SE0950029A1 - Induction apparatus for combining air flows - Google Patents

Description

Another problem is that the degree of use of the heat exchanger becomes uneven and poorly optimized in that the static negative pressure generated by the primary air nozzles over the inlet opening connected to the heat exchanger varies over different parts of its area. Thus, the static negative pressure is almost 100% in the part of the inlet opening area closest to the duct wall with the primary air nozzles, while the static negative pressure goes towards 0% in the part of the inlet opening area which is furthest from this duct wall.

Previously known induction devices (fi g. L) thus have a curved flow path for the secondary air, which in combination with an uneven static pressure over the heat exchanger surface means that the air cannot be distributed evenly over the heat exchanger surface.

An object of the invention is to provide an improved induction apparatus which does not suffer from the problems and disadvantages described above in hitherto known technical solutions of the type in question.

This is possible with an induction apparatus according to the invention which has the characterizing features of the independent claim 1. Advantageous further developments and improvements of the invention appear from the independent claims as well as from the description and drawing.

Experiments with computer simulation (so-called CFD simulation) which have been performed with the induction apparatus according to the invention have shown that the velocity distribution becomes very iron over the secondary air intake.

With the design according to the invention, the flow paths through the induction device are straight from the secondary air intake to the outlet with as low a flow resistance as possible to maximize the secondary lu fifl flow. If applicable, the flow through a connected heat exchanger then becomes uniform, which leads to an optimal utilization of the heat exchanger surface. The invention is described in more detail below with reference to the accompanying schematic drawing. In the drawing, fi g. 1 is a cross-section through an induction apparatus of a conventional type, fi g. 2 shows a cross section through an embodiment of an induction apparatus according to the invention with an induction channel, fi g. 3a shows a cross section of a further embodiment formed provided with a partition wall and two induction channels, fi g. 3b and 3c are perspective sketches showing how the induction apparatus in fi g. 3a can be formed in sections, fi g. 4 shows a variant of the induction apparatus in fi g. 3 with three induction channels and fi g. 5 shows a further improved embodiment of the induction apparatus in fi g. 3.

In the drawings, the same details and details with the same function have been assigned the same reference numerals.

Fig. 1 shows a previously known induction apparatus 2 which has so-called duct-bound primary air nozzles 4 formed directly in the wall of a primary air duct 6, which is connected to a fresh air fan (not shown). Extending from the duct wall with the primary air nozzles 4 and parallel to the outflow direction for these is an induction duct 8, which in its duct wall in connection with the primary air nozzles 4 has a secondary air intake 12 connected via a heat exchanger 10, towards an outlet 14 common to the air mixture.

The secondary air intake 12 is located across the spreading direction of the primary air nozzles 4.

With its true pressure, the released air jet produces jets through the nozzles 4, which in turn generate a static negative pressure over the secondary air intake 12 and the connected heat exchanger 10. The secondary air is thus sucked in through the secondary air intake 12 the secondary air is forced to change direction by approximately 90 degrees during mixing with the primary air before the air mixture is returned to the ambient air through the common outlet l4. As previously mentioned, the static negative pressure generated by the primary air nozzles thus varies over the inlet opening connected to the heat exchanger over different parts of its area. Thus, the static negative pressure is almost 100% in the part of the area of the inlet opening closest to the duct wall with the primary air nozzles 4, while the static negative pressure goes towards 0% in the part of the area of the inlet opening which is furthest from this duct wall.

F ig. 2 shows a cross section through a basic embodiment of an induction apparatus 20 according to the invention with an induction channel 21, which on the other hand extends substantially straight from an upstream end with a secondary outlet inlet 22 to a downstream end with an outlet 24 and has a reference line passing through the ends. A.

The flow paths from the upstream spirit with the secondary air intake 22 to the downstream end with the outlet 24 are thus straight and parallel to the reference line A, which gives a significantly lower flow resistance compared to the prior art and thus a maximized secondary air fl fate. In an advantageous manner, moreover, when a heat exchanger 26 is connected to the secondary air intake 22, due to the straight flow paths through the induction apparatus, a uniform flow through the heat exchanger 26 is also obtained, which leads to an optimal utilization of the entire heat exchanger surface. Thus, the variations in the static negative pressure are very small and close to 100% over the entire area of the inlet opening 22.

The induction apparatus 20 according to the invention is also provided with primary air nozzles in the form of duct-connected first openings 28, which may be formed directly in a first duct wall 29 between the induction duct 21 and a first primary air duct 30, which is also connected to a fresh air duct (not shown). In this embodiment, the first channel wall 29 has been proliferated to a substantially z-like shape with a web 32 running transverse to the reference line A, in which resp. first opening 28 is occupied and with which a co-current directed primary air fl F1 is insertable in the induction duct 21 with a relatively small angle u of cza 0 - 10 ° towards the reference line A. The life 32 is suitably located at cza 1/3 of the distance between the secondary air intake 22 and the outlet 24. From the web 32 a first leg of the first duct wall 29 extends diverging relative to an opposite second duct wall 34 towards the secondary air intake 22 and connects to its delimitation against an outer wall 36 of the first primary air duct 30. The second the duct wall 34 forms the opposite boundary of the secondary air intake 22, through which the entire cross section of the secondary air intake 22 is open towards the induction duct. Extending from the web 32 in the direction of the outlet 23 is a second leg of the first duct wall 29 converging relative to the second duct wall 36 a further 1/3 in such a way that a cross section which is smaller than half the cross-section of the secondary air inlet provides has a substantially constant cross-section over the remaining 1/3 towards the outlet 24. The second channel wall 36 of the induction channel 21 may have an extending extent corresponding to this cross-section. The secondary air intake 22 thus has an area which is at least twice as large as the outlet 24 and thus a venturi 38 is formed, the venturi effect of which contributes to a greater suction effect in the secondary air intake 22.

Fig. 3a shows a further improved embodiment similar to that of Fig. 2, with a two-channel induction apparatus 20 'made of two mirror-inverted induction apparatuses 20 with a first induction duct 21' and a second induction duct 21 ", each having its own primary air duct, a first primary air duct 30 'and a second primary air duct 30' with associated first openings 28 '. Each second duct wall 34 has here been replaced by a partition wall 38 »which separates the first induction duct 21' from the second induction duct 21 By means of the partition wall 38 it is possible to distribute different air fl fates to the induction ducts by, for example, equipping the first primary air duct 30 'and the second primary air duct 30' with different first openings 28 '. Alternatively, each first opening 28', or one in each induction duct blowing group of first openings 28 'can be closed in a manner known per se, in order to enable, for example, the first induction channel 21' while the second induction channel 21 ”is still in operation or vice versa. The regulation of primary air can also be controlled in other ways between the primary air ducts, e.g. by damper control of the inlet to each primary air duct or by using different fans that are individually adjustable, to create the intended effect. An example may be that the first primary air duct 30 'is used for a shallow desert and the second primary air duct 30 "and / or additional primary air ducts, which will be described later with reference to fi g. 4, are used for one or more feedings. In the case of three primary airflows in the respective induction duct, the partition wall 38 provides separate liquor paths for each duct and thus an optimal induction.

The partition can also be movably designed, ie. if the first primary air duct 30 'has the most primary air, the first induction duct 21' should be larger, which can thus be solved by displacing the partition wall 38 in some known manner towards the second induction duct 21. Figs. 3b and 30 are perspective views showing how the inductor 20 'in fi g. 3a can be formed in sections, where each section 40 is box-shaped with the height H, the depth D and the length L and comprises the two primary air channels 30 '; 30 'and the two induction channels 21'; 21 As trarngår of fi g. 3b, the "profiled web 32" of the first duct wall 29 may, for example, be provided with a group of three first openings 28 ', which connect each primary air duct to the associated induction duct. Thus, as shown in fi g. 3e, an induction apparatus 20 "can thus be constructed in modular form of one or more sections 40, depending on the capacity required in the present case. Due to the modular construction in sections 40, an induction apparatus 20" with the height H, the depth D and the length nx L is composed of a linear number n sections 40 in accordance with the current ventilation and / or conditioning needs.

F ig. 4 shows a variant of induction apparatus with three induction channels.

According to this variant, an induction apparatus 20 according to the basic embodiment has i g. 2 is combined with an induction apparatus 20 'according to the embodiment in fi g. 3 so that a three-channel induction apparatus 20 "'is obtained. Thus, this three-channel variant has a first induction channel 21', a second induction channel 21" and a third induction channel 21 '", each of which has its associated primary air duct, a first primary air duct 30'. , a second primary air duct 30 "and a third primary air duct 30" 'with associated first openings 282 The function of each duct in this variant is equivalent to the previous embodiments and is therefore not described in more detail here. It is pointed out that for special needs it is of course also possible to combine a number of single-channel and / or two-channel and / or three-channel with each other, in order to obtain an induction device which meets high requirements for controllability by means of a number of different flows. there is an almost unlimited possibility here, in addition to regulating individual, or groups of, first openings 28 ', to control the primary air between the various primary air ducts. rna, e.g. by damper control of the input to each primary air duct or by using different fans that are individually adjustable, to create the intended effect. An example may be that the first primary air duct 30 'is used for a shallow och and the second primary air duct 30' for a forced till to a first level and the third primary air duct 30 "'for a forced till to a second level and any additional primary air ducts for In operational cases with different primary air prim fates in the respective induction duct, the partition wall 38 "'or equivalent partition walls entails separate air ducts for each duct and thus an optimal induction. Alternatively, the ground speed can be ensured by means of two or more primary air ducts, whereupon forcing fights can be achieved by means of any additional number of primary air ducts.

Fig. 5 shows a further improved embodiment 20 "" of the induction apparatus in fi g. 3a-c. Here the design of each induction channel has been further improved, in that the z-propelled first channel wall 29 has been replaced by a smooth wall, for outer Thus, a third induction channel 42 and a fourth induction channel 42 'are each formed with a smooth third wall 44 and a fourth wall 44', respectively, on each side of an associated, likewise smooth partition, which for the sake of clarity here is called partition wall 46. From the secondary air intake 48, each smooth third wall 44 or smooth fourth wall 44 'converges to a position located substantially 2/3 of the distance to the outlet 50 and extends with a substantially constant cross section over the remaining 1 / The first channel wall 29, which has a substantially z-like shape, has a web 32 running transversely to the reference line A, which partially encroaches on the cross section sarean hos resp. induction duct and in which resp. first opening 28 is occupied, has thus been replaced by each smooth third 44 resp. 44 ärde 44 'wall. Each first opening 28 in previous embodiments acc. fi g. 2-4 have then been replaced by a second primary air nozzle 52 designed as a curved tube, which instead of the web 32 inserts a piece in resp. induction duct 42, 42 'and can be configured in such a way that the primary air flow can be directed parallel to the partition 46 and the reference line A. , to enable shutdown of e.g. the third induction channel 42 while the fi fourth induction channel 42 'is still in operation or vice versa.

The construction according to the improved embodiment 20 "'' means, thanks to the fact that only the second primary air nozzles 52 project pointwise into the third and fourth induction ducts 42, 42 'through the smooth third 44 and fourth 44' walls, respectively, that the second primary air nozzles 52 affects the disturbance resistance of the respective induction duct 42, 42 'to a much lesser extent in comparison with the cross-reference line A of the life 32 of previous embodiments. Although the induction apparatus in the various embodiments has been described in conjunction with a heat exchanger, it may , which is derived from the dashed boundary line of the heat exchanger across the upstream end, the heat exchanger is disconnected and the induction device is used, for example, for mixing circulating air with fresh air in certain proportions.

Claims (10)

10 15 20 25 Patent claims An induction apparatus for interconnecting air ducts comprising at least one induction duct (21) coordinated with a primary air duct (30) having an upstream end and a downstream end and a center line (A) passing through the ends and at least one induction duct communicating with the primary air duct (30) (21) with- Current mouth opening, first opening (28) for a primary air fl desert (F1), at least one secondary air intake (22) concerns intake of a secondary air fl desert (F2) to the induction duct (21) from a room surrounding the induction apparatus and at least one outlet (24) arranged to return a space (F3) resulting from primary air fl fate and secondary air fl fate (F3) to the space surrounding the induction apparatus, characterized in that the secondary air fi unit (22) is arranged at the upstream end of the induction duct (21) and is substantially center line (A). Induction apparatus according to claim 1, characterized in that each first opening (28) is arranged in such a way that both the primary air fl fate (F 1) itself and the secondary air im fate (P2) generated by it and the resulting air fl fate (P3) are aligned substantially parallel to the center line (A) of the induction channel. Induction apparatus according to claim 1 or 2, characterized in that a longitudinal partition wall (38) is arranged in the induction channel in such a way that a first induction channel (21 ') is formed on one side of the partition wall and a second induction duct (21 ") on the other side of the partition. Induction apparatus according to claim 3, characterized in that! in that each induction duct (21 ', in 21 ") has its own primary air duct (30', 30") with associated first openings (28 ') for the primary air. 10 15 20 25 10 Induction apparatus according to claim 4, characterized in that the first primary air duct (30 ') and the second primary air duct (30 ") have different large first openings (28'). Induction apparatus according to Claim 4, characterized in that the partition wall (38) is movable. Induction device according to one of the preceding claims, characterized in that at least one induction channel (21 ') is shut-off while at least one induction channel (21') is in continued operation and / or that at least one induction channel (21 ') is usable in operation. while at least one induction duct (21 ") is in operation and / or that the resulting fl fate (P3) of each induction duct (21 ', 21") is individually variable, depending on the primary air flow through the associated primary air duct (30', 30 "). Induction apparatus according to one of the preceding claims, characterized in that the secondary outlet (22) has an area which is at least twice as large as the area of the outlet (24). Induction apparatus according to one of the preceding claims, characterized in that a heat exchanger (26) is connected in series with the secondary air intake. Induction apparatus according to one of the preceding claims, characterized in that the outlet (24) is arranged at the downstream end of the induction channel and is substantially axially aligned with its center line (A).