DE10053026A1 - Air-conditioning arrangement, formed as ceiling induction instrument with heating- and/or cooling arrangement, and with arrangement for blowing treated room air and primary air - Google Patents

Abstract

The arrangement is formed as a ceiling induction instrument (6) with a heating- and/or cooling arrangement (13), and with an arrangement for blowing air consisting of treated room air and primary air in vertical direction downwards and/or in horizontal direction. The primary air is preferably led over a secondary air drive device (15,16) which is formed as at least one ventilator, especially a cross-current ventilator or at least one primary air nozzle (17,18).

Description

The invention relates to a ventilation technology A Direction for heating and / or cooling, in particular for air conditioning, from large ceiling heights the rooms, halls, event rooms etc.

Large halls that are used for events such as exhibitions, trade fairs, congresses, sporting events, etc. are often only air-conditioned from above. This is preferably understood to mean heating or cooling. In addition to the supply of outside air, it is necessary in a fully occupied hall to dissipate up to 200 watts / m ^{2 of} heat load. Conversely, it may be necessary to heat such halls in the cold season, especially if they are not fully occupied or at the beginning of an event.

It is known as so-called air-only climate systems use where primary air is centrally processed tet, for example heated or cooled, and then for example, in the ceiling area of the hall orderly swirl air outlets is supplied. The Swirl air outlets are designed in this way adjustable so that when the heating is on the warm Blow out air vertically downwards and when cooling the cold supply air flow is essentially horizontal twist.  

Furthermore, so-called chilled ceilings are known which can achieve a cooling capacity of up to 150 watts / m ² , but are uneconomical.

In rooms with a normal ceiling height, e.g. Bü space, so-called In are used for air conditioning Production devices preferably below the window benches set up.

The invention has for its object a ventilation system for air conditioning of rooms with high ceilings (e.g. more than 5 m) to create effective, one simple and inexpensive way to heat both as well as a cooling operation without creating a unpleasant indoor climate (for example due to Zug Apparitions and the like) allowed.

According to the invention, this object is achieved by that the ventilation system as ceilings induction device is designed with a heating and / or cooling device and with a device to the essentially vertically downwards and / or blowing out approximately in the horizontal direction self-treated indoor air (secondary air) and primary air supply air. Erfin According to the invention is therefore used to create a secondary Luftkreises applied the induction principle that means mixed in a conditioned supply air flow itself - according to the induction principle - room air, whereby the supply air flow when heating is essentially lower is brought right down into the room because with the warm air jets reaching the floor. In this respect, a sufficient exit impulse is required.  In the case of cooling, the conditioned Zu air flow blown out essentially horizontally, whereby he - according to the induction principle - mixed with polluted, warm room air. Because of of the horizontal blow-out angle here phenomena in the lounge areas of the room avoided. In the course of this registration is under one "horizontal blowout" is not just pure hori to understand zontal direction, but it is also Directions meant that diagonally from above point below. This applies accordingly to a "vertical blow". This is not only blowing out the vertically downwards To understand supply air flow, but it will also captured directions that depend on the vertical soft, so run obliquely to the vertical. At the system according to the invention is thus preferably se outside air as primary air supplied by Induction effect of secondary air from the climat sucking space. The secondary air is over led at least one heat exchanger and ther mixed treated. Avoid primary air and secondary air and are fed into the room as supply air blow.

The supply air is made up of primary air and secondary go together. The primary air is over a second därluft drive means out. Here it can a fan or a primary air nozzle or act several primary air nozzles. Downstream of the fan or the Primary air nozzle is created - by induction effect - a negative pressure so that secondary air (loaded Room air) flows in laterally, this secondary air  previously a heating and / or cooling device, preferably passes through a heat exchanger and - depending after operation - is conditioned accordingly. Treated primary air and by means of the heat exchanger Secondary air mix and form a mixture air that is the supply air to the room - from the ceiling - fed in the horizontal or vertical direction becomes.

According to a development of the invention Ceiling induction device at least one vertical and a horizontal air outlet, whereby - each depending on the operating case - either the vertical Air outlet or the horizontal air outlet in Be drive is taken. When heating, the vertical Air outlet operated; in the case of cooling the horizontal Air outlet. The arrangement is made that - inside the ceiling induction device - the two above-mentioned air outlets are technically connected and ever because at least one secondary air drive means exhibit. Furthermore, the ceiling induction device at least one secondary air inlet that over fluidically at least one heat exchanger is connected to the secondary air drive means. They are already used as secondary air drive means fans mentioned above, in particular Cross-flow fans and / or primary air nozzles set. The peculiarity is that both the Ver tical air outlet as well as the horizontal air outlet let such a secondary air Drive means is assigned. As a consequence, that - depending on the desired supply air outlet direction - the assigned secondary air  Drive means operated with the appropriate power ben while the other secondary accordingly air drive means only with such a small Performance drives that the inflow of indoor air is avoided by the assigned air outlet. In other words: If, for example, the Verti Kal air outlet operated and this is as a second därluft driving means a primary air nozzle row assigned space air sucked in, but not through the horizon valley air outlet, but through the Secondary air inlet so that the secondary air Flows through heat exchanger. Hence the secondary Air drive means of the horizontal air outlet operated just so strongly that a supply air flow with low blowing speed is generated, the suction via the horizontal air outlet ver prevents. At the same time, a little warm air electricity blown out from under the roof of the hall uncontrolled cold air waste from the roof works.

It is also advantageous to have at least two seconds to provide därluft driving means, one of which for heating and the other for cooling serves and which ge at least one heat exchanger is assigned together. Through the common ver Use of the heat exchanger is an inexpensive one Design realized.

The air flow is preferably carried out in such a way that with a transition from heating to cooling fall - and vice versa - a secondary air flow reversal takes place through the heat exchanger.  

To be during a transition from heating to cooling the supply air from cooling to heating flow into the room with the appropriate direction let, the air outlet is preferably a movable ches air guide assigned. Depending on the position of the air control element, the supply air becomes horizontal or blown out in the vertical direction. Also are correspondingly intermediate exhaust angles - depending on the position of the air control element - possible. The air guiding element works similarly to one Thrust reverser blade, as is the case with jet engines is known to ent the angle of the supply air jet adjust speaking. This is in the heating case the vertical direction and in the cold case the horizon aimed towards the valley.

In particular for cooling, it is provided that the air outlet is a single jet fan has direction. As a result, the cold supply air in different directions divides and enters the room as single beams therefore - due to the individual rays - a higher In effect occurs, so a very effective Mixing with the room air takes place. Such a thing Can proceed - after another execution game - also or only be provided in the case of heating.

The air outlet that enters the supply air into the room brings, preferably out as a slot outlet forms from which - seen over its length - the Supply air exits with changing flow angles. This creates air jets that - across for the longitudinal extension of the air outlet - alternately  at an appropriate angle (approximately vertical to about horizontal).

Finally, you can switch to the generation the flow angle air guide elements provided be essentially transverse in their position cause a horizontal deflection to the air flow and in their position essentially in air currents a vertical flow of the supply air to let. The air guiding elements are preferably in their position changeable, especially ver can be swiveled so that - depending on the operating case (heating and / or cooling) - an exit angle variation of the Supply air flow can be carried out.

Further advantages of the invention are in the Unteran sayings marked.

The invention is explained in more detail in the figures. Show it:

Fig. 1 is a schematic view of a ceiling-inductive device,

Fig. 2 is a system concept induction units with several blankets,

Figures ceiling induction devices in a schematic 3 to 7 view after further execution play,

FIG. 8a to 8c for implementing various views of a Deckenin duktionsgeräts according to a further stop,

Figure 9 is a further example of a duktionsgeräts Deckenin.,

Figure 10 is a schematic view onsgerät. Matisierenden to a cli hall with Deckenindukti,

FIGS. 11 and 12 different modes of operation of the ceiling induction apparatus according to Fig. 10,

Fig. 13 is a detailed view of the Deckenin duktionsgeräts of Fig. 10,

Fig. 14a and 14b show different views for a wei more advanced embodiment of a ceiling-inductive device,

Figs. 15 to 17 different modes of operation of the ceiling induction apparatus according to the Fig. 14a and 14b,

Figure 18 shows another embodiment of view. A ceiling induction device in Seitenan,

Fig. 19 is a front view of the ceiling induction apparatus of FIG. 18,

FIGS. 20 and 21 show different positions of an air outlet of the chilled device of FIGS. 18 and

Fig. 22 is an adjusting device of the air from passage of FIG. 18.

Fig. 1 shows a has room to be conditioned 1, a ceiling 2 and a floor 3 in the distorted scale. In the ceiling area 4 of room 1 there is a ventilation device 5 , which forms out as a ceiling induction device 6 .

The ceiling induction device 6 has a housing 7 , which has a secondary air inlet 8 , which faces the ceiling 2 , but with a was from a to it. The housing 7 is provided with a vertical air outlet 9 and with a horizontal air outlet 10 . The outlet opening of the vertical air outlet 9 points in the direction of the floor 3 . The outlet opening of the horizontal air outlet 10 points in the direction of a side wall 11 of the room 1st Accordingly, the vertical air outlet 9 and the horizontal air outlet 10 are offset from one another by an angle of 90 °. Downstream of the secondary air inlet 8 is - within the housing 7 - a Klimatisierungsvor device 12 , which is designed as a heating and / or cooling device 13 and is preferably realized by a heat exchanger 14 . The heat exchanger 14 works according to the 2- or 4-pipe principle, that is, it is connected to a water circuit (2-pipe principle) or to two water circuits (4-pipe principle). In the 2-pipe principle, cooled or heated water can be conducted in the water circuit, with the result that the ge-fed heat exchanger 14 cools or heats, so that air passing through it is appropriately tempered. If it is a 4-pipe principle, it is possible to conduct cooled water by means of two lines (outward and return line) and heated water by means of two further lines (outward and return line), so that - depending on the position - appropriate Shut-off valves - either heating and / or cooling the heat exchanger it follows, whereby in the course of a system concept with several ceiling induction devices 6 certain induction devices can be heated and others cooled, if this is necessary due to different temperature loads in the room. This flexibility is also advantageous if the hall is divided into several individual rooms, for example, and the individual rooms are to be climate controlled differently. For the sake of simplicity, the water circuits in Fig. 1 are not Darge. Downstream of the heat exchanger 8 are two secondary air drive means 15 , 16 which are designed as primary air nozzles 17 , 18 or primary air nozzle rows. According to another embodiment, not shown, it is also possible that the secondary air drive means are designed as fans, in particular as cross-flow fans. From this training option of the secondary air drive medium, namely as a fan or as a primary air nozzle, is alternatively or in a mixed form in all embodiments of the present application. By means of an air line connection 19 not shown , the primary air nozzle 17 is connected to a primary air line 20 , with which - from a central processing point - processed, preferably heated, primary air is supplied. A corresponding air line connection 21 couples the primary air nozzle 18 to a further primary air line 22 , which - from the central processing point - delivers primary air, preferably in a cooled state.

At the primary air nozzle 17 connects a mixing chamber 23 , which - viewed in the direction of flow - leads to the Ver tikal air outlet 9 . A mixing chamber 24 connects to the primary air nozzle 18 and leads to the horizontal air outlet 10 . The heat exchanger 14 is associated with both secondary air drive means 15 , 16 in terms of flow technology and only - seen in the flow direction - from the secondary air drive means 15 , 16 is an air flow separation carried out such that the corresponding air outlet, namely vertical air outlet 9 or horizontal Air outlet 10 is supplied.

This results in the following mode of operation: First, the heating situation of room 1 should be considered. For this purpose, 20 primary air is supplied to the primary air nozzle 17 or the primary air nozzle row 17 by means of the primary air line, which expels a primary air flow into the mixing chamber 23 at high speed and with an appropriate induction effect. Due to the induction effect, room air located in the ceiling area 4 is sucked in by the secondary air inlet 8 (dashed arrows) and flows through the heat exchanger 14 as secondary air. The Wärmetau shear 14 is heated by means of a water circuit, so that the secondary air is heated up and flows to the mixing chamber 23 , where it mixes with the primary air and emerges from the vertical air outlet 9 vertically downwards in the direction of the floor 3 with high momentum, in such a way that the heated air reaches the floor 3 and, in this respect, heats the stay zone there. In order to prevent ver that room air is sucked through the horizontal air outlet 10 bypassing the heat exchanger 14 , the primary air nozzle 18 or a corresponding row of primary air nozzles 18 is so strongly provided by means of the primary air line 22 that a supply air flow with a low blow-out speed is ensured is generated, which prevents suction via the horizontal air outlet 24 . At the same time, a small flow of warm air is blown out from under the hall roof, which counteracts an uncontrolled drop in cold air from the roof. A shut-off of the horizontal air outlet 10 is not necessary if the primary air line 20 is operated with warm primary air, which is sufficient for heating al line. In this case, the greatest possible amount of secondary air is sucked in from the room (cold air) in order to reduce the excess temperature of the supply air flow at the vertical air outlet 9 in order to ensure a sufficient jet penetration depth.

In the case of cooling, the primary line 22 supplies the primary air nozzle 18 or a row of primary air nozzles 18 , which blows into the mixing chamber 24, with primary air which is preferably cooled. The negative pressure generated there leads to room air being sucked in through the secondary air inlet 8 and passing the heat exchanger 14 . The heat exchanger 14 is fed with a cold water circuit, so that a corresponding conditioning of the room air (secondary air) takes place and this conditioned secondary air meets the primary air in the mixing room 24 and flows out as a cooled supply air flow from the horizontal air outlet 10 in an approximately horizontal direction. As a result, the cooled supply air is not blown directly into the lounge area of room 1 to avoid drafts and an uncomfortable room climate. The cooled air reaches the floor area, is heated there by existing heat loads, rises to the ceiling area of room 1 and can then be conditioned again by the ceiling induction device 6 . Also in the cooling case - to avoid bypassing the heat exchanger 14 - it is provided that by means of the primary air line 20 the primary air nozzle 17 or the corresponding nozzle assembly is fed so strongly that a small amount of air escapes from the vertical air outlet.

Fig. 2 shows - in a schematic representation a system with several ceiling induction devices 6 , with only three ceiling induction devices 6 are provided and further are only hinted at. The ceiling induction devices 6 are arranged in the area of the ceiling of the room 1 with a corresponding distribution. The ceiling induction devices 6 are supplied by means of the primary air lines 20 and 22 , the primary pressure being able to be set in each case via pressure regulating paths 25 , 26 . At the primary lines 20 and 22 , the individual ceiling induction devices 6 are connected linearly, that is, they are fluidically connected in parallel. An air flow adjustment is carried out in each case by pulling the primary air duct 20 or 22, that is, it reduces its nominal diameter or else corresponding nominal diameters are provided in the branching lines, in order to thereby lose the pressure and thus achieve the ventilation. It is therefore only necessary to carry out the air-side control by means of two centrally arranged control flaps 27 , 28 and to control / regulate the speed 29 for a supply air fan 30 of a central primary air treatment point 31 . The supply air fan 30 has in its downstream area a heat exchanger 32 for heating and a heat exchanger 33 for cooling, so that differently tempered primary air streams can be generated in the two primary air lines 20 and 22 .

Fig. 3 shows a ceiling induction unit 6 according to a further embodiment. The housing 7 is - seen in cross section - T-shaped, so that two diametrically opposed Ho rizontal air outlets 10 and 10 'who the. The vertical air outlet 9 corresponds to that of the embodiment according to FIG. 1. Both horizontal air outlets 10 , 10 'are each assigned a primary air nozzle or at least one primary air nozzle row 18 or 18'. For the sake of simplicity, the contours of room 1 and the primary air lines are not shown. The water cycles are also not outlined for the sake of simplicity.

The embodiment of Fig. 3 works as follows: In the heating case, the heat exchanger 14 is fed with warm water, so that the secondary air sucked in (dashed arrows) is heated during the passage of the heat exchanger 14 and reaches the mixing chamber 23 , in which to generate the Induction effect is also blown by means of the primary air nozzle 17 primary air. The air conditioned in this way emerges vertically downward through the vertical air outlet 9 into the room. The two primary air nozzles 18 and 18 'are only so strongly charged with primary air that a small amount of air emerges from the horizontal air outlets 10 , 10 '. In the cooling case, the two primary air nozzles 18 are acted upon by primary air, so that room air is sucked in by induction, passes through the heat exchanger 14 and in each case reaches the mixing chamber 24 or 24 'and then there in diametrically opposite directions from the horizontal air outlets 10 and 10 'blown out who. The primary air nozzle 17 is operated with low power to bring about a small air outlet from the vertical air outlet.

FIG. 4 shows an embodiment of a ceiling induction device 6 , which essentially corresponds to the embodiment of FIG. 3. The only difference is that the primary air nozzle 17 for generating a vertical supply air flow is not inside the housing 7 , but outside the housing 7 . The primary air nozzle 17 is preferably located centrally below the Ge housing 7th The primary air nozzle 17 can also be designed as a vertically blowing linear air outlet. Since the primary air nozzle 17 to be activated for the heating case is not located within the housing 7, there can also be no interaction with the heat exchanger 14 . This means that for the heating case heated primary air must be supplied to the primary air nozzle 17 in order to be able to lead a warm air flow to the floor 3 of the room 1 in this way. Due to the induction effect, room air vortices enter the warm air flow, so that a mixture with the air of room 1 takes place in this way. This leads to a correspondingly uniform temperature control of the room 1 . In the cooling case, the primary air nozzle 17 is taken out of operation. Only the primary air nozzles 18 and 18 'are in operation, which are operated with unheated or even cooled primary air. Accordingly, primary air flows into the mixing rooms 24 and 24 'and induce room air (dashed arrows) which passes through the heat exchanger 14 as secondary air and is cooled in the process. In the mixing rooms 24 and 24 ', mixed air is generated which is expelled in the two opposite horizontal directions from the horizontal air outlets 10 , 10 '. From Fig. 4 it can be seen that the heat exchanger 14 is in the upper region of the housing 7 of the ceiling induction device 6 , that is, the secondary air inlet 8 faces the ceiling.

In the embodiment of FIG. 5, a ceiling induction device 6 is provided, the secondary air inlet 8 of which points downwards, that is to say it is directed onto the floor 3 of the room 1 . There is also the heat exchanger 14 . Within the housing 7 of the chilled device of FIG. 5 is vorgese hen whose primary air nozzles obligations 18 and 18 'in horizonta ler, mutually diametrically opposite Rich have a primary air nozzle assembly 34. The primary air nozzle arrangement 34 is located above the heat exchanger 14 and, viewed downstream, leads to the mixing spaces 24 and 24 ', which are followed by the horizontal air outlets 10 and 10 '. Below the heat exchanger 14 and outside of the housing 7 there is a primary air nozzle 17 or a primary air nozzle row 17 or a linear air outlet. The Li nienluftauslass can, for example, Luftleitelemen te, air adjusting rollers or the like, not only to blow vertically downwards, but also deviating from the vertical direction, i.e. obliquely downwards, as shown by the two arrows 35 .

. For the embodiment of Figure 5, the following function is obtained: When heating the primary air is taken into operation 17 nozzle, this may be heated, or else be used non-heated primary air. The heat exchanger 14 is heated by means of water. The primary air emerging from the primary air nozzle 17 leads to an induction effect with the result that room air is sucked in through the horizontal air outlets 10 and 10 '(dashed arrows) and passes through the heat exchanger 14 which heats up. Additionally or alternatively, it can also be provided that the heat exchanger 14 is taken out of operation and heated primary air is blown vertically downwards or obliquely downwards by means of the primary air nozzle 17 . In cooling mode, the primary air nozzle 17 is put out of operation and the primary air nozzles 18 and 18 'are activated by means of untempered or cooled primary air. The result is that room air enters the secondary air inlet 8 from below while passing through the heat exchanger 14 (dashed arrows 36 ) and reaches the mixing rooms 24 and 24 ', where it meets the primary air and as supply air through the two horizontal air outlets 10 , 10 'are blown out in an approximately horizontal direction or obliquely thereto.

In the embodiment of FIG. 6, there is an embodiment which corresponds to that of the exemplary embodiment 5 essentially. The only difference is that within the secondary air inlet 8, two heat exchangers 14 , 14 'are arranged, the primary air nozzle 17 being arranged a little downward between the two heat exchangers 14 , 14 '. In the heating case, operation takes place in accordance with the exemplary embodiment in FIG. 5, either the two heat exchangers 14 , 14 'being put into operation (hot water) and / or the primary air nozzle 17 being supplied with warm primary air, and the two heat exchangers 14 and 14 ' are switched off. In the cooling case, the two heat exchangers 14 , 14 'operated with cold water are flowed through by secondary air (dashed arrows 36 ), the primary air nozzles 18 and 18 ' being supplied with untempered or cooled-temperature primary air. It is also possible a mixing operation in which, for example, by means of the Hori zontal air outlet 10 cold air and 10 'warm air is discharged horizontally by the horizontal air outlet, but with the horizontal ejection or approximately horizontal discharge of warm air has the disadvantage that these are not the Floor area of the hall reached. For hot air operation, it is then of course necessary that in a 4-pipe heat exchanger the heat exchanger 14 'is fed with hot water and the heat exchanger 14 with cold water.

In the embodiment of FIG. 7, the primary air nozzles 18 , 18 'have been divided, that is to say the housing 7 is divided into two partial housings 7 and 7 ', the primary air nozzle 17 being arranged between the two partial housings. The primary air nozzle 18 works with the heat exchanger 14 and the primary air nozzle 18 'with the heat exchanger 14 '. Otherwise, the structural design and the function correspond to the exemplary embodiment in FIG. 6, so that reference is made to the associated description.

In the embodiment of FIGS. 8a to 8c it follows - in the longitudinal extent of the ceiling induction device 6 - a vertical blowing of preheated primary air by means of swirl outlets 37th As is apparent from the Fig. 8c, the diffusers 37 Zvi's heat exchange regions 14 are arranged. A section of a heat exchanger 14 therefore always alternates with a swirl outlet 37 . In the area of the heat exchanger 14 - according to FIG. 8a - primary air nozzles 18 , 18 'are arranged. The arrangement is preferably made in such a way that the swirl cone of the swirl outlets 37 can be individually variably adjusted in order to achieve a good compromise between sufficient vertical depth of penetration and the lowest possible indoor air movement in the occupied zone. In the heating case, the swirl outlets 37 are fed with warm primary air and the heat exchanger 14 are switched off. In the cooling case, the two primary air nozzles 18 , 18 'are supplied with untempered or cooled primary air, so that room air can pass through the heat exchanger 14 which is in cooling operation according to the dashed arrows 38 and can exit the horizontal air outlets 10 and 10 ' into the room.

Fig. 9 shows an embodiment of a ceiling induction device 6 , in which two heat exchangers 14 , 14 'arranged at a distance from one another are arranged in an inclined position to the vertical. The two heat exchangers are located in partial housings 7 , 7 ', a primary air nozzle 18 being arranged in the housing 7 and a primary air nozzle 18 ' being arranged in the interior of the housing 7 '. These two primary air nozzles 18 , 18 'are connected to the primary air line 22 . The inclination of the two heat exchangers 14 and 14 'is such that the upper regions of the heat exchangers are closer together than the lower regions. The inclination should be selected so that any condensate that may occur can run off to a condensate pan. Between the two heat exchangers is - in the lower position - an air outlet grille 39 , in which - over the longitudinal extension of the ceiling induction device - vorzugwei se with spaced swirl outlets 37 are arranged. The air outlet grille 39 also serves as a catwalk for maintenance work. The swirl outlets 37 arranged at a distance from one another are connected to the primary air line 20 . In the case of heating, either the swirl outlets 37 are fed by means of the primary air line 20 ; which supplies heated primary air. In addition, it can be provided that the two heat exchangers 14 and 14 'are supplied with warm water and that the two primary air nozzles 18 , 18 ' are active. In the cooling case, the two primary air nozzles 18 and 18 'are supplied via the primary air line 22 with conditioned or unconditioned primary air and the two heat exchangers 14 and 14 ' are supplied with cooling water. On the one hand, room air passes from the bottom up through the air outlet grille 39 and, on the other hand, also comes from above, passes through the heat exchangers 14 and 14 'and reaches the mixing chambers 24 and 24 ', mixes with the primary air flow there and emerges as supply air from the horizontal -Air outlets 10 and 10 'into the room.

Fig. 10 shows a ceiling induction device 6 in a room 1 , which has two angularly angeord designated housing 7 and 7 '. In the illustrated embodiment, only a primary air line 20 is provided, which is located between the two housings 7 , 7 '. Each housing 7 , 7 'has a heat exchanger 14 , 14 ', a mixing chamber 24 , 24 'and air outlets 10 , 10 '. From these air outlets 10 , 10 ', air flows can emerge in such a way that not only directions - as already defined above - are recorded which run horizontally or inclined downwards, but also air flow directions are recorded which point obliquely upwards, as can be seen from the angular position of the two housings 7 , 7 '. From Fig. 10 it can be seen that the outlet direction of the air outlets 10 and 10 'form an angle α with the horizontal. In the exemplary embodiment in FIG. 10, both the heating case (left side) and the cooling case (right side) are shown simultaneously for the sake of simplicity. Which occurs FIGS. 11 to 13 illustrate how in the respective operating case, the airflow guide, namely the leakage of air to the air outlets 10 and 10 '.

Since the two housings 7 and 7 'are correspondingly mirror-symmetrical, the description of both arrangements should be dispensed with. Rather, it is provided that only the housing 7 'according to FIGS. 11 to 13 is explained in more detail. The Ge housing 7 is then designed accordingly.

Referring to FIG. 11, the housing 7 'in the lower Be rich its bottom wall 40 the heat exchanger 14'. Furthermore, a primary air nozzle 17 'is arranged in the interior of the housing 7 ', which is connected to the primary air line 20 according to FIG. 10. Above the primary air nozzle 17 ', the mixing chamber 24 ' lies within the housing 7 'and extends to the air outlet 10 '. The bottom wall 40 forms the angle α with the horizontal. The air outlet 10 ′ has an opening 41 , the opening area of which lies in a plane that is perpendicular to the bottom wall 40 . The opening 41 is overlaid by an angle element 42 , which forms a fixed air guiding element 43 . As can be seen from FIG. 13, the fixed air guiding element 43 fastened to the housing 7 'has a wall section 44 which lies in the plane of the ceiling wall 45 of the housing 7 '. There then follows an angled Wandab section 46 , which - as shown in FIGS. 11 and 12 - runs approximately horizontally or even points obliquely downwards with its free end. According to FIG. 13, the angled wall section is provided with a toothing 47 which leads to regions 48 and incisions 49 which project further.

In the cooling case, untempered or cooled primary air is supplied to the primary air nozzle 17 'by means of the primary air line 20 , which draws in room air by induction through the heat exchanger 14 ', the heat exchanger 14 'being supplied with cold water. From the air outlet 10 ', the supply air composed of primary air and secondary air exits at an angle α relative to the horizontal until the supply air comes against the angled air guiding element 43 and in the case of the projecting areas 48 obliquely downwards (single jet 50 ) and in the case the incisions 49 are blown out approximately in the horizontal direction (single jet 51 ). In this respect, a single jet fan-out device 52 is formed by means of the air guide element 43 . The heating situation is explained in Fig. 12. It can be seen that a pivot lever 53 is mounted on the housing 7 'about an axis 54 and carries an angle screen 55 . In cooling mode ( FIG. 11), the angle shield 55 is pivoted in such a way that its pivoting lever 53 does not protrude into the outlet area of the supply air. This is different in the case of FIG. 12. There, the swivel lever 53 is brought into a position in which the left-hand side of the swivel lever 53 part of the winch screen 55 overlaps the incisions 49 and the right-hand side of the swivel lever 53 is the area of the angle screen 55 represents an extension of the projecting regions 48 , the corresponding part of the angle shield 55 being angled more downward than the projecting regions 48 .

In this way, the hot air stream emerging from the air outlet 10 'is blown out vertically or obliquely downwards into the room 1 . The primary air nozzle 17 'is fed with non-temperature-controlled or temperature-controlled primary air and the heat exchanger 14 ' is supplied with hot water, so that room air drawn in by induction is conditioned accordingly. For the transition from heating to cooling, the angle screen 55 is moved continuously from the initial position ( FIG. 11) to the end position ( FIG. 12), so that sufficient purging of the occupied zone with supply air is ensured. If the heating power of the primary air flow is sufficient, i.e. the heat exchanger is not functioning, the addition of the colder secondary air flow can be used to reduce the excess temperature of the jet, so that the vertical penetration depth increases.

FIGS. 14a, 14b and 15 to 17 show an embodiment of a ceiling induction unit 6, that a housing 7 and an air distribution chamber 56 has. The housing 7 is connected via a pleated duct 57 to the air distribution chamber 56 in terms of ventilation. The bottom wall 40 of the housing 7 extends in the horizontal direction and has a secondary air inlet 8 , on which a heat exchanger 14 borders. Furthermore, primary air nozzles 17 are provided, which are arranged in rows, as shown in FIG. 14b. The air distribution chamber 56 has vertically downward side walls 58 and 59 and a ceiling wall 60 . At the bottom the Luftverteilkam mer 56 is open. Only inward-pointing air guide sections 61 and 62 are provided, which are formed by angled extensions of the side walls 58 and 59 . In the interior of the air distribution box 56 there is an air guiding element 63 , which is designed as an angle plate 64 and has alternating air outlet openings 67 in both its leg 65 and in its leg 66 ( FIG. 14 b). From Fig. 14a it can be seen that room air is sucked in by an induction effect from a primary air stream emerging from the primary air nozzle 17 and passes through the heat exchanger 14 through which cold water flows. The mixed air thus formed enters the air distribution chamber 56 via the Faltenka channel 57 and flows from there downward and passes through the alternate air outlet openings 67 in the legs 65 and 66 of the air guide element 63 , which is located at a vertical distance from the air guide sections 61 and 62 . The air guide sections 61 and 62 ensure - in cooperation with the lower regions of the side walls 58 and 59 - that individual jets 50 and 51 emerge from the lower region of the air distribution box 56 in alternating directions. Depending on the angular position of the air guide sections 61 and 62 and the position of the air outlet openings 67 , the individual jets 50 and 51 will flow out more vertically downwards or more in the horizontal direction and reach the room 1 .

In Figs. 15 to 17 a further exporting is approximately example of the arrangement according to FIG. Explained 14a and 14b which is opposite to the latter differs only in that the legs 65 and 66 of the air guide 63 are pivotally supported. For this purpose, an axis 68 is provided in the middle between the side walls 58 and 59 , on which the legs 65 and 66 are mounted. In the position shown in FIG. 15, the legs 65 and 66 lie with their free ends on the inside of the side walls 58 and 59 . According to the Fig. 16 and 17, the leg may be sequentially supplied pivots 65 and 66 until they reach the Stel Fig. 17 lung reach, that is, both legs are parallel to each other and run pa rallel to the side walls 58 and 59. The pivoting has the As a result, the individual jets flowing through the air outlet openings 67 between the legs 65 and 66 and the side walls 58 and 59 are influenced in their exit direction in such a way that they are released by releasing flow gaps between the free ends of the legs 65 and 66 and the inner sides of the Side walls 58 and 59 are blown increasingly steeply into room 1 . In this respect, the position shown in FIG. 15 of the legs 65 and 66 is used for cooling and the position shown in FIG. 17 of the legs 65 and 66 for heating. The heat exchanger 14 is then operated in a corresponding manner.

Fig. 18 shows a further embodiment of a ceiling induction machine 6, which is disposed in a space 1 with relatively high ceilings (for example in egg ner hall). As can be seen, the ceiling induction device 6 is suspended by means of a holding device 70 just below the ceiling 2 of the room 1 . The supply of the ceiling induction device 6 takes place by means of a primary air line 20 , that is, there is only one primary air line 20 and there are not - as in the exemplary embodiment of FIG. 1 - two primary air lines.

Fig. 18 shows that the Deckeninduk tion device 6 in its housing 7 has a Wärmetau shear 14 which is assigned as Sekundärluftantriebsmit tel 15 a set of primary air nozzles 17. The arrangement is such that the heat exchanger 14 is arranged in a vertical position on a vertical side 71 of the housing 7 . In this respect, the position of the heat exchanger 14 of FIG. 18 differs from the position of FIG. 1. In FIG. 1, the heat exchanger is arranged horizontally; in FIG. 18 in a vertical position. Therefore, the secondary air inlet 8 of the embodiment of FIG. 18 has a vertical orientation. In the output region of the Wärmetau shear 14 are in the upper region of the housing 7, the aforementioned primary air nozzles 17 which blow out primary air supplied vertically downward from the primary air line 20 within the housing 7 (arrow 72 ). By means of a depth of the heat exchanger 14 bridging air guide plate 73 , the blown-out primary air comes together with induction through the heat exchanger 14 through room air (arrow 74 ) while passing through a mixing chamber 23 to a flange 75 provided with outlet port 76 , which is on the horizontal Underside 77 of the housing 7 is formed. On the flange 75 , a pipe socket 78 is fastened with flanges 79 on the input and output sides. On the lower flange 79 , a flange 80 of an air outlet 81 is attached, which preferably 52 forms a single jet fan device. The air outlet 81 has, according to FIGS. 18 and 19, pivotable side walls 82 and 83 , each of which is cut by a plurality of side wall longitudinal sections 84 , 85 . The side wall portions 84 along the side wall 82 and the side wall longitudinal sections 85 include the sidewall 83 at. The arrangement being such that - as shown in FIG. 19 - are arranged 85 with gaps between the side wall of the longitudinal portions 84, such that the gaps in the side wall of the longitudinal portions 84 of wall longitudinal portions of the sides 85 facing each other and accordingly opposite to the side wall of the longitudinal portions 84 of the interstices of the side wall longitudinal portions 85.

The side wall longitudinal sections 84 and 85 are - seen in their cross section - air deflecting trained, that is, they have a curved or more angular shape. In the embodiment of FIG. 18, each side wall longitudinal section 84 , 85 consists of a first, flat area 86 , to which a second flat area 88 is connected at an obtuse angle 87 and to which a third flat area 90 is connected at an obtuse angle 89 . The arrangement can be such that the first flat area 86 forms an angle of approximately 90 ° with the third flat area 90 . The upper edge 91 of the first flat region 86 is pivotally movable with a horizontal pivot axis 92 . In the region of the pivot axis 92 , each side wall longitudinal section 84 , 85 has an air guide part 93 , which forms an acute angle 94 with the adjoining the first flat region 86 and protrudes so far into the interior of the air outlet 81 that a sufficiently wide passage for those from the pipe trim 78 incoming air remains.

From Fig. 18 it can be seen that the sides of the longitudinal wall sections 84 and 85 have such a pivoting position that they overlap in the lower region - as seen in the end view of FIG. 18 -, which results in a reciprocal, almost ho horizontal or slightly downward inclined air blowout (arrow 95 ). Thus, the air from the mixing chamber 23 passes through the pipe socket 78 to the air outlet 81 and is guided there by the respective air guiding part 93 in the direction of the respective opposite side wall longitudinal section 84 or 85. There is an air deflection in the opposite direction, so that an S-shaped air flow occurs. Finally, the air emerges from the air outlet 81 under the guidance of the second and the third flat regions 88 , 90 substantially horizontally with slightly upward-pointing and also slightly downward-pointing rays, in particular individual rays. This applies to both sides of the air outlet, but only the air flow arrows for one side are entered in FIG. 18 for the sake of simplicity.

Comparing the positions of the longitudinal side wall sections 84 , 85 of FIG. 18 with the positions in FIG. 20, which only shows the pipe socket 78 and the air outlet 81 (and no longer the induction device 6 ), it can be seen that both side walls 82 and 83 have been pivoted away from each other so that they no longer overlap in the side view. Its lower edge edges 96 and 97 are spaced apart. With a pivoting of the side wall longitudinal sections 84 , 85 is a pivoting of the associated air guide parts 93 , because these parts are fixed to each other. In this respect, the passage for the air coming from the pipe socket 78 is increased.

Due to the opening of the side walls 82 and 83 , the air is no longer diverted as much from the air guiding parts 93 designed as sheet metal plate parts, and also the individual regions 86 , 88 and 90 no longer act as strong leaders on the stub 87 in the pipe vertically downward inflowing air, so that the air exits the air outlet 81 less horizontally than in the exemplary embodiment of FIG. 18. While in the exemplary embodiment of FIG. 18 the pure cooling case is illustrated, in the exemplary embodiment of FIG. 20 there is an operating mode between heating and cooling. In contrast, FIG. 21 shows a position of the two side walls 82 , 83 which relates to the pure heating case. The side wall longitudinal sections 84 , 85 are spread further apart, so that the air flowing vertically downward in the housing 6 and also in the tube 78 remains essentially unaffected and consequently exits into space 1 approximately vertically downward. Depending on the operating mode "heating" or "cooling", the heat exchanger 14 is operated with warm or cold water.

Fig. 22 shows an adjusting device 98, the means of a servomotor 99 (Fig. 19) can be actuated. The adjusting device 98 serves to deflect the side wall longitudinal sections 84 , 85 symmetrically to the center line 100 ( FIG. 22). For this purpose, a lever 101 and 102 is arranged on both pivot axes 92 of the side wall longitudinal sections 84 , 85 , the two levers 101 and 102 being coupled by means of a connecting lever 103 . The connection to the two levers 101 and 102 is made by means of axes of rotation 104 . As can be seen from FIG. 22, the lever 101 points obliquely downwards and the lever 102 obliquely upwards (viewed from its axis of rotation 92 in each case). Relocated the actuator 99 together with the Seitenwandlängsab 84 cut the lever 101 , this pivots and thus moves the connecting lever 103 which in turn pivots the lever 102 . This takes the side wall longitudinal sections 85 in a corresponding manner, so that it is always ensured that when the side wall longitudinal sections 84 are pivoted away from the center line 101 , the side wall longitudinal sections 85 also swing away from this center line 100 . The same applies to the swiveling towards the center line 100 .

Claims (22)

1. Air conditioning device for heating and / or cooling of larger ceiling heights have the rooms, characterized by the training as a ceiling induction device ( 6 ) with a heating and / or cooling device ( 13 ) and with a device for essentially vertically downwards and / or For example, in the horizontal direction, the supply air is composed of treated room air and primary air. 2. Device according to claim 1, characterized in that the primary air is guided via a secondary air drive means ( 15 , 16 ) which is designed as at least one fan, in particular cross-flow fan or at least one primary air nozzle ( 17 , 17 ', 18 ) is. 3. Device according to one of the preceding claims, characterized in that the room air is promoted as secondary air by the flow of the primary air according to the induction principle and at least one heat exchanger ( 14 , 14 ') for heating and / or cooling. 4. Device according to one of the preceding claims, characterized by at least one Ver tikal- ( 9 , 9 ') and at least one horizontal air outlet ( 10 , 10 '), which are fluidically connected to one another in the interior of the ceiling unit ( 6 ) and each have at least one secondary air drive means ( 15 , 16 ) and with at least one secondary air inlet ( 8 ) which is connected in terms of flow to the secondary air drive means ( 15 , 16 ) via at least one heat exchanger ( 14 , 14 '). 5. Device according to one of the preceding claims, characterized by at least two secondary air drive means, one of which is used for heating and the other for cooling and to which at least one heat exchanger ( 14 , 14 ') is assigned together. 6. Device according to one of the preceding claims, characterized in that during a transition from heating to cooling and vice versa, a secondary air flow reversal through the heat exchanger ( 14 , 14 '). 7. Device according to one of the preceding claims, characterized by at least one air outlet ( 10 , 10 '), which for pivoting the supply air from the horizontal direction in the vertical direction is assigned a movable air guide element (angle screen 55 , leg 65 , 66 ) is. 8. Device according to one of the preceding claims, characterized in that the air outlet ( 10 , 10 ') has a single jet fan device ( 52 ). 9. Device according to one of the preceding claims, characterized in that the air outlet (air outlet openings 67 ) is designed as a slot outlet, from which - seen over the length - the supply air emerges with preferably changing flow angles. 10. Device according to one of the preceding claims, characterized in that for the generation of the changing flow angle air guiding elements (legs 65 , 66 ) are provided which produce a horizontal deflection in their position substantially transversely to the air flow and at their position Allow vertical flow essentially in the direction of air flow. 11. Device according to one of the preceding claims, characterized by an on the end face of the ceiling induction device ( 6 ) arranged air outlet ( 81 ). 12. Device according to one of the preceding claims, characterized in that the air outlet ( 81 ) has at least one, preferably several, in particular two displaceable side walls ( 82 , 83 ). 13. Device according to one of the preceding claims, characterized in that the displaceable side walls ( 82 , 83 ) - seen in the air flow direction - have an air-deflecting shape. 14. Device according to one of the preceding claims, characterized in that at least one, preferably several, in particular two, of the side walls ( 82 , 83 ) are pivotably articulated. 15. Device according to one of the preceding claims, characterized in that the side wall / the side walls ( 82 , 83 ) is composed of several side wall longitudinal sections ( 84 , 85 ) / which are spaced apart to form gaps. 16. Device according to one of the preceding claims, characterized in that the length of the gaps corresponds approximately to the length of the side wall longitudinal sections ( 84 , 85 ). 17. Device according to one of the preceding claims, characterized in that a gap of a side wall ( 82 , 83 ) a side wall longitudinal section ( 84 , 85 ) of the other side wall ( 83 , 82 ) is opposite ge. 18. Device according to one of the preceding claims, characterized in that the opposite side walls ( 82 , 83 ) assume a spreading position to one another in the heating case. 19. Device according to one of the preceding claims, characterized in that the opposite side walls ( 82 , 83 ) in the cold case assume a closed or overlapping position to each other. 20. Device according to one of the preceding claims, characterized in that in the region of the gaps of a side wall ( 82 , 83 ) in each case one of the air flow to the gap opposite sides wall longitudinal section (84, 85) directing air guiding part ( 93 ) is arranged. 21. Device according to one of the preceding claims, characterized in that the air guiding parts ( 93 ) with the associated side wall ( 82 , 83 ) can also be moved. 22. Room ( 1 ) with a relatively large ceiling height (hall, event room, workshop or the like) with a room air technical device arranged in the ceiling area according to one or more of the preceding claims.