiles 2, on one horizontal line, at a center-to-center distance from in this case three roof tile widths. The roof passages 1 are placed at some distance from the side edge of the roof, in a free roof area. The left-hand roof outlet 1 is connected via an air supply line 3 to the burner of an inner-roof boiler 5, which burner is connected to the right-hand roof outlet 1 via gas discharge line 4.

The two roof passages 1 are identical to each other at least with regard to the surface located on the outside of the sloping roof, and differ only in that one is connected to a supply line and the other is connected to a drain line. Furthermore, the material of the pipes may differ due to differences in thermal and chemical conditions of use. This is also shown schematically in Figure 2, wherein the cross-section through both roof liners 1 is shown. Partly with reference to figure 3, the construction of the roof terminal 1 will be discussed briefly.

The roof lead-through 1 essentially consists of a cap or bump 9 of, for example, plastic, which is provided on the roof side with a circulating flange 15. With the circulating flange 15, the roof lead-through 1 rests on a lead bib 8, which itself is supported by a can. bottom plate 12. This can bottom plate 12 is provided with fixing holes for fixing the roof lead-through 1 on the roof construction, which fixing holes are covered by the (when folding up) lead flashing 8. The pans 2 can extend over the flashing 8.

The cap 9 is secured to the lead-through slab-20 sheet plate with the aid of a snap ring 13 provided with a circumferential flange 16, which at the location of 14 enters into a snap connection with the cap 9. With this, the roof lead-through can be assembled, 2, can be placed as a whole on a roof.

The cap 9 is furthermore provided here with a horizontally directed end face 10, in which a hole is present for passage of an end pipe 19. The end pipe 19 is herein sealed in a sealed but somewhat tiltable manner (in order to be able to adjust the angle of inclination) in the cover 9 included. To this end, the end face 10 is provided with a circumferential collar 11 formed thereon to which a rubber sealing sleeve 17 can be fixed by flipping it outwards with portion 18 around the ring 11. The sealing sleeve 17 is furthermore provided with a circumferential sealing rib 24 having a triangular cross section and which is sealingly clamped against the inner surface of the collar 11, whereby at the bottom of the collar 11, at the location of 25, a drainage hole the collar 11 is provided to allow water to escape.

The end pipe 19 is provided at the end with a radial grating 23 clamped therein by press fit, and 5 extends with its inner end into a widened end part 21 of the connecting bend 20, which can be connected to either an inner roof discharge pipe 4 or an inner roof supply pipe 3. The widened portion 21 is furthermore provided with a ring chamber 22, in which a rubber sealing ring 10 can be received.

As is shown in Figure 1 with the arrows P, the circumstances at the location of both roof passages 1 are the same in the event of a change in the pressure of the environment, for example with a gust of wind. In both roof passages, in particular in both end pipes thereof, the pressure will then increase by ΔΡ, so that the actual pressure difference across the burner does not change.

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Claims (9)

A system of a combustion air supply pipe for a boiler and a combustion gas discharge pipe therefor, a roof passage for the supply pipe and a roof passage for the discharge pipe, the two roof passages being provided with means for placement on a roof with a normal having a vertical directional component, and have an upper roof part, wherein the roof passages for the upper roof part thereof are externally substantially shaped and aligned. A system according to claim 1, wherein the two roof passages are provided with means for placement on a sloping roof. 3. System as claimed in claim 1 or 2, wherein the two roof passages have a substantially horizontally directed outlet. A system according to claim 1, 2 or 3, placed on a sloping roof, wherein the two roof penetrations are placed at a center-to-center distance of more than approximately 0.2 meters. The system of claim 4, wherein the sloping roof is a tile roof, wherein the center-to-center distance is at least one pan width. The system of claim 5, wherein the center-to-center distance is a multiple of the pan width. 7. System as claimed in any of the foregoing claims, wherein the two roof penetrations are placed in a horizontal line at a distance from each other. 8. System as claimed in any of the foregoing claims, including a boiler connected to the supply and discharge. 1 01 7 3 51 9. System provided with one or more of the characterizing measures described in the attached description and / or shown in the attached drawings. -o-o-o-o-o-o-o-o-1Ö1 7 3 51