FI104388B - Conditioning installation - Google Patents

Description

"......, 104388

Ilmastointijarjestely

Konditioneringsanläggning 5

The invention relates to an air-conditioning arrangement comprising an air-conditioning device by means of which air is circulated to a room, whereby the supply air flow is used to provide air circulation in the room through heat exchanger devices.

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From the Applicant's prior FI Announcement 83 133, a device solution is known in which the supply air flow causes the air in the room to circulate through the heat exchanger of the auxiliary heat exchanger. In the aforementioned FI application, the flow of fresh supply air and the recirculated air flow through the auxiliary heat exchanger device 15 connected thereto are directed in a direction parallel to the surface level of the heat exchanger panel of the actual heat exchanger devices.

A device solution is known from SE 161 701, in which an air flow is directed from the duct to the side of the duct and an air flow is provided by means of the heat exchange means. The hardware solution consists of a removable • · plate with clips on the underside. The above solution does not allow the device to be placed near the surface level of the suspended ceiling.

<<· F • ·: A: This application seeks to find an improvement in the prior art * · · ί 25 ventilation units. The invention has been realized to provide an air-conditioning arrangement such that the ventilation device comprises, on the side of the fresh air inlet duct, a side chamber which

ML V: The top has a heat exchanger. Fresh air is flowing from the fresh air duct to the chamber on page • · · *. * *. A heat exchanger is used to circulate the room through a heat exchanger.

The heat exchanger is located at the top of the chamber. The apparatus further comprises a downstream flow opening from which the combined airflow is flown sideways. The air flow is controlled: "': sideways by means of a sloping guide surface. This surface is obliquely relative to the vertical axis of the side chamber. In the air conditioning arrangement of the invention, the underside of the fresh air duct t 104388 2 is level with the ceiling. In the device solution according to the invention, the device is also located on the level surface of the suspended ceiling. Therefore, the cooled air does not immediately fall down.

In the solution according to the invention, the recirculated air flows freely downwards from the heat exchanger when cooled, so that the supply air coming from the outlet of the longitudinal channel easily and efficiently induces recirculated air with the directional components of both streams being parallel.

In the device solution according to the invention, the mixing chamber is open from below. The flow exiting the mixing chamber is already directed in the mixing chamber so that the flow is discharged to the side in the lower surface Tj of the device housing.

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· '··: In the device according to the invention, the supply air flow range is wide, i.e., the device 20 according to the invention can blow small and large air flows. The supply air blowing pattern is wide; j 'and the flow rates are still low due to the large available blowing range * in the device. Supply air can be blown in one or two directions, depending on the situation.

The air conditioning arrangement according to the invention is characterized in that the lower surface plane Tj of the air channel • · duct bottom wall is in the ceiling K in the plane T2 and that the air flow T * is directed sideways obliquely to control the air flow in the air conditioner. . 'By means of a surface relative to the vertical axis.

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The invention will now be described with reference to some preferred embodiments of the invention shown in the figures of the accompanying drawings, but which are not intended to be limited thereto.

Figure 1 is an axonometric view of an air conditioner according to the invention. Figure 2 is a sectional view I-I of the device of Figure 1.

Figure 3 shows an embodiment of the device comprising only one side air chamber 10 which serves as a mixing chamber for recirculated air and fresh supply air.

Figure 4 shows an embodiment of the invention in which the flow openings in the side wall of the elongated channel are formed by stamping.

Figure 5 illustrates an embodiment of the invention in which the flow opening of an elongated channel sidewall is formed by a single elongated slot.

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Fig. 6 illustrates an embodiment of the invention in which the flow to the air chamber B is provided: from the flow openings 14aj, 14a2,14a3 ..., the flow openings comprising the nozzle tubes 20 16aj, 16a2,16a3 · .. through which the air flow is directed to the air chamber B.

'· * * Figure 1 is an axonometric view of the air conditioner 10 of the invention. Weather. , the actuator 10 comprises heat-exchangers 12 on at least one side of the elongate casing-shaped duct 11 and the duct 11, on both sides of the duct 11, as shown in the figure, air from the air chamber C of duct 11 to the heat exchanger 12 and the air chamber is C relative to the longitudinal axis X to the side such that air is discharged from duct 11 to heat- * · ·

* "·" To the air chamber B below the exchanger 12 and flows from said air chamber B

The air 4 is already directed in the air chamber B so that when it leaves the air chamber B it is directed sideways and flows in the direction of the lower surface of the conduit 11 and substantially in said plane. The heat exchanger 12 is used to either heat or cool the convection air L3 in the room. However, the most common use is cooling only.

The elongate channel 11 of the air conditioner 10 comprises flow openings 14a 1, 14a 2, 14a 3 ... in the air chamber B, from which the air flow is directed downwards. Thus, the air blown out of the duct 11 from its space C and its flow openings 14a1, 14a2, 14a3 ... provides a recirculated air flow (L3) through the heat exchanger 12. The air flowing from the flow openings 14a1, 14a2 · .., and generally from the duct 11 to the chamber B, draws in the room recirculated air L3 such that the recirculated air passes through the heat exchanger 12 which in the cooling case specifically cools the recirculated air When the air is cooled in the heat exchanger 12, the cooled air in the heat exchanger 12 flows downwardly and thus said flowing air stream has the same directional component as the fresh supply air flow blown from chamber 14a, 14a2. The airflow through the heat exchanger 12 is connected to the supply air L2 in the air chamber B on the side of the duct 11 on the side of the duct 11. The combined airflow (L2 + L3) is already directed in the air chamber B by the guide edges inside the air chamber B; 15 so that the combined air flow (L2 + L3) is directed sideways and away from the structure in the direction Tj of the bottom wall 11a of the channel 11a. Thus, the device according to the invention can advantageously be placed in the plane T2 of the suspended ceiling K. The air 20 is made to flow parallel to the surface of the suspended ceiling, whereby it is attached by the Coanda effect to the suspended ceiling K, and thus, for example, in the case of cooling, the fall of the air flow is prevented from falling. When using the ceiling K, it is ensured that the air in the room can circulate to and from the space between the ceiling K and the actual ceiling of the room.

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• · · 1 2 3 4 5 6, however, is used with the unit below the actual ceiling of the room * · 2 • m 3 ". In this case, the suspended ceiling structure will not be used.

Fig. 2 is a sectional view I-I of Fig. 1. The channel 11 comprises a bottom wall 11a, 5 · · · · · · side walls 11b → 11ll and a top wall 11c. The solution further comprises end walls lldj 6 and 11 112 · A fresh supply air stream is blown (not shown blower) from inlet E to longitudinal channel 11 to its space C from which air flows through side openings 14aa144a2 ... on side walls 11a mixing chambers B. The mixing chambers B are formed between the side walls 13 and the side wall 1 lbj, 11 lb2 of the channel 11. The heat exchanger device 12 is located at the top of each mixing chamber B. In the figure, the flow of air 5 entering the channel 11, its internal space C, is indicated by the arrow Lj. The arrow shows the downward flow of air from duct 11 to mixing chamber B. Downward airflow L2 from duct 11 induces recirculation of room air (arrow L3) via heat exchanger 12. The airflow L3 through the heat exchanger 12 is combined with the airflow L2 from the duct 11. The combined airflow leaving the unit is indicated by arrows L2 + L3. The mixing chamber B is open at the bottom and comprises a flow port F. The air flows through the oblique surface 15 below the side wall 11b as shown by the arrows L2 + L3. The sloping surface 15 is at an angle to the vertical axis Y of the mixing chamber B.

The duct 11, from its space C, has a plurality of airflow discharge openings 14aj, 14a2> 14a3 ..., 11, which open at the top of the mixing chamber B and are further located near the heat exchanger device 12. In the ceiling solution the device according to the invention The bottom wall 11a of the channel 11 is located in the surface plane T2 of the suspended ceiling K. The combined airflow LL2 + L3 flows sideways in the direction T T of the lower surface 11a of the channel 11. Here

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:.:: the combined airflow L2 + L3 flows specifically along the surface T2 of the surface K of the suspended ceiling K and attached to the surface by the Coanda effect. Combined airflow • t

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L2 + L3 further induce the circulation of room H without air circulation L4 in room H. The wall walls 13 are connected by brackets 13a to duct 11. When using the ceiling K, it is ensured that the recirculated air passes from room H to the ceiling K and the actual ceiling. 12. If there is no ceiling K, the unit is used

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• · · 25 conventionally by placing it completely under the actual roof.

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Figure 3 shows an embodiment of the invention in which the channel 11 comprises flow openings ···: V 14a ^, 14a 2 · .. only to one of the second side walls m 11bj of channel 11 of mixing chamber B.

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Figure 4 illustrates an embodiment of the invention in which the flow openings 14aj, 14a2 ... in the sidewall of channel 11 are formed by stamping, whereby the pressed-down sheet metal section 14a ^ ', 14a2' ·. · Forms a flap guide section; The control portions 14a ^ ', 14a2' ... are thus made in the same phase as the flow openings 14a ^ 144a2 · ..

Fig. 5 illustrates an embodiment of the invention wherein the side wall 11bbj of channel 11 has only one elongated flow opening 14a ^ formed by a flap guide portion 14a for controlling downward flow and for efficiently inducing airflow through heat exchanger 12.

Figure 6 illustrates an embodiment of the invention in which the flow openings 14aj, 14a2,14a3 · .. comprise nozzle tubes 16aj, 16a2,1683 ... which are arranged in the flow openings so that the flow (¾) is directed downwardly in the chamber B. 1 ^ 3 ...

15 is effectively effected by the air (L2) entering chamber B effectively absorbing the convection air flow (L3) through the heat exchanger 12. Hereby, the entire flow cross-section of the pipe '1 is available to provide suction through the heat exchangers 12.

The tubular drive 16a ^, 16a2,16a3 · .. is thus a very efficient way of drawing air through the heat exchanger 12 :. Fresh air (L2) acts as carrier air that directs the airflow

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'' 20 (L2 + L3) toward the flow port F below chamber B

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Claims (2)

An air-conditioning arrangement, which comprises an air-conditioning device (10) comprising a) single duct (11) b) on at least one side of the duct (11) a heat exchanger (12) and at least one side wall (13), air chamber (B) between the side wall (13) and the duct (11), and wherein the heat exchanger (12) is arranged in said air chamber (B), advantageously in the upper part thereof, between the side wall (13) and a side wall (1 lbj and / or Mby) of the duct (11), c) wherein the air space (B) formed between the side wall (13) and the duct (11) is open at the bottom, d) the side wall (1 lb ^ and / or 1¾) of the duct (11) comprises air flow openings (143 ^ 1432- ..). through which an air flow flows out (arrow L)) into the space between the side wall (13) and the duct (11), whereby the air flow (1 ^) flowing through the opening 20 (14a ..., 1432 ...) is arranged to draw : /: circulation air (arrow L3) from a room through the heat exchanger (12), characterized in that in the air-conditioning arrangement • · · · e .1 e) it the lower surface plane (Ti) of a bottom wall (1a) of the duct (11) of the air conditioning device (10) lies in the plane (T2) of a lower ceiling (K), and that the air flow is directed to the side by means of an oblique relative to a vertical axis (Y) of the air chamber (1) standing surface (15), which controls the air flow in the air conditioner (10); · «1! wherein said air flows (L2, L3) are directed from the air chamber (B) in such manner, that said air flows when leaving the air chamber (B) are directed substantially from the bottom (plane O2) of the lower roof (K). • f 1 · 104388 10 Air conditioning arrangement according to claim 1, characterized in that the surface (15), with which the air flow is controlled on the side, is a lower surface of the side wall (lib) of the duct (11). «II · III It • · · · • · · · a · · · mi · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · t · · · · T «· · · · · · · · · · · · f · · 1