RU2722076C1 - Valve for exhaust channel - Google Patents

Abstract

FIELD: construction technology; ventilation technology.SUBSTANCE: invention relates to a valve for an exhaust air duct. Valve for exhaust channel, made with possibility of connection with outer end of exhaust channel, comprises housing, having inner diameter (X2) and exhaust air hole, open funnel located inside housing and made with possibility of connection with flow connection with outer end of exhaust channel and air outlet in direction (Y) of flow to hole for exhaust air in housing, and insert (30), which: is located at least partially inside housing at distance (Y1) in direction (Y) of flow from outer end of exhaust channel, comprises reflecting surface expanding in direction (Y) of flow, wherein insert includes output surface converging in flow direction (Y), wherein the ratio of the distance (Y1) between the insert and the outer end of the exhaust air duct to the inner diameter (X2) of housing is 0.4 or more.EFFECT: due to new type of exhaust channel valve reduced pressure loss is achieved, which has favorable effect on energy efficiency of ventilation system without damage to channel protection; since ventilation equipment can operate at lower power than before, there is also an additional advantage of noise reduction in the ventilation system.12 cl, 3 dwg, 1 tbl

Description

FIELD OF TECHNOLOGY

[0001] The present invention relates to the field of construction technology. In particular, the invention relates to ventilation technology. More specifically, the invention relates to a valve for an exhaust duct, in accordance with the restrictive part of paragraph 1, to create a substantially laminar flow of exhaust air.

BACKGROUND

[0002] In particular, in the construction of the ventilation ducts of buildings equipped with forced ventilation, it is a common task to create an almost laminar air flow as possible to minimize aerodynamic drag, i.e. loss of pressure. To obtain a laminar air flow during the formation of ventilation ducts, sharp corners are avoided. The same applies to the valve installed at the end of the exhaust duct opening outside the building, the task of which is, on the one hand, to release exhaust air from the building, and on the other, to prevent rain, snow, debris, small animals and other outsiders from entering the ventilation duct items. Valves are known, i.e. “Caps” in which sockets are used that are connected to the end of the exhaust duct and extending in the direction of flow, above which there is an insert that transmits rainwater past the socket to the water outlet in the valve body. One such valve is the VILPE® Hattu-160 valve, through which the exhaust duct pipe is reliably protected without compromising the flow characteristics of the ventilation duct. Nevertheless, it would be advisable to further reduce the pressure loss in the ventilation duct to ensure the operation of ventilation equipment at reduced power and to increase energy efficiency.

SUMMARY OF THE INVENTION

[0003] One solution is a new type of valve that optimizes flow characteristics. Inside the valve body provided with an exhaust air opening, an outwardly open socket is arranged to be connected by means of a fluid connection to the external end of the exhaust air duct and to exhaust air in the direction of flow to the exhaust air opening in the housing. At least part of the insert located inside the housing, at some distance in the direction of flow from the outer end of the exhaust duct, contains a reflective surface that expands in the direction of flow, and a tapering exit surface. The ratio of the distance between the insert and the outer end of the exhaust duct and the inner diameter of the housing is 0.4 or more.

[0004] More specifically, the invention is characterized in that it is claimed in the characterizing part of claim 1.

[0005] Thanks to a new type of exhaust duct valve, a reduced pressure loss is achieved, which has a beneficial effect on the energy efficiency of the ventilation system, without compromising duct protection. Since ventilation equipment can operate at lower power than before, there is also the added benefit of reducing noise in the ventilation system.

BRIEF DESCRIPTION OF THE DRAWINGS

[0006] The following are described in more detail in some examples of embodiments of the present invention with reference to the accompanying drawings, in which:

FIG. 1 is a cross-sectional view of an exhaust duct valve in accordance with one embodiment of the present invention,

FIG. 2 is a sectional side view with additional reference numbers for an exhaust duct valve in accordance with FIG. 1 and

FIG. 3 is a cross-sectional perspective view of an exhaust duct valve according to FIG. 1.

The implementation of the invention

[0007] As shown in FIG. 1-3, the valve 100 of the exhaust duct 200 is configured to be installed on the outer end of the exhaust duct 200 outside the building. The valve 100 has a housing 10 configured to connect to the outer end of the exhaust duct 200. The housing 10 may be made of one or more parts. In the example shown in FIG. 1, the housing 10 comprises two parts 11, 12 connected to each other by means of a profile connection to facilitate installation. Alternatively, the parts 11, 12 can be connected to each other, for example, by gluing, screw connection, rivets or some other connection. From the point of view of manufacturing technology, a valve made of one part (not shown) can also be provided. The socket part 11 connects the outer end of the exhaust channel 200 by means of a profile, screw or other connection, and may include a cover 14 extending along the perimeter of the exhaust channel 200. The socket 11 contains a row of holes at the lower end 50 for removing water that are designed to drain rainwater, entering the housing 10, from the housing 10, without the accumulation of water inside the housing. Basically, the bottom surface of the socket 11 is configured to extend outward and downward from the center line of the valve 100 to direct rainwater outward from the valve body 10. In the examples in accordance with the figures, the lower surface, in addition, is curved, in particular, convex up.

[0008] The socket 11 also comprises a socket 40 located inside the housing 10 and configured to be connected with a flow connection to the outer end of the exhaust duct 200. In the embodiment shown in FIG. 1-3, the bell 40 is a separate component connected to the socket 11 through a profile connection. Alternatively, the bell 40 may be secured to the cover 14 by means of a profile or other connection, or at the junction between the socket 11 and the cover 14, or the bell 40 may be integral with the socket 11 or the cover 14. The bell 40 has a shape open in the direction of flow . Thus, the free end of the bell 40 is wider than its lower end connected to the exhaust duct 200. In this case, the flow direction is defined as normal to the hole connecting the bell 40 to the exhaust duct 200, which is in the embodiment shown in the figures vertical direction. Due to mounting tolerances, the flow direction Y may deviate from the vertical direction.

[0009] The casing 12 connected to the socket 11 of the housing 10 is configured to protect the bell 40 from environmental factors such as rain, litter and small animals. The casing 12 covers the bell 40 and contains an insert 30 located above the bell 40. More specifically, the insert 30 is located at a distance Y2 in the Y direction of flow from the bell 40 and at a distance Y1 from the outer end of the exhaust duct 200 to which the bell 40 is connected. Insert 30 can be completely contained in the housing 10, as shown in FIG. 1-3, or may extend above the housing 10 to output air flow (not shown). The insert 30 is made, on the one hand, to protect the socket 40 from environmental factors and, on the other hand, to facilitate laminar flow. Thus, the insert 30 comprises a reflective surface 31 expanding in the Y direction of the flow, which receives air coming from the exhaust duct 200 and is supplied by a bell 40. According to one embodiment of the invention, the reflective surface 31 is convex in the Y direction of the flow, being, for example, spherical, or it may have a shape with a varying radius (not shown). In other words, the lower part of the insert 30 is convex. The reflecting surface 31 distributes the incoming air in the direction of the casing 12 of the housing 10. More specifically, the reflecting surface 31 is configured to direct the flow of exhaust air across the flow direction Y, to the gap between the inner surface of the housing 10 and the insert 30, which has a width X3 in the transverse direction to the direction of flow Y. On the other hand, in the flow direction Y, the insert 30 has a tapering exit surface 32. In other words, the insert 30 has a tapering top. According to the embodiment shown in the figures, the exit surface 32 is a cone with a rounded apex, as well as other tapering shapes, for example, domes may be provided. The reflecting and output surfaces 31, 32 coincide along the circular outer edge of the insert. The outer edge is preferably made as a sawtooth drain edge 33, the sharp ends of which divide the flowing water mass into controlled drain flows, which helps to prevent curvature of the water flow in the direction of the axial line of the valve 10, and, therefore, in the direction of the socket 40. In other words, thanks to the drain edge 33, the flow of water is directed in the form of streams to the inner surface of the housing 10.

[0010] The upper end of the housing 10 is shaped so that an outlet 20 is formed between the casing 12 and the insert 30. Thus, the outlet 20 is located at the outer end of the housing 10, in the Y direction of flow. In other words, the housing 10 is open from above. The outlet 20 is annular to prevent rainwater from entering the socket 40. The housing 10 also encompasses a guide member 13, which surrounds the outlet surface 32 of the insert 30, between the insert 30 and the housing 10. According to an embodiment of the invention shown in the figures, the guide member 13 is a cylinder 13 that extends and tapers in the Y direction of flow. The guide element 13 is relatively short and is positioned to surround the insert 30 from above, thereby causing the smallest possible pressure loss. The guide element 13 contributes to the direction of rainwater from the bell 40.

[0011] When selecting the shape of the valve 100, particular attention is paid to the behavior of the compressible and fluid substance in the channel. Thus, a relationship has been developed between the dimensions of the valve 100 to minimize turbulence, but without compromising the protection of the socket 40. According to one embodiment of the invention, for example, the ratio of the distance Y1 between the insert 10 and the outer end of the exhaust duct 200 to the inner diameter X2 is 0.4 or more. If, for example, the valve 100 is made with dimensions suitable for the 125 mm exhaust duct 200, the size of X4 of which is 125 mm, the ratio Y1 / X2 is of the order of 0.6. If the valve 100 is made with dimensions suitable for a 160 mm exhaust duct 200, the size of X4 of which is 160 mm, the ratio Y1 / X2 is of the order of 0.5. As the ratio increases, the distance of the insert 30 from the exhaust duct 200 becomes larger, so that the flow of exhaust air can pass into the valve 100, only smoothly flowing around the insert 30. For the same purpose, the insert 30, in accordance with one embodiment of the invention, is located at a distance Y2 in the direction of flow from the bell 40, so that the ratio of the distance Y2 between the insert 30 and the bell 40 to the inner diameter X2 of the housing 10 is 0.1 or more, preferably 0.2 or more. If, for example, the valve 100 is made with dimensions suitable for a 125 mm exhaust duct 200, the size of X4 of which is 125 mm, the ratio Y2 / X2 is of the order of 0.2. If the valve 100 is made with dimensions suitable for a 160 mm exhaust duct 200, the size of which X4 is 160 mm, the ratio Y2 / X2 is of the order of 0.13. Thus, the flow remains smooth. It should be understood that the dimensions of real parts may differ from the nominal dimensions indicated above.

[0012] On the other hand, it is advisable to consider the protective characteristics of the insert. Therefore, the outer diameter X1 of the insert 30, especially the largest outer diameter at the drain edge 32, is sufficiently large compared to the inner diameter X5 of the socket 40. According to one embodiment, the ratio X1 / X5 is 1 or more, preferably 1.2 or more. If, for example, the valve 100 is made with dimensions suitable for a 125 mm exhaust duct 200, the size of X4 of which is 125 mm, or for a 160 mm exhaust duct 200, the size of X4 of which is 160 mm, the ratio X1 / X5 is of the order of 1, 2. Thus, the insert 30 is wide enough with respect to the size of the horn 40. As is evident from the above examples, the insert 30 need not be significantly wider than the inner diameter X5 of the socket 40.

[0013] Similarly, it is advisable to provide a sufficiently wide gap between the insert 30 and the inner surface of the housing. According to one embodiment of the invention, the ratio of the width X3 of the gap between the insert 30 and the housing 10 to the inner diameter X4 of the exhaust duct 200 is 0.1 or more, preferably 0.2 or more. On the other hand, the ratio of the gap X3 between the insert 30 and the inner surface of the housing 10 to the inner diameter X2 of the housing 10 is 0.05 or more, preferably 0.1 or more.

INDUSTRIAL APPLICABILITY

[0014] A known valve was compared with a valve made in accordance with one embodiment of the present invention, in a flow simulation in which, at a flow speed of 5 m / s, the flow characteristics of a conventional valve and a valve made in accordance with one embodiment were compared with each other of the present invention, intended for 125 mm exhaust duct, the test results are shown in the table:

[0015] Parameters Y2 / X1, Y2 / X2, Y2 / Y1 and Y1 / X2 in the column of the Known Valve table are omitted due to the absence of an insert provided with a convex reflective surface. However, the insert had an exit surface tapering in the direction of flow, as well as a comparable valve made in accordance with one embodiment of the present invention. As is apparent from the table, a new type of valve can be used to achieve a pressure loss of almost 30% less than with a known valve.

LIST OF REFERENCE POSITIONS

Claims (23)

1. The valve (100) for the exhaust channel, made with the possibility of connection with the outer end of the exhaust channel (200) and containing: a housing (10) having an inner diameter (X2) and an opening (20) for exhaust air, open bell (40) located inside the housing (10) and made with the possibility of connection with a flow connection with the outer end of the exhaust channel (200) and air exhaust in the direction (Y) of the flow to the exhaust hole (20) in the housing (10) , and insert (30), which:

located at least partially inside the housing (10) at a distance (Y1) in the direction (Y) of the flow from the outer end of the exhaust channel (200),

contains a reflecting surface (31), expanding in the direction (Y) of the flow, while the insert

comprises an exit surface (32) tapering in the direction (Y) of the flow, characterized in that the ratio of the distance (Y1) between the insert (10) and the outer end of the exhaust duct (200) to the inner diameter (X2) of the housing is 0.4 or more. 2. The exhaust duct valve (100) according to claim 1, wherein the ratio of the distance (Y1) between the insert (10) and the outer end of the exhaust duct (200) to the inner diameter (X2) of the housing is 0.5 or more. 3. Valve (100) of the exhaust duct according to claim 1 or 2, in which the housing (10) has an open upper part. 4. An exhaust duct valve (100) according to claim 1, 2 or 3, wherein the reflective surface (31) is convex in the direction (Y) of the flow. 5. The valve (100) of the exhaust duct according to any one of the preceding paragraphs, in which the insert (30) is located at a distance (Y2) in the direction (Y) of the flow from the socket (40), wherein the ratio of the distance (Y2) between the insert (30) and the bell (40) to the inner diameter (X2) of the housing (10) is 0.1 or more, preferably 0.2 or more. 6. An exhaust duct valve (100) according to any one of the preceding claims, wherein the insert (30) has an outer diameter (XI) transverse to the flow direction, however, the ratio of the outer diameter (X1) of the insert (30) to the inner diameter (X5) of the outer end of the socket (40) is 1 or more, in particular 1.2 or more. 7. An exhaust duct valve (100) according to any one of the preceding claims, wherein the largest outer diameter (XI) of the insert (30) is larger than the diameter of the mouth of the bell to prevent rainwater from entering the bell. 8. The exhaust duct valve (100) according to any one of the preceding claims, wherein the reflective surface (31) is shaped to direct the exhaust air flow in a direction transverse to the flow direction into the gap between the inner surface of the housing (10) and the insert ( thirty), moreover, the gap has a width (X3) in the direction transverse to the direction (Y) of the flow. 9. An exhaust duct valve (100) according to any one of the preceding claims, wherein the ratio of the width (X3) of the gap to the inner diameter (X4) of the exhaust duct (200) is 0.1 or more, preferably 0.2. 10. An exhaust duct valve (100) according to any one of the preceding claims, wherein the ratio of the width (X3) of the gap to the inner diameter (X2) of the housing (10) is 0.05 or more, preferably 0.1 or more. 11. An exhaust duct valve (100) according to any one of the preceding claims, wherein the insert (30) comprises a sawtooth drain edge (33) between the reflecting surface (31) and the outlet surface (32) in the flow direction (Y). 12. An exhaust duct valve (100) according to any one of the preceding claims, wherein, when mounted, the flow direction (Y) is vertical or substantially vertical.

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