DE1604152B1 - Induction device for air conditioning - Google Patents

Description

1 2

The invention relates to an induction channel wall lying opposite. With the aid of the device for an air conditioning system, with one outlet opening pointing upwards and two upwardly directed outlet openings which run up to an air outlet and generate two parallel primary air flows which interact with one another without at least in its upper section upwards, ensure a good, widening main air duct, a secondary air flow that passes horizontally through the heat exchanger section of the main air duct at the bottom,
len series of mutually spaced side-by-side embodiments of the invention are to be explained in more detail on the primary air outlet nozzles arranged on the other hand from drawings, where each nozzle has a number of transverse F i g. 1 shows a cross-section through an induction device which is arranged side by side in a row and is shown upwardly;
directed primary air outlet openings Fig.2 _; shows, on a reduced scale, partially and one connected to the main air duct, the front view of the arrangement of the primary air-secondary air duct through which as a result of the outlet nozzles according to FIG. 1;

the primary air outlet nozzles caused suction Fig. 3 shows a cross section through another

effect of secondary air via a heat exchanger in the form of an induction device;

the main air duct is sucked in. F i g. 4 shows a section through a third embodiment

In a known induction device of this type guide form of an induction device;
is the heat exchanger below the primary air _r F i g. 5 shows a side view of a primary air outlet opening arranged. The secondary air outlet nozzle;

is through inlet openings below the heat 20 Fig. 6 shows a plan view of that in Fig. 5

exchanger sucked in. Such a structure of an outlet nozzle shown in FIG.

duktionsgerätes requires a relatively large The in F i g. 1 illustrated induction device 11 has overall height. In another known induction housing 6 with a front wall 7, an air device, the heat exchanger is arranged above the primary air inlet grille 8, an upper wall 9 and an air outlet nozzle, the outlet openings 25 of which have outlet grids 10. In the housing 6 an antechamber is pointing in different directions. The main air duct arranged above mer 12, which extends upwards from an upper chamber of the primary air outlet openings 12 α and a lower chamber 12 b converging, is partially set by one, being limited on the opposite sides of the wall of the heat exchanger. Even with the upper chamber 12 α there are passages 13 for the sem device, there is a relatively large primary air flow. The chambers 12 α and overall height. In addition, the arrangement 12 b are separated by a throttle device 14 and the exit direction of the primary air is separated from one another. Primary nozzles are an unfavorable secondary air inflow with the chamber 12 b , so air outlet nozzles 15 are in connection,
Each outlet nozzle 15 has two outlet opening channel walls and the formation of turbulence and 16 (FIGS. 5 and 6) through which primary air congestion occurs, flow 17 into a main air channel 18 flows. Every

It is therefore the object of the invention, an Induk nozzle 15 consists of a hollow plastic housing

creation device, in which one constructively and with two opposite, flat wall sections

flow-wise favorable assignment of the Wärmetau- th 18 α, from a straight edge 18 b and a

Schers to the primary air outlet openings and to the 40 adjoining arcuate edge 18 c

Main air duct is provided. be limited. On the arched edge

In an induction device of the aforementioned sections 18 c close arcuate wall sections

Art this problem is solved in that in an 18 d an.

In a known manner, at least part of a side wall sections 18 / connect the straight

ten wall of the main air duct from a wall surface 45 edges 18 b. The outlet openings 16 are located

of the heat exchanger is taken, in the flat wall sections 18 /. Which adhere to the

Passage openings for the secondary air provided by flat wall section 18 / adjoining edges

hen and that a part of the wall surface form under opposite the arcuate wall section

half of the outlet opening of the primary air outlet 18 d an air inlet opening 18 g for passage

nozzles. - ■ ■ .- · ₅₀ ^ ₆₈ p _r iniärluftstromes from the antechamber 12 into the

Because a part of the heat exchanger is located under the inside of the outlet nozzle 15. The outlet openings half of the primary air outlet nozzles and a part above 16 are shown in FIG. 6 to see. The two from outside is arranged, is appropriate for the invention outlet openings 16 emerging air streams 17 trained induction device an extremely run parallel to each other and are perpendicular to each other low overall height. With the help of in a row 55 directed above. They flow on a wall surface 19 side by side, upwardly directed one of the main air duct 18 delimiting heat primary air outlet openings the outlet nozzle exchanger 20. An outer wall surface 20 α des on the one hand and the special arrangement of the heat exchanger 20 is opposite the air inlet heat exchanger on the other hand, there is a favorable single grille 8. The channel 18 is furthermore caused by an opposing flow of the secondary air without detaching 60 lying side walls 21 and a rear wall 22 of the air flows from the duct walls, which at the same time form a wall of the antechamber 12 or to form turbulence and congestion. The upper wall section 23 of the rear wall comes. 22 is inclined and thus forms in the upper area

A particularly advantageous embodiment of the channel 18 has a diffuser 24 that extends up to

consists in that each primary air outlet nozzle extends two 65 an air outlet 25, above which the air

has upwardly directed outlet openings, outlet grille 10 is arranged.

one of which is near the wall surface of the heat exchanger has passage openings

Heat exchanger and the other near the 27, extending from below the outlet openings 16

the outlet nozzles 15 extend to the air outlet 25. As in Fig. 6, the outlet openings 16 consist of two openings 30 and 31, directed vertically upwards and arranged next to one another along a line 32. The opening 30 is in the vicinity of the wall surface

19 of the heat exchanger, while the opening 31 is arranged in the vicinity of the opposite wall 23 is. The air flows emerging from the outlet openings 16 run parallel to one another xo and prevent turbulence caused by interaction. Since the passage openings 27 in Heat exchanger 20 also below the outlet nozzles

15, a secondary air flow is sucked in by the primary air flow below the nozzles 15, which initially runs parallel to the primary air flow 17 without initially mixing. Through this Loss of the secondary air flow sucked in below the nozzles is prevented. The diffuser 24 causes a pressure equalization between that on the inner wall surface 19 of the heat exchanger

20 prevailing negative pressure and the atmospheric pressure prevailing at the air outlet and improved thus the mixing of the secondary air flow with the primary air flow.

In the embodiment according to FIG. 3, a housing 32 α is drawn with dashed lines. In contrast to the induction device according to FIG. 1, the main air duct 37 continues above the heat exchanger 20 in a duct 33 which, with the walls 34, 38 and 39 in the upper area, forms a diffuser 35 which extends to an upper air outlet 36 . The rest of the structure of this embodiment corresponds to the induction device according to FIG. 1.

The embodiment according to FIG. 4 includes a lower heat exchanger 20, which is the heat exchanger corresponds to the previously described embodiments and an upper heat exchanger 40. The upper heat exchanger 40 has an inner wall surface 41 which connects to the inner wall surface 19 of the lower heat exchanger 20 connects in the vertical direction. The induction device according to FIG. 4 corresponds essentially according to FIG. 3, but with the wall 38 according to the embodiment F i g. 3 is formed by the wall surface 41 of the upper heat exchanger 40. The outlets

16 of the outlet nozzles 15 are at a height of one sixth of the total height of the wall of the main air duct formed by the wall surfaces 19 and 41. The inclined wall surface of the diffuser 35, which corresponds to the diffuser according to the embodiment of FIG. 3 corresponds to is inclined at an angle of about 10 °. The arrangement of two heat exchangers arranged one above the other is particularly suitable for an air conditioning system with 3 or 4 pipes, in which coolant from a cooling unit 42 circulates through the lower heat exchanger 20 and hot water from a heating device 43 circulates in the upper heat exchanger. The cooling capacity of this arrangement is compared to that in FIG. 1 embodiment shown by about 32 ¹ Vo higher when both heat exchangers 20 and 40 are charged with coolant.

Claims (5)

Patent claims: 1. Induction device for an air conditioning system, with one that extends upwards to an air outlet and main air duct widening upwards at least in its upper section, a horizontal row of with arranged in the lower section of the main air duct mutually spaced side-by-side primary air outlet nozzles, each of which Nozzle a number of juxtaposed in the direction across the row, upwards directed primary air outlet openings and one connected to the main air duct Secondary air duct through which as a result of the caused by the primary air outlet nozzles Secondary air suction is sucked into the main air duct via a heat exchanger, characterized in that at least part of a side wall is known per se of the main air duct (18) taken up by a wall surface (19) of the heat exchanger (20; 42, 43) is, are provided in the passage openings for the secondary air, and that a Part of the wall surface (19) below the outlet opening (16) of the primary air outlet nozzles (15) lies. 2. Induction device according to claim 1, characterized in that each primary air outlet nozzle (15) has two upwardly directed outlet openings (16), one of which in the vicinity of the wall surface (19) of the heat exchanger (20; 42, 43) and the other in the vicinity the opposite channel wall (23) lies. 3. Induction device according to claim 1 and 2, characterized in that the below the outlet openings (16) the part of the wall surface (19) of the heat exchanger lying near the outlet nozzles is approximately one third of the total height of the wall surface (19) is. 4. Induction device according to one of claims 1 to 3, characterized in that the a channel wall is formed by the wall surface of two heat exchangers (20, 40) arranged one above the other is, and that the height of the outlet openings (16) of the outlet nozzles (15) above the lower end of the wall surface of the lower heat exchanger (20) about a third of the height this wall area is. 5. Induction device according to claim 1 or 2, characterized in that the channel (18) over the top of the heat exchanger (20) is extended with walls (33) closed on all sides and that the channel (18) only has a constant cross section above the heat exchanger is expanded to a diffuser up to the outlet openings (10). 1 sheet of drawings COPY