DE60132218T2 - DECORATIVE PLATE FOR AIR CONDITIONING, UNIT FOR AIR OUTLET AND AIR CONDITIONING - Google Patents

Description

Technical area

The The present invention relates to air conditioning decorative panels, air conditioning ventilation units and Air conditioning. The invention particularly relates to configurations for one Air outlet of an air conditioner.

Underlying technique

at Air conditioners, for example of the type embedded in the ceiling or of the channel type are conventionally at air outlets horizontal baffles or slats attached, which are able are vertical, the direction in which conditioned air is discharged to change. While the mode of heating is the emission direction of the air-conditioned Air aligned relatively horizontally through the horizontal slats, and while the mode of cooling on the other hand, the emission direction of the conditioned air becomes relative aligned upwards so as to be as parallel as possible with a ceiling surface (operating mode the so-called "horizontal Emission ") in order to increase the efficiency of the air conditioning a uniform distribution the room temperature during to reach every operating mode.

However, in the state of such "horizontal emission", particulate matter contained in the emitted conditioned air and dust contained in the room air are likely to deposit on areas of the ceiling surface. As a result, the ceiling surface is sometimes dirty. Specifically, an airflow discharged from an air outlet (a) in a "horizontal emission" state forms a shape that is approximately similar when viewed from the air conditioner from a horizontal direction of a V-shape in the flow direction (see FIG 10 ). Here, the speed of an airflow discharged in a longitudinally central portion of the air outlet (a) is fast, so that the negative pressure becomes stronger, thereby preventing outflowing air from reaching a ceiling surface (b) near the air outlet.

On the other hand, since the speed of an airflow discharged at each end of the air outlet (a) is slow, the air is sucked by the negative pressure in the central portion. as a result, the air reaches the ceiling surface (b) near the air outlet (a). In this case, dust contained in such a slow air stream discharged at each end of the air outlet (a) is contained (in particular, dust contained in the slow airflow contained at each end of the air outlet (a) plus dust from the indoor air discharged from entrained in the slow flow of air), deposited on the ceiling surface (b). Therefore, in areas (D) in the immediate vicinity of the two sides of the air outlet (a) and in an approximately V-shape, contamination of the ceiling surface normally occurs, and such contamination is due to leakage of air from the air outlet (a) from both ends of the air outlet Air outlet (a) is directed towards the middle section (see 2 ).

To avoid such contamination of the ceiling area, was in the Japanese Patent Application Kokai Gazette No. H03-160266 proposed a method in which an auxiliary rib, which can change the emission direction so that it faces towards a ceiling surface, is detachably attached to a horizontal slat. In addition, the auxiliary rib is mounted and removed depending on the tendency to foul the ceiling. In an air conditioning system constructed in accordance with the method of this patent application, such an auxiliary rib is removed and the horizontal fin is directed downwards, for example in an environment where there is a large amount of dust due to the room air or in a place such as a room Hospital, which requires a high level of contamination prevention, is likely to contaminate the ceiling. The auxiliary rib, on the other hand, is mounted so that horizontal emission operation can be performed, for example, in an environment where the ceiling is unlikely to become soiled, or in a location that does not require a high level of contamination prevention.

Even However, if an auxiliary rib is provided, as in the above Example of the prior art, the auxiliary rib must be in an environment when it comes probably to dirty the ceiling, away become. Finally, conditioned air is continuously supplied by the Air outlet discharged down. This leads to a drop in the efficiency the air conditioning during the mode of cooling, in which basically a horizontal emission operation is performed should. There is also the additional problem that cold air falls directly onto a person in a room. This can lead to, that the person feels uncomfortable (so-called "feeling of drafts").

in view of the problems described above, the invention has been made. As a result, It is an object of the invention to carry out a horizontal operation Emission by means of a horizontal slat to allow and at the same time a pollution of the ceiling by an improvement to prevent in the configuration of an air outlet.

Further, in JP-A-07-324802 pre schla conditions to design the horizontal slat so that conditioned air in areas near the two longitudinal ends of the slat is discharged more in the downward direction than in a longitudinally central portion of the horizontal slat.

DISCLOSURE OF THE INVENTION

The Invention relates to improvements in the form of an air outlet, whereby conditioned air at both longitudinal ends the air outlet is discharged more towards the bottom than in a longitudinal direction middle section of the air outlet.

In particular, the invention provides problem solving means located on a trim panel for an air conditioner, comprising: an air outlet (US Pat. 16 ), by the conditioned air from the direction of a ceiling surface ( 70 ) is discharged into an interior, and one at the air outlet ( 16 ) mounted horizontal slat ( 18 ) for adjusting the direction in which conditioned air is discharged to a ventilation unit for an air conditioning system with an air outlet ( 16 ), by the conditioned air from the direction of a ceiling surface ( 70 ) is discharged into an interior, and one at the air outlet ( 16 ) mounted horizontal slat ( 18 ) for adjusting the direction in which conditioned air is discharged, in an air conditioner with the ornamental plate ( 14 ), which is mounted along the ceiling surface, and in an air conditioner in which the ventilation unit ( 51 ) is mounted on a ceiling surface and via a fan duct ( 52 ) with a main body ( 53 ) of the air conditioner is connected.

The air outlet ( 16 ) is designed so that conditioned air at, substantially, both longitudinal ends of the air outlet ( 16 ) (ie in areas near the two longitudinal ends of the air outlet ( 16 ) is discharged more in the downward direction than in a longitudinally central portion of the air outlet ( 16 ). In addition to the arrangement, according to which the two ends of the air outlet ( 16 ) differ in the angle in which conditioned air from the middle section of the air outlet ( 16 ), for example, the volume of at both ends of the air outlet ( 16 ) downwards emitted air, if the emission angle in the emission direction on the inside of the horizontal slat ( 18 ) is originally set more down than the emission angle in the emission direction on the outside.

In the configuration described above, the air outlet ( 16 ) in the areas near its two longitudinal ends with guide surfaces ( 16b - S), the conditioned air to lead so that it is discharged in these areas more in the downward direction than in the longitudinally central portion.

Further, in the above-described configuration, it is possible to use such an embodiment that the guide surfaces (FIG. 16b -S) of the air outlet ( 16 ) in areas near the two longitudinal ends of one or both side walls ( 16a . 16b ) and ( 16c . 16d ) of the air outlet ( 16 ) and that between the areas in the vicinity of the two longitudinal ends of the side wall ( 16a . 16b () 16c . 16d ) of the air outlet ( 16 ) and the ceiling surface ( 70 ) is greater than that between a longitudinally central portion ( 16b -C) the side wall ( 16a . 16b () 16c . 16d ) of the air outlet ( 16 ) and the ceiling surface ( 70 ) formed angles.

Further, in the configuration described above, the guide surfaces (FIG. 16b -S) of the air outlet ( 16 ) in the side wall ( 16a . 16b ) corresponding to a side facing an upper side of the horizontal slat ( 18 ), when the horizontal slat ( 18 ) is arranged in a state of horizontal emission. In addition to the arrangement according to which the angle of the side wall ( 16c . 16d ) in the areas near the two longitudinal ends of the angle of the side wall ( 16c . 16d ) is different in the longitudinally central portion, in this case, the opening width of the air outlet ( 16 ) are made larger at the two ends than the opening width of the air outlet ( 16 ) in the longitudinally central portion so that the volume of the downwardly flowing air increases. In other words, when the guide surfaces are to guide the conditioned air so that they are in the areas near the two longitudinal ends of the air outlet ( 16 ) is discharged more in the downward direction than in a longitudinally central region of the air outlet ( 16 ), from the side wall ( 16c . 16b ) corresponding to a side facing an underside of the horizontal slat ( 18 ), when the horizontal slat ( 18 ) is arranged in a state of horizontal emission, it is possible in the embodiment where the opening width of the air outlet ( 16 ) in the longitudinally central portion is made larger, to increase the volume of the air discharged at both ends downward, because in general the angle of the side wall ( 16c . 16d ) to the ceiling surface ( 70 ) is originally set relatively large.

When conditioned air through the air outlet ( 16 ) is discharged into a room, thanks to the above-described configuration, during the cooling mode, conditioned air becomes in a substantially horizontal direction in the middle Ab cut the air outlet ( 16 ), in which the emission speed is relatively high, while simultaneously conditioned air at the two longitudinal ends of the air outlet ( 16 ) at which the emission speed is relatively slow is discharged more in the downward direction than in the longitudinal middle section. Therefore, the flow rate of conditioned air at the two ends of the air outlet ( 16 ) is emitted at a low emission speed and flows along the ceiling surface, decrease. Furthermore, during the heating mode, the horizontal slat ( 18 ) is adjusted so that it is directed downwards, so that conditioned air through the entire air outlet ( 16 ) is delivered down into the room.

When the guide surfaces ( 16b -S) in the areas near the two longitudinal ends of the air outlet ( 16 ) are in particular by regulating the angle of the two ends of the side wall ( 16a . 16b () 16c . 16d ) of the air outlet ( 16 ) the emission down at the two ends of the air outlet ( 16 ) with a simple configuration.

Further, if the guide surfaces ( 16b -S) for angle regulation in the side wall ( 16a . 16b ) corresponding to a side facing an upper side of the horizontal slat ( 18 ), when the horizontal slat ( 18 ) is arranged in a state of horizontal emission, this leads to the fact that the guide surfaces ( 16b -S) at both ends of the air outlet ( 16 ) of the horizontal lamella ( 18 ) approach. As a result, the distance between the horizontal blade narrows ( 18 ) and the guide surfaces ( 16b -S), and conditioned air is definitely more delivered down at both ends than in the middle section. In addition, since the distance between the horizontal slat ( 18 ) and the guide surfaces ( 16b -S), this reduces the flow velocity at the two ends of the air outlet ( 16 ) discharged air.

If, on the other hand, the guide surfaces ( 16b -S) for angle regulation in the side wall ( 16c . 16d ) corresponding to a side facing an underside of the horizontal slat ( 18 ), when the horizontal slat ( 18 ) is arranged in a state of horizontal emission, this widens the distance between the horizontal lamella ( 18 ) and the guide surfaces of the side wall ( 16c . 16d ) at the two ends of the air outlet ( 16 ), thereby ensuring that conditioned air is discharged more at the two ends in the downward direction than in the middle section.

Furthermore, in the construction described above, the air outlet ( 16 ) is preferably formed so that when the horizontal slat ( 18 ) is arranged in a state of horizontal emission, the longitudinally middle section ( 16b -C) with the guide surfaces ( 16b -S) provided side wall ( 16a . 16b () 16c . 16d ) according to the inclination of the horizontal slat ( 18 ) is inclined. Furthermore, the with the guide surfaces ( 16b -S) provided side wall ( 16a . 16b () 16c . 16d ) of the air outlet ( 16 ) be designed so that in relation to the ceiling surface ( 70 ) formed angle from the longitudinally central portion ( 16b -C) to the areas near the two ends ( 16b -S) changed continuously.

If the horizontal slat ( 18 ) is disposed in a state of horizontal emission (for example, during the cooling mode), flows through the air outlet (FIG. 16 ) conditioned air discharged into the space between the longitudinally central portion ( 16b -C) the side wall ( 16a . 16b () 16c . 16d ) of the air outlet ( 16 ) and the horizontal lamella ( 18 ), and its flow direction is gradually changed. The conditioned air is in a direction substantially parallel to the ceiling surface ( 70 ). On the other hand, at this time at the two ends of the air outlet ( 16 ) conveyed conditioned air in a downward direction in the room.

In the construction described above, the horizontal slat ( 18 ) is preferably designed so that conditioned air can flow through upstream end edges of the regions near the two longitudinal ends. For example, opening sections ( 18c ) by notching parts of the horizontal blade ( 18 ) To be defined.

If the horizontal slat ( 18 ) is arranged in a state of horizontal emission, flows due to such an arrangement air at the two ends of the air outlet ( 16 ) through the opening sections ( 18c ) of the horizontal lamella ( 18 ) and so on. Therefore, air in the middle section of the air outlet ( 16 ) in the horizontal direction and, on the other hand, air is delivered at the two ends more targeted down.

Furthermore, if the air outlet ( 16 ) in areas near its longitudinal ends with extension sections ( 16L ), so that the opening length of the air outlet ( 16 ) extends longitudinally in areas facing an interior space (see 9 ), the guide surfaces ( 16b -S) of the air outlet ( 16 ) are desirably formed in areas substantially corresponding to the extension sections ( 16L ) correspond.

If the air outlet ( 16 ) with such extension sections ( 16L ), this leads, if no guide surfaces ( 16b -S), conditioned air in the air circulation channel (W) flows downwards and on the horizontal lamella ( 18 ) to travel from the side of the longitudinal middle section to the extension sections (FIG. 16L ) to flow. Thereafter, the conditioned air is slowly released in approximately horizontal direction. However, if the guide surfaces ( 16b -S) are provided in areas which essentially correspond to the extension sections ( 16L ), conditioned air is provided at both ends of the air outlet ( 16 ) are emitted more in the downward direction than in the case where no guide surfaces ( 16b -S) are provided.

effects

According to the problem-solving means described above, during the cooling mode requiring horizontal emission of conditioned air, air in the longitudinally central portion of the air outlet (FIG. 16 ) in the horizontal direction, while at the two longitudinal ends of the air outlet ( 16 ) a portion of the air is discharged in the downward direction. As a result, the air discharged at the two longitudinal ends is unlikely to be on the ceiling surface (FIG. 70 ) flow along. Contamination of the ceiling surface ( 70 ) is therefore prevented, and moreover, a total of horizontal emission is ensured. Therefore, the occurrence of contamination of the ceiling surface ( 70 ) are avoided while ensuring an emission direction according to the operating condition of the air conditioner.

Further, if the guide surfaces ( 16b -S) of the areas near the two longitudinal ends of the air outlet ( 16 ) Surfaces are the angle of the side wall ( 16a . 16b () 16c . 16d ) of the two ends of the air outlet ( 16 ), thereby realizing a simplified construction while at the same time preventing soiling of the ceiling by ensuring that conditioned air at both ends of the air outlet (FIG. 16 ) is delivered down.

Further, if the guide surfaces ( 16b -S) in the side wall ( 16a . 16b ) corresponding to a side facing an upper side of the horizontal slat ( 18 ), when the horizontal slat ( 18 ) is arranged in a state of horizontal emission, this narrows the distance between the horizontal lamella ( 18 ) and the guide surfaces ( 16b -S) at the two ends of the air outlet ( 16 ), whereby the flow velocity at the two ends of the air outlet ( 16 ) discharged air is reduced. As a result, at the two ends of the air outlet ( 16 Probably not entrained by air in the middle section of the air outlet ( 16 ) is discharged, whereby a pollution of the ceiling is more selectively prevented.

Even if, on the other hand, the guide surfaces in the side wall ( 16c . 16d ) corresponding to a side facing an underside of the horizontal slat ( 18 ), when the horizontal slat ( 18 is arranged in a state of horizontal emission, conditioned air at the two ends of the air outlet ( 16 ) are discharged in the downward direction, whereby contamination of the ceiling is prevented.

Further, when the longitudinal middle section (FIG. 16b -C) the side wall ( 16a . 16b () 16c . 16d ) is designed so that it corresponds to the inclination of the horizontal slat ( 18 ) is inclined when the horizontal slat ( 18 ) is arranged in a state of horizontal emission, it is possible to prevent contamination of the ceiling, because conditioned air at both ends of the air outlet ( 16 ), while ensuring that conditioned air is present in the middle section of the air outlet ( 16 ) is discharged in the horizontal direction.

If further the side wall ( 16a . 16b () 16c . 16d ) of the air outlet ( 16 ) is designed so that in relation to the ceiling surface ( 70 ) formed angle from the longitudinally middle portion ( 16b -C) to the areas near the two ends ( 16b -S), the angle of the sidewall ( 16b ) gradually change. This will cause the air outlet ( 16 ) from the point of view of construction quite superior. In addition, there are no parts that lead to an abrupt change in the emission angle, so that it is unlikely that there will be a turbulence of the air flow.

If further opening sections ( 18c ) or the like through which conditioned air is allowed to flow, at the upstream end edges of the regions near the two longitudinal ends of the horizontal fin (FIG. 18 ) flows at the two ends of the air outlet ( 16 ) discharged air through the opening portions ( 18c ), when the horizontal slat ( 18 ) is arranged in a state of horizontal emission. As a result, at the two ends of the air outlet ( 16 ) discharged in a targeted direction downwards, while in the central portion of the air outlet ( 16 ) conveyed air in the horizontal direction, thereby ensuring that contamination of the ceiling is prevented.

If further, then, if the extension sections ( 16L ) in the areas near the two longitudinal ends of the air outlet ( 16 ), the guide surfaces ( 16b -S) of the air outlet ( 16 ) are formed in areas that are substantially the extension sections ( 16L ) of the air outlet ( 16 ), at the two ends of the air outlet ( 16 ) is likely to be discharged downwards, thereby enhancing the effect of preventing soiling of the ceiling.

BRIEF DESCRIPTION OF THE DRAWINGS

1 Fig. 11 is a schematic cross-sectional view of a ceiling-mounted air conditioner according to an embodiment of the invention;

2 Fig. 12 is a perspective view of the ceiling-mounted air conditioner when viewed from below;

3 1, which is an enlarged construction diagram of an air outlet, illustrates a state in which the direction in which conditioned air is discharged is set to a state of "horizontal emission";

4 is a schematic representation similar 3 but illustrates a state in which the emission direction of the conditioned air is set to a state of "emission down".

5 is a perspective view of the air outlet when viewed from below;

6 is a perspective view of a horizontal slat;

7 Fig. 10 is a construction diagram of a channel-type air conditioner;

8th consists of the 8A - 8D FIGS. 7A and 6B are perspective views showing horizontal sipes having different shapes of the opening portion;

9 is a partial perspective view when in the air outlet extension sections are defined; and

10 Fig. 12 is an explanatory diagram for illustrating a state of a flow of conditioned air from an air outlet when viewed from the side of a conventional air conditioner.

BEST MODE FOR CARRYING OUT THE INVENTION

following Become embodiments of the Invention with reference to the figures described.

1 is a vertical section showing the arrangement of the embedded in the ceiling air conditioning ( 1 ) according to an embodiment of the invention. As shown in the figure, the air conditioning system ( 1 ) a housing ( 10 ), in which a fan ( 20 ) and a heat exchanger ( 30 ) are housed. The air conditioner ( 1 ) is in a mounting hole ( 71 embedded in a ceiling slab (ceiling) ( 70 ) opens. In this way, the air conditioner ( 1 ) mounted in a covered space.

The housing ( 10 ) consists of a box-shaped main body housing ( 11 ), which is open at the bottom, and a decorative plate ( 14 ), with which a lower opening portion of the main body housing ( 11 ) is covered. The main body case ( 11 ) is suspended by means of a Hängerings, which is not shown in the figure, fixed to an overlying support or the like. In particular, the main body housing ( 11 ) from an octagonal shaped top plate ( 12 ) by bevelled notching of four corners of a square plate (not shown) and side plates ( 13 ) extending from the outer edges of the upper plate ( 12 ) extend downwards, is formed. The ornamental plate ( 14 ) is a plate having a substantially square shape and is at the lower ends of the side plates ( 13 ) of the main body housing ( 11 ) attached. The ornamental plate ( 14 ) is along the ceiling plate ( 70 ), so that its circumference with a lower surface of the ceiling plate ( 70 ).

As well as in 2 which is a perspective view showing a state in which the air conditioner (FIG. 1 ) is mounted on the ceiling, is also an air intake ( 15 ) in a substantially central portion of the ornamental plate ( 14 ) is formed to form a square opening. Immediately outside the four sides of the air intake ( 15 ) and in parallel there are four rectangular air outlets ( 16 ). In addition, the air intake ( 15 ) over its entire surface with an air filter ( 17 ) for removing suspended matter, such as particulate matter contained in the room air. The entire lower surface of the air filter ( 17 ) is mounted on a grid cover of the filter.

The air outlet ( 16 ) of the ornamental plate ( 14 ) is between an outer guide surface ( 16a . 16b ), which is a side wall of an air passage located on the outer peripheral side of the plate (on the right side in the figures), and an inner guide surface (FIG. 16c . 16d ) defined on the inner peripheral side of the plate (on the left in FIG the figures) side wall is. Areas near the two longitudinal ends of the air outlet (FIG. 16 ) are designed so that conditioned air is discharged more in the downward direction than in a longitudinally central portion of the air outlet ( 16 ). This is the air outlet ( 16 ) in the areas near its two longitudinal ends with guide surfaces ( 16b -S) so that conditioned air is discharged more in the downward direction than in the longitudinal middle section. The guide surfaces ( 16b -S) of the air outlet ( 16 ) are defined by areas near the two longitudinal ends of one of the side walls of the air outlet ( 16 ), ie the side wall ( 16a . 16b ). It is arranged so that between the areas near the two longitudinal ends ( 16b -S) of the side wall ( 16a . 16b ) and the ceiling surface ( 70 ) is greater than that between the longitudinal middle section ( 16b -C) the side wall ( 16a . 16b ) and the ceiling surface ( 70 ) formed angles.

As in particular in 3 and 4 shown enlarged, the outer guide surface ( 16a . 16b ) from a first outer guide surface ( 16a ), which extends substantially vertically downwards, and a second outer guide surface (FIG. 16b ) extending from the lower end of the first outer guide surface ( 16a ) to the underside of the decorative plate ( 14 ) slopes obliquely downward toward the outer periphery of the plate. These outer guide surfaces ( 16a . 16b ) are evenly connected.

The second outer guide surface ( 16b ) comprises the middle section ( 16b -C) and the two ends ( 16b -s). The middle section ( 16b C) is located longitudinally in the middle in the air outlet ( 16 ), and its inclination to the ceiling surface ( 70 ) is set relatively small (an angle of about 30 degrees). The two ends ( 16b -S) are located near the two longitudinal ends of the air outlet ( 16 ) and their inclination to the ceiling surface ( 70 ) is set relatively large (an angle of about 60 degrees). This a larger angle to the ceiling surface ( 70 ) forming sections are in the guide surfaces ( 16b -S) formed.

The inclination of the second outer guide surface ( 16b ) gradually changes from the middle section ( 16b -C) to the two ends ( 16b -S), and to the ceiling surface ( 70 ) formed angle changes continuously. And, like in 5 shown as viewed from below a perspective view of the air outlet ( 16 ), the second outer guide surface ( 16b ) further has a lower end edge ( 16b -E), which is shaped like a circular arc.

How against in 3 and 4 shown, the inner guide surface ( 16c . 16d ) from a first inner guide surface ( 16c ), which extends substantially vertically downwards, and a second inner guide surface (FIG. 16d ) extending from the lower end of the first inner guide surface ( 16c ) is inclined slightly obliquely downward to the outer periphery of the plate. These inner guide surfaces ( 16c . 16d ) are evenly connected.

The outer guide surface ( 16a . 16b ) is in an outer element ( 14a ) of the ornamental plate ( 14 ), while the inner guide surface ( 16c . 16d ) in an inner element ( 14b ) of the ornamental plate ( 14 ) is trained. The air outlet ( 16 ) is, as described above, between the outer guide surface ( 16a . 16b ) and the inner guide surface ( 16c . 16d ) Are defined. And in the air outlet ( 16 ) is the horizontal air baffle or the horizontal slat ( 18 ), which can vertically adjust the direction in which conditioned air is discharged, between the outer guide surface (FIG. 16a . 16b ) of the outer element ( 14a ) and the inner guide surface ( 16c . 16d ) of the inner element ( 14b ) arranged. In addition, the guide surfaces ( 16b -S) of the air outlet ( 16 ) on one side of the horizontal lamella ( 18 ) leading to an upper side of the horizontal slat ( 18 ), when the horizontal slat ( 18 ) is arranged in a state of horizontal emission.

The horizontal lamella ( 18 ) is as in 6 shown, a long plate member and is slightly bent over its width direction. From an inner surface of the horizontal lamella ( 18 ) protruding arms ( 18a . 18b ) are each with the two longitudinal ends of the horizontal blade ( 18 ) formed in one piece. At the end of each arm ( 18a ) is a connecting pin ( 18b ) formed in the longitudinal direction of the horizontal slat ( 18 ) extends to the outside. The horizontal lamella ( 18 ) is at the air outlet ( 16 ) are mounted so that they around the connecting pins ( 18b . 18b ) can be swung around. In particular, the horizontal slat ( 18 ) by a motor (not shown) around the connecting pins ( 18b . 18b ) swung around. In the arrangement described above, the horizontal slat ( 18 ) downwards when conditioned air is to be delivered towards the very bottom, as in 4 shown. In a so-called "horizontal emission" mode, the horizontal slat ( 18 ) is adjusted so that it is oriented upwards, as in 3 shown.

Notches ( 18c ) as opening portions through which the conditioned air can flow are at the upstream end edges of the regions near the two longitudinal ends of the horizontal fin (FIG. 18 ) Are defined. These scores ( 18c ) are at the upstream end edges of the areas near the two longitudinal ends of the horizontal slat ( 18 ) and have a length of approximately one quarter of the length of the horizontal slat ( 18 ). Because of the provision of these notches ( 18c ) has the horizontal slat ( 18 ) such a shape that the two ends ( 18e ) a narrowed width of about two thirds of the width of the middle section ( 18d ) to have. Furthermore, the horizontal slat ( 18 ), for example, have the following specific dimensions. The total length of the horizontal slat ( 18 ) is about 480 mm. The width of the horizontal slat ( 18 ) (the width of the middle section ( 18d )) is about 37 mm. The width of each end ( 18e ) is about 25 mm. The length of each notch ( 18c ) is about 120 mm.

The outer guide surface ( 16a . 16b ) bends in its central portion substantially according to the cross-sectional shape of the horizontal slat ( 18 ) (the shape is not limited to such a bent shape, and any shape may be used as long as it is substantially the shape of the horizontal sipe (FIG. 18 ) corresponds). In other words, the air outlet ( 16 ) is designed so that when the horizontal slat ( 18 ) is arranged in a state of horizontal emission, the side wall ( 16a . 16b C) of the longitudinal middle portion a slope corresponding to the horizontal slat ( 18 ), in other words, the total inclination is substantially identical to the inclination of the horizontal slat (FIG. 18 ). The inner guide surface ( 16c . 16d ) is shaped in such a way that it extends overall more vertically downwards than the outer guide surface (FIG. 16a . 16b ) of the outer guide element ( 14a ). In addition, the shape of the inner guide surface ( 16c . 16d ) a question of choice.

And these two wall surfaces (the outer guide surface ( 16a . 16b ) and the inner guide surface ( 16c . 16d ), which have the above-mentioned shapes and face each other, are designed to extend over the entire length of the air outlet (FIG. 16 ) (ie in a direction perpendicular to the paper surface of the figure). The between the wall surface ( 16a . 16b ) and the wall surface ( 16c . 16d ) has the function of serving as an "approach path" for adjusting a flow of conditioned air while simultaneously changing the direction of the conditioned airflow.

The fan ( 20 ), on the other hand, lies substantially in the center of the main body housing ( 11 ). This fan is a so-called turbo fan in which a shovel ( 23 ) between a fan cowl ( 21 ) and a hub ( 22 ) is held. One on the top plate ( 12 ) of the main body housing ( 11 ) mounted drive shaft ( 26 ) of the fan motor ( 25 ) is firmly in the hub ( 22 ) of the fan ( 20 ) used. The fan ( 20 ) is due to the driving force of the fan motor ( 25 ), causing the area under the fan ( 20 ) sucked air is transported radially to the side. Furthermore, a funnel ( 27 ), over the air passing through the air intake ( 15 ) inside the case ( 10 ) has flowed to the fan ( 20 ), below the fan ( 20 ) intended.

The heat exchanger ( 30 ) is a so-called Querverrippter heat exchanger, which consists of a large number of plate-like ribs ( 31 ), which are arranged parallel to each other, and from a heat transfer tube ( 32 ) arranged so that it passes through the ribs ( 31 ) runs. The heat exchanger ( 30 ) is formed as a rectangular cylinder when viewed from above, around the circumference of the fan ( 20 ) to surround. The heat exchanger ( 30 ) is connected via a coolant pipe (not shown) to an outdoor unit. The heat exchanger ( 30 ) acts as an evaporator during the cooling mode of operation and as a condenser during the heating mode of operation to control the temperature condition of the fan ( 20 ) to control delivered air. And a drain pan ( 33 ) for receiving waste water is below the heat exchanger ( 30 ) arranged.

Thanks to the construction described above, there is an air circulation duct (W), which is located above the air filter ( 17 ), the funnel ( 27 ), the fan ( 20 ) and the heat exchanger ( 30 ) from the air inlet ( 15 ) of the ornamental plate ( 14 ) to the air outlet ( 16 ) is inside the main body housing ( 11 ) of the air conditioner ( 1 ) Are defined. And if the fan ( 20 ) is driven during the air conditioning mode, flows out of the air inlet ( 15 ) over the air filter ( 17 ) inside the case ( 10 ) aspirated room air in this order in the funnel ( 27 ), into the fan ( 20 ) and in the heat exchanger ( 30 ) in the air circulation passage (W). The room air exchanges with coolant in the heat exchanger ( 30 ) Heat and their temperature is controlled (cooled during the cooling mode and heated during the heating mode). Thereafter, the air is given off as conditioned air into an interior. In this way, the interior is air conditioned.

If there is a need for air-conditioned air to be discharged relatively downwards, such as in the heating mode or the like, the horizontal fin (FIG. 18 ) is oriented substantially vertically downwards (see 4 ), so that conditioned air between the located on the outer periphery of the plate side wall ( 16a . 16b ) and located on the inner circumference of the plate side wall ( 16c . 16d ) of the air outlet ( 16 ) on the horizontal lamella ( 18 ) and is discharged in a downward direction, as indicated by the arrow S in the figure.

During the mode of so-called "horizontal emission" (for example during the cooling mode and so on), on the other hand, the horizontal slat ( 18 ) turned upwards (see 3 ), so the top ( 18f ) of the horizontal lamella ( 18 ) substantially parallel to the middle section ( 16b C) the second outer guide surface ( 16b ) of the air outlet ( 16 ) becomes. As a result, conditioned air flows in the middle section of the air outlet ( 16 ) in the arch at the middle section ( 18d ) of the horizontal lamella ( 18 ), and the direction of its flow line changes strongly and evenly. As indicated by the arrow S1 in the figure, the conditioned air then flows between the second outer guide surface (FIG. 16b C) on the outer peripheral side of the air outlet relative to the plate ( 16 ) and the horizontal lamella ( 18 ). Thereafter, the conditioned air is at an emission angle as parallel as possible to the bottom of the ceiling plate ( 70 ) is (for example at an angle of 30 to 35 degrees to the bottom of the ceiling plate ( 70 )) through the air outlet ( 16 ).

Furthermore, flows at the two ends of the air outlet ( 16 ) a portion of the conditioned air which has flowed down through the air circulation duct (W), even more downwards (ie in a direction indicated by arrow S3) than in the direction of arrow S1, because the between the guide surfaces ( 16b -S) at the two ends of the air outlet ( 16 ) and the ceiling surface ( 70 ) formed angle is large and the horizontal slat ( 18 ) approaches the guide surfaces ( 16b -S) to reduce the distance between them. Furthermore, as described above, the distance between the horizontal lamella ( 18 ) and the guide surfaces ( 16b -S) at the two ends of the air outlet ( 16 ), and as a result, the flow velocity of the air flowing in the direction of arrow S3 decreases. Furthermore, flows at the two ends of the air outlet ( 16 ) the remaining part of the conditioned air, which has flowed down through the air circulation duct (W), through the notches ( 18c ) of the two ends ( 18e ) of the horizontal lamella ( 18 ) and is delivered down as indicated by arrow S2 of FIG 3 indicated. As a result, it is unlikely that at the two ends of the air outlet ( 16 ) discharged air on the ceiling surface ( 70 ) flows along.

In a conventional ceiling-mounted air conditioner, an airflow discharged at low air-emission speed sections (at both ends of the air outlet (FIG. 16 )) slightly the bottom of the ceiling plate ( 70 ) to reach. When the direction of emission of conditioned air during the mode of cooling by the horizontal blade ( 18 ) is oriented relatively upward so that the between the emission direction and the underside of the ceiling plate ( 70 ) is in the range between about 30 and about 35 degrees, this causes a flow of air at the bottom of the ceiling plate ( 70 ) flows along. As a result, in the areas (D), the ceiling becomes soiled as indicated by the dashed lines in FIG 2 indicated. In other words, the pollution of the ceiling is distributed substantially V-shaped at each air outlet. In the air conditioner ( 1 ) of the present embodiment, however, at the two ends of the air outlet ( 16 ) discharged air during the mode of cooling, which requires above all a "horizontal emission" of conditioned air, probably not on the underside of the ceiling plate ( 70 ) flow along. Even if, therefore, the direction of emission through the air outlet ( 16 ) discharged air through the horizontal slat ( 18 ) is changed so that the air conditioned between the direction of emission and the underside of the ceiling plate ( 70 ) at the central portion of the air outlet approaches to, for example, about 30 to about 35 degrees, the occurrence of fouling of the ceiling can be prevented.

In the air conditioner ( 1 ) of the present embodiment, therefore, the pollution of the ceiling is prevented while at the same time making it possible to approach the emission direction of the conditioned air closer to a horizontal direction than conventionally, especially during the cooling mode which requires a horizontal emission of conditioned air. This prevents a resident present in the room from feeling uncomfortable (drafts) while ensuring efficient air-conditioning.

Further, in the present embodiment, each notch ( 18c ) of the horizontal lamella ( 18 ) only in one area of each end ( 18d ) of the horizontal lamella ( 18 ) whose length is about one quarter of the length of the horizontal slat ( 18 ), thus making it possible to achieve overall satisfactory "horizontal emission" operation while at the same time preventing the occurrence of fouling of the ceiling.

Further the invention is not in the above embodiment limited. The invention also comprises various other embodiments.

For example, in the embodiment described above, the guide surfaces ( 16b -S) only in the areas near the two ends of the outer guide surface ( 16a . 16b ) of the air outlet ( 16 ) and in addition, the inclination of the side walls of the two ends of the inner guide surface ( 16c . 16d ) so that they can act as a guide surface. To the Example is that between the areas near the two ends of the inner guide surface ( 16c . 16d ) of the air outlet ( 16 ) and the ceiling surface formed angle larger than that between the middle portion of the inner guide surface ( 16c . 16d ) and the ceiling surface formed angles, whereby it is possible that the areas in the vicinity of the inner guide surface ( 16c . 16d ) serve as a guide surface. Even with such an arrangement, it becomes possible to supply air at both ends of the air outlet (FIG. 16 ) to flow down, whereby the occurrence of contamination of the ceiling is prevented.

Furthermore, it is provided in the arrangement described above, that the angle of the outer guide surface ( 16a . 16b ) of the air outlet ( 16 ) is continuously changed between the central portion and the two ends. Alternatively, other embodiments may be possible. For example, it can be provided that the angle of the outer guide surface ( 16a . 16b ) of the air outlet ( 16 ) gradually changed. In such a case, the lower end edge of the second outer guide surface ( 16b ) and the lower end edge of the second inner guide surface ( 16d ) have a different shape than a circular arc, z. B. a trapezoidal shape.

In addition to the arrangement that the two ends of the air outlet ( 16 ) differ in the angle in which conditioned air from the middle section of the outlet ( 16 ), the volume at the two ends of the air outlet ( 16 ) downwardly flowing air are increased when, as in the embodiment described above, the emission angle in the emission direction on the inside of the horizontal blade ( 18 ) (the side of the inner guide surface ( 16c . 16d ) is originally set more downward than in the emission direction on the outside (the side of the outer guide surface ( 16a . 16b )). In other words, in addition to the arrangement that the areas in the vicinity of the two longitudinal ends at the angle of the inner guide surface ( 16c . 16d ) are designed differently than the middle section, the opening width of the air outlet ( 16 ) at the two ends be made larger than the opening width of the air outlet ( 16 ) in the longitudinally central portion to increase the volume of the downwardly flowing air.

As described above, it is sufficient if the invention is designed so that conditioned air in the areas near the two longitudinal ends of the air outlet ( 16 ) is discharged more in the downward direction than in the longitudinally central portion of the air outlet ( 16 ). Further, means other than the guide surface may be used as far as the invention has such a construction.

Further, the invention in the embodiment described above, the air conditioning ( 1 ) is applied by the so-called four-directional type radiator, which is provided with a turbo fan and delivers conditioned air in four directions. However, the invention is not limited to such an application. For example, the invention is applicable to an air-conditioning system of the so-called recessed two-way type which discharges conditioned air in two directions.

Further, the invention is applicable not only to air-conditioned ceiling-mounted type but also to duct-type air-conditioner. According to 7 is the air conditioner ( 50 ) of the duct type to an air conditioner, with one at the ceiling plate ( 70 ) mounted ventilation unit ( 51 ) via a fan duct ( 52 ) with an air conditioning main body ( 53 ) mounted on a building roof or the like. Even for the ventilation unit ( 51 ) of the air conditioner ( 50 ), the same effects as in the above-described embodiment can be achieved by controlling the emission direction by, for example, providing the guide surfaces (FIG. 16b -S) in the areas near the two longitudinal ends of the air outlet ( 16 ) is regulated.

Furthermore, in the embodiment described above, the notches ( 18c ) as opening portions in the areas near the two ends ( 18e ) of the horizontal lamella ( 18 ) educated. The opening sections ( 18c ) are not necessarily provided. Even in cases where opening portions are defined, through-holes or the like may be used instead of the notches (FIG. 18c ) in the horizontal lamella ( 18 ), and any construction may be used as long as conditioned air is present during the "horizontal emission" mode at both ends of the air outlet (FIG. 16 ) is discharged in the downward direction. In other words, the horizontal slat ( 18 ) preferably has upstream end edges, which are brought into such a shape that the flow velocity of the on a negative pressure side of the horizontal blade ( 18 ) (a stream of air downwards (see S2 of 3 ) on the back of the horizontal slat ( 18 ) (on the side of the inner guide surfaces ( 16c . 16d ) of the air outlet ( 16 ), ie on the inside of the emission direction)) is greater at the two ends than in the longitudinally middle section. It should be noted, however, that such an arrangement is not necessarily made.

Further, the shape and the dimensions the horizontal lamella ( 18 ) and the shape and dimensions of the notch shown above ( 18c ) are only examples and therefore, of course, depending on the shape and dimensions of a product according to the invention can be changed accordingly.

If the opening section ( 18c ) is a notch, the notch ( 18c ) be formed in various forms, and in 8A - 8C are horizontal slats ( 18 ) with different ends. 8A shows an example of the score ( 18c ), in which upstream end edges of the regions in the vicinity of the two longitudinal ends of a horizontal blade ( 18 ) are formed into a circular arc. 8B shows another example of the score ( 18c ), in which upstream end edges of the regions in the vicinity of the two longitudinal ends of a horizontal blade ( 18 ) are obliquely linearly shaped. 8C shows yet another example of the score ( 18c ), in which upstream end edges of the regions in the vicinity of the two longitudinal ends of a horizontal blade ( 18 ) in relation to the in 8A illustrated arch are formed inverted circular arc.

Further shows 8D a replacement for the opening section ( 18c ). In particular, each end of the horizontal slat ( 18 ) are brought into a three-dimensionally twisted shape so that the upstream end edges of the longitudinally central portion to the two ends of the horizontal blade ( 18 ) rise up. Since it is unlikely in this case that the air at the ends of the horizontal slat ( 18 ), it is unlikely that the ends of the horizontal slat ( 18 ) carry warm air from the area. This offers the advantage that condensation is unlikely.

Further, for example, in a ceiling-mounted air conditioner, pipes and boxes for electrical components are located in corners of the main body housing ( 11 ), and the decorative plate ( 14 ), four air outlets must have the same opening shape to provide a better appearance, which results in a difference in the opening length of the air duct between the side of the main body housing (FIG. 11 ) and the side of the decorative plate ( 14 ), as in 9 shown. In order to take account of such a case, there are four defined extension sections ( 16L ) at the two longitudinal ends of the air outlet ( 16 ), so that the opening length of the air duct in areas facing an interior in the longitudinal direction of the air outlet ( 16 ) is extended. In addition, the length of the extension sections varies ( 16L ) from an air outlet ( 16 ) On the other hand, depending on the product according to the invention.

Therefore, the guide surfaces ( 16b -S) and the opening sections ( 18c ), such as in the upstream end edges of the regions near the two longitudinal ends of the horizontal fin ( 18 ) formed notches or the opening portions ( 18c ) equivalent sections are desirably defined in areas substantially corresponding to the extension sections ( 16L ) of the air outlet ( 16 ) correspond. Without the guide surfaces ( 16b -S) or the opening sections ( 18c ), or if these are short, discharged air is likely at the two ends of the horizontal slat ( 18 ) and is likely to be emitted in a horizontal direction. However, if they are designed so that they are substantially the extension section ( 16L ), it becomes possible to adjust the volume of the in the extension sections ( 16L ) remaining air at the two longitudinal ends of the horizontal slat ( 18 ) to reduce. As a result, the occurrence of contamination of the ceiling can be prevented. The same applies to the air conditioning ( 50 ) of the channel type.

Claims (20)

Decorative panel for air conditioning with an air outlet ( 16 ), by the conditioned air from the direction of a ceiling surface ( 70 ) is discharged into an interior, and one at the air outlet ( 16 ) mounted horizontal air baffle ( 18 ) for adjusting the direction in which conditioned air is discharged, characterized in that the air outlet ( 16 ) is designed so that conditioned air in areas near the two longitudinal ends of the air outlet is discharged more in the downward direction than in a longitudinally central portion of the air outlet ( 16 ). Air conditioning plate according to claim 1, wherein the air outlet ( 16 ) in the areas near its two longitudinal ends with guide surfaces ( 16b -S), which guide the conditioned air so that it is discharged in these areas more in the downward direction than in the longitudinally central portion. An air conditioning plate according to claim 2, wherein: the guide surfaces ( 16b -S) of the air outlet ( 16 ) in areas near the two longitudinal ends of one or both side walls ( 16a . 16b ) and ( 16c . 16d ) of the air outlet ( 16 ) are formed, and between the areas near the two longitudinal ends ( 16b -S) of the side wall ( 16a . 16b () 16c . 16d ) of the air outlet ( 16 ) and the ceiling surface ( 70 ) formed angle is greater than that between a longitudinally middle Section ( 16b -C) the side wall ( 16a . 16b () 16c . 16d ) of the air outlet ( 16 ) and the ceiling surface ( 70 ) formed angles. Air conditioning plate according to claim 3, wherein the guide surfaces ( 16b -S) of the air outlet ( 16 ) from the side wall ( 16a . 16b ) corresponding to a side facing an upper side of the horizontal baffle plate ( 18 ), when the horizontal air baffle ( 18 ) is arranged in a state of horizontal emission. Air conditioning plate according to claim 3, wherein the guide surfaces of the air outlet ( 16 ) from the side wall ( 16c . 16d ) corresponding to a side facing an underside of the horizontal baffle ( 18 ), when the horizontal air baffle ( 18 ) is arranged in a state of horizontal emission. Air conditioning plate according to one of claims 2-5, wherein the air outlet ( 16 ) is designed so that when arranging the horizontal baffle plate ( 18 ) in a state of horizontal emission the longitudinal middle section ( 16b -C) with the guide surfaces ( 16b -S) provided side wall ( 16a . 16b () 16c . 16 ) according to the inclination of the horizontal baffle plate ( 18 ) is inclined. Air conditioning plate according to one of claims 3-6, wherein the side wall ( 16a . 16b () 16c . 16d ) of the guide surfaces ( 16b -S) provided air outlet ( 16 ) is designed so that the with the ceiling surface ( 70 ) formed angle from the longitudinally central portion ( 16b -C) to the areas near the two ends ( 16b -S) changed continuously. Air conditioning zierplatte according to any one of claims 2-7, wherein the horizontal air baffle ( 18 ) is configured so that conditioned air can flow through end edges of the regions located near the two longitudinal ends located on the upstream side of the airflow. Ventilation unit for an air conditioning system with an air outlet ( 16 ), by the conditioned air from the direction of a ceiling surface ( 70 ) is discharged into an interior, and one at the air outlet ( 16 ) mounted horizontal air baffle ( 18 ) for adjusting the direction in which conditioned air is discharged, characterized in that the air outlet ( 16 ) is designed so that conditioned air in areas in the vicinity of the two longitudinal ends of the air outlet ( 16 ) is discharged more in the downward direction than in a longitudinally central portion of the air outlet ( 16 ). An air conditioning ventilation unit according to claim 9, wherein the air outlet ( 16 ) in the areas near its two longitudinal ends with guide surfaces ( 16b -S), which guide the conditioned air so that it is discharged in these areas more in the downward direction than in the longitudinally central portion. An air conditioning ventilation unit according to claim 10, wherein: the guide surfaces ( 16b -S) of the air outlet ( 16 ) in areas near the two longitudinal ends of one or both side walls ( 16a . 16b ) and ( 16c . 16d ) of the air outlet ( 16 ) are formed, and between the areas near the two longitudinal ends ( 16b -S) of the side wall ( 16a . 16b () 16c . 16d ) of the air outlet ( 16 ) and the ceiling surface ( 70 ) is greater than that between a longitudinally central portion ( 16b -C) the side wall ( 16a . 16b () 16c . 16d ) of the air outlet ( 16 ) and the ceiling surface ( 70 ) formed angles. An air conditioning ventilation unit according to claim 11, wherein the guide surfaces ( 16b -S) of the air outlet ( 16 ) from the side wall ( 16a . 16b ) corresponding to a side facing an upper side of the horizontal baffle plate ( 18 ), when the horizontal air baffle ( 18 ) is arranged in a state of horizontal emission. An air conditioning ventilation unit according to claim 11, wherein the guide surfaces of the air outlet ( 16 ) from the side wall ( 16c . 16d ) corresponding to a side facing an underside of the horizontal baffle ( 18 ), when the horizontal air baffle ( 18 ) is arranged in a state of horizontal emission. An air conditioning ventilation unit according to any one of claims 10-13, wherein the air outlet ( 16 ) is designed so that when arranging the horizontal baffle plate ( 18 ) in a state of horizontal emission the longitudinal middle section ( 16b -C) with the guide surfaces ( 16b -S) provided side wall ( 16a . 16b () 16c . 16d ) according to the inclination of the horizontal baffle plate ( 18 ) is inclined. An air conditioning ventilation unit according to any one of claims 10-14, wherein the guide surfaces ( 16b -S) provided side wall ( 16a . 16b () 16c . 16d ) of the air outlet ( 16 ) is designed so that the with the ceiling surface ( 70 ) formed angle from the longitudinally central portion ( 16b -C) to the areas near the two ends ( 16b -S) changed continuously. Air conditioning ventilation unit according to any one of claims 10-15, wherein the horizontal Luftleit sheet ( 18 ) is configured so that conditioned air can flow through end edges of the regions located near the two longitudinal ends located on the upstream side of the airflow. Air conditioning system with a decorative plate (shown along a ceiling surface ( 14 ), wherein the decorative plate ( 14 ) consists of a decorative plate according to any one of claims 1-8. Air conditioning system with a decorative plate (shown along a ceiling surface ( 14 ), wherein: the ornamental plate ( 14 ) consists of a decorative plate according to any one of claims 2-8, an air outlet ( 16 ) of the ornamental plate ( 14 ) Extension sections ( 16L ), so that the length of the longitudinal opening of the air outlet ( 16 ) becomes larger in areas facing an interior, and guide surfaces ( 16b -S) of the air outlet ( 16 ) are formed in areas that are substantially the extension sections ( 16L ) of the air outlet ( 16 ) correspond. Air conditioning system in which a ventilation unit attached to a ceiling surface ( 51 ) via a fan duct ( 52 ) with a main body ( 53 ) is connected to the air conditioning system, wherein the ventilation unit ( 51 ) consists of a ventilation unit according to any one of claims 9-16. Air conditioning system in which a ventilation unit attached to a ceiling surface ( 51 ) via a fan duct ( 52 ) with a main body ( 53 ) of the air conditioning system, wherein: the ventilation unit ( 51 ) consists of a ventilation unit according to any one of claims 10-16, an air outlet ( 16 ) of the ornamental plate ( 14 ) Extension sections ( 16L ), so that the length of the longitudinal opening of the air outlet ( 16 ) becomes larger in areas facing an interior, and guide surfaces ( 16b -S) of the air outlet ( 16 ) are formed in areas that are substantially the extension sections ( 16L ) of the air outlet ( 16 ) correspond.