NL1037249C2 - DEVICE AND METHOD FOR SUPPLYING TO AT LEAST ONE LOCATION TO BE COOLED OF A COOLED AIRFLOW. - Google Patents

Description

DEVICE AND METHOD FOR SUPPLYING A COOLED AIRFLOW TO AT LEAST ONE LOCATION

The present invention relates to a device 5 for supplying a cooled air flow to at least one location to be cooled. The present invention also relates to supplying a cooled air stream to at least one location to be cooled with such a device.

In areas with a warm climate, it is customary to provide rooms where people are staying with air conditioning, with which the air in the room can be conditioned, usually cooled, as desired by people in the room. This cooling of the air in the said spaces is accompanied by a considerable energy consumption. There is therefore a need for a comfort-enhancing device, which is also energetically favorable.

The device according to the invention comprises a cooling unit for generating a cooled air stream; and a guide channel for guiding the cooled air flow from the cooling unit to the at least one location to be cooled, wherein substantially the entire wall of the guide channel is permeable to the air of cooled air flow, an outflow portion of the wall of the guide channel and has first air permeability, and a guide portion of the wall has a second air permeability, wherein the outflow portion of the wall can be placed near the at least one location to be cooled, and the air permeability of the outflow portion of the wall is higher than the air permeability of the guide portion of the wall.

2

This device makes it possible to concentrate the cooled air flow at this specific location by means of the placement of the outflow part of the wall of the guide channel near a specific location for cooling within a room, for example a bed or a workplace. This makes the device according to the invention energetically favorable with respect to a device whose supplied air flow cannot be concentrated at the specific location. Moreover, because not only the outflow portion of the wall of the guide channel, but substantially the entire wall is permeable to the air of the cooled air stream, it is thereby possible to have undesired effects of guiding the cooled air stream through the guide channel, such as condensation. on the wall of the guide channel. Such condensation can, for example, reduce comfort when the condensation falls off the wall onto the bed, the workplace, or even to the people using it. Such condensation is a problem in particular in areas with a relatively high air humidity.

The outflow portion of the wall of the guide channel can be placed above the at least one location to be cooled. This measure makes it possible to use gravity to cause the relatively cold air to descend at the location to be cooled and the persons using it. This has the advantage that the outflow speed of the cooled air of the air flow from the outflow portion of the wall of the guide channel can be lower, so that the noise generated when the air flow passes through the wall of the guide channel and thus the air flow. nuisance is less, while moreover the people experience the comfort of a descending cool air.

The device also comprises a frame with which the outflow part of the wall of the guide channel can be placed above the at least one location to be cooled. This measure makes it possible, for example, to simply place the device above the desired location for cooling. For example, the device can be designed as a movable unit that can easily be placed in an existing space 10 to supply cooled air to a specific location in that space.

The guide channel is clamped in the frame by means of a tension extending between the guide channel and the frame. This measure makes it possible, for example, to physically separate the guide channel from the frame and thus to prevent condensation on the frame or on the wall of the guide channel when a relatively cold air flow is supplied.

In a further favorable embodiment of the device according to the invention, the temperature of the cooled air stream is at least 2 ° C lower than the temperature of the ambient air. The temperature of the cooled air flow that is at least 2 ° C lower than the temperature of the ambient air causes the cooled air to descend by means of gravity to the location to be cooled, whereby the person using the location experiences a pleasant cooling without a draft.

In a further favorable embodiment of the device wherein the outflow part of the wall of the guide channel can be placed above the at least one location to be cooled, the outflow part of the wall of the guide channel is at a distance of preferably between 100-300 cm , more preferably between 150-250 cm, and even more preferably 4, can be placed substantially 200 cm above the at least one location to be cooled. This distance of, for example, 100, 125, 150, 175, 200, 225, 250, 275, 300 cm appears to enable a good spread of the cooled air flow over the location to be cooled, while the device also with regard to its height is suitable to place it in an existing space.

In a further embodiment the fixture has a substantially airtight portion extending from the wall 10 of the guide channel over a distance of preferably at least 10 cm, more preferably at least 20 cm, and even more preferably at least 30 cm in extends in the direction of the frame. This measure makes it possible, for example, when supplying a relatively cold air stream to a location to be cooled, to prevent hot air that is above the outflow part of the guide channel being sucked in by the air stream. As a result, the efficiency of the device can be further improved, which makes the device more energetically favorable.

In a further favorable embodiment of the device according to the invention, the cooling unit comprises a suction mouth for sucking in an air flow to be cooled, which suction mouth can be placed under the outflow portion 25 of the wall of the guide channel. This measure makes it possible to at least partially re-cool the cooled air stream supplied to the location to be cooled in the cooling unit. The cooled air which has flowed out of the outflow portion of the wall of the guide channel placed above the location to be cooled will fall under the influence of gravity and is then sucked in again by the cooling unit under the outflow portion. The temperature of this air, although it will warm up slightly before it is sucked in again, is cooler than the ambient air, so that only a small degree of additional cooling is required, which makes the device more energetically favorable.

In a further favorable embodiment of the device according to the invention, the wall of the guide channel is made of textile. This measure makes it possible for the air flow to leave the guide channel virtually silently, so that the comfort of the person using the location is maintained.

In a further favorable embodiment of the device according to the invention, the outflow speed of the air of the cooled air flow from the outflow portion of the wall of the guide channel is preferably between 0.04 - 0.12 m / s, more preferably between 0 , 06 - 0.10 m / s, and even more preferably substantially 0.08 m / s. These outflow rates of, for example, 0.04; 0.05; 0.06; 0.07; 0.08; 0.09; 0.10; 0.11 and 0.12 m / s, together with the fall acceleration exerted by gravity on the cooled air 20, ensures that the speed of the air flow upon reaching a person using the location to be cooled is so low that this person experiences a comfort-enhancing cooling, without the air flow being experienced as heat.

In a further favorable embodiment of the device according to the invention, the air permeability of the outflow portion of the wall is preferably between 200 and 1400 m3 / m2 / hour at a static pressure of 120 Pa, more preferably between 400 and 1200 m3 / m2 / hour, and even more preferably between 600 - 1000 m3 / m2 / hour. This air permeability of the outflow portion of the wall of the guide channel of, for example, 200, 300, 400, 500, 600, 700, 800, 900, 1000, 1100, 1200, 1300, 1440 6 m3 / m2 / hour at a static pressure of 120 Pa has proved to be very suitable for realizing a comfort-increasing device, in particular for realizing the aforementioned outflow velocities of the air of the air stream that flows out of the outflow portion of the guide channel.

In a further favorable embodiment of the device according to the invention, the air permeability of the rest of the wall is preferably between 10 - 80 m3 / m2 / hour at a static pressure of 120 Pa, more preferably between 15 - 70 m3 / m2 / hour, and even more preferably between 20 - 60 m3 / m2 / hour. This air permeability of the rest of the wall of the guide channel of, for example, 10, 15, 20, 25, 30, 35, 40, 45, 50, 55, 60, 65, 70 m3 / m2 / hour at a static pressure of 120 Pa has proven to be very suitable for effectively preventing condensation on the wall of the guide channel.

The invention also relates to a method for supplying a cooled air flow to at least one location to be cooled with a device described above.

In a favorable embodiment of the method according to the invention, it comprises the step of placing the outflow portion 25 of the wall of the air-permeable guide channel above the at least one location.

The present invention will be explained in more detail below with reference to exemplary embodiments, which are shown in the accompanying figures. These are non-limitative exemplary embodiments.

In the figures: figure 1 shows a perspective view of an embodiment of a device according to the invention; 7 - figure 2 shows a perspective view of an alternative embodiment of the device of figure 1; figure 3 shows a perspective view of the application of the device of figure 2 for supplying a cooled air flow to a workplace to be cooled; figure 4 shows a schematic representation of the operation of an embodiment of the device according to the invention; and: figures 5a and 5b show a schematic cross-sectional view of an embodiment of the guide channel of the device of figure 4; and - figures 6a and 6b show a schematic cross-sectional view of an alternative embodiment of the guide channel of figures 5a and 5b.

Figure 1 shows a device 1 for supplying an air flow to a location 2 for cooling.

The device 1 is shown a cooling unit 3 that rests on the ground surface 4 of the location 2 to be cooled. The cooling unit 3 has a suction mouth 5 and a blow-out mouth 6. Via the suction mouth 5, the cooling unit 3 draws in air from the location 2 for cooling. in the direction of arrow D. The air drawn in is then cooled by means of the cooling unit 3 and blown out via the outlet nozzle 6 as a cooled air flow into the guide channel 7. The guide channel 7 guides the cooled air flow to the location to be cooled 2. The entire wall 8 of the guide channel 7 is permeable to the cooled air flow air, so that cooled air from the cooled air flow that is led to the location 2 to be cooled flows out substantially everywhere on the wall 8 of the guide channel 7. An outflow portion 8a of the wall 8 of the guide channel 7 placed above the location 2 for cooling has a first air permeability. An 8 guide portion 8b of the wall 8 of the wall 8 of the guide channel 7 has a second air permeability. Because the air permeability of the outflow section 8a of the wall 8 of the guide channel 7 is higher than the air permeability of the guide section 8b of the wall 8 of the guide channel 7, the cooled air of the cooled air stream becomes mainly along the guide section 8b of the wall 8 conducts and flows the cooled air from the cooled air stream mainly at the outflow portion 8a of the wall 8. The cooled air flowing out of the outflow portion 8a of the wall 8, as a result of the outflow velocity and under the influence of gravity, descends in the direction of arrow C to the location 2 to be cooled. clarified with reference to Figure 4.

Figure 1 also shows that the outflow portion 8a of the wall 8 of the guide channel 7 is placed above the location 2 to be cooled by means of a frame 9, the guide channel 7 being clamped in the frame 9 by means of a fixture 10 extending from the guide channel 7 and the frame 9. The wall 8 of the guide channel 7 is, for example, of textile. The web 10 is also, for example, of textile, so that the web 10 and the guide channel 7, for example, appear to form one whole. The device 1 can easily be moved over the ground surface 4 if desired in order to place the outflow part 8a above another location for cooling.

Figure 2 shows an alternative embodiment 30 of the device 1 of Figure 1. This device 11 is also shown with a cooling unit 3 which blows cooled air in the form of a cooled air stream into a guide channel 7 with a wall 8 with a 9 outlet section 8a and a guide section 8b. Also with this device 1, the outflow portion 8a of the wall 8 of the guide channel 7 is placed above the location 2 to be cooled by means of a frame 9, wherein the guide channel 7 is clamped in the frame 9 by means of a frame arranged between the guide channel 7 and the fixture 10 extending to the frame 9. However, in the device 1 shown in Figure 2, the frame 9 forms an arc, so that the guide channel 7 is also arcuate. Figure 3 shows the device 11 of Figure 2, wherein the outflow portion 8a of the wall 8 of the guide channel 7 is placed above an office chair 12, so that cooled air flowing out of the outflow portion 8a of the wall 8 in the direction of arrow C descends on the office chair 12.

The operation principle of a device according to the invention, including the devices 1 and 11 of Figures 1 to 3, is explained in more detail below with reference to the device 13 shown diagrammatically in Figure 4.

The device 13 is shown with a cooling unit 3.

The cooling unit 3 has a suction mouth 5 and a blow-out mouth 6. Via the suction mouth 5, the cooling unit 3 draws in air in the direction of arrow D. The sucked-in air is then cooled by means of the cooling unit 3 and via the blow-out mouth 6 as a cooled mouth airflow in the direction of arrow E blown out into the guide channel 7. The guide channel 7 guides the cooled airflow in this exemplary embodiment to two locations 2a and 2b to be cooled. The entire wall 8 of the guide channel 7 is permeable to the cooled air flow air, so that cooled air from the cooled air flow that is led to the locations to be cooled 2 flows out substantially everywhere on the wall 8 of the guide channel 7, as shown by the air flows indicated as 10 zigzag arrows F and G. An outflow portion 8a of the wall 8 of the guide channel 7 placed above each location 2a and 2b to be cooled has a first air permeability. A guide portion 8b of the wall 8 of the wall 8 of the guide channel 7 has a second air permeability. Because the air permeability of the outflow section 8a of the wall 8 of the guide channel 7 is higher than the air permeability of the guide section 8b of the wall 8 of the guide channel 7, the cooled air of the cooled air stream becomes mainly along the guide section 8b of the wall 8, so that relatively little air of the cooled air stream flows through the guide portion 8b of the wall 8 (indicated by the relatively short zigzag arrows F), and the cooled air of the cooled air stream flows mainly at the locations to be cooled above the locations to be cooled 2a and 2b, the outflow portion 8a of the wall 8 exits (indicated by the relatively long zigzag arrows G). Because substantially the entire wall 8 is permeable to the cooled air from the cooled air stream blown into the guide channel 7, the relatively warm air in the environment 14 of the wall 8 of the guide channel 7 is kept away, so that this relatively warm ambient air cannot condense against the wall 8 of the guide channel 7.

The cooled air flowing out of the outflow portion 8a of the wall 8, due to the outflow velocity and under the influence of gravity, descends in the direction of arrow C to the locations 2a and 2b to be cooled and collects on the ground surface 15, such as 30 indicated by hatch H. Because the suction mouth 5 of the cooling unit 3 is placed under the outflow portion 8a of the wall 8, or downstream of the cooled air flowing out of this outflow portion 8a (zigzag 11 arrows G), the collected and meanwhile somewhat warmed up air again sucked in through the suction nozzle 5 in the direction of arrow D by the cooling unit 3 and cooled again.

As shown in Figure 4, the outflow portion 8a is placed at a distance I above the ground surface of the locations 2a and 2b to be cooled.

Figure 4 shows that the device 13 supplies cooled air to two locations to be cooled.

Alternatively, the device according to the invention can supply cooled air to one or more than two locations to be cooled.

Figures 5a and 5b show a diagrammatic cross-sectional view of an embodiment of the guide channel 7 of the device 13 of Figure 4. Figure 5a shows a cross section at the sections A of the guide channel 7 of figure 4. Figure 5b shows a cross section at the sections B of the guide channel 7 of figure 4. Figures 5a and 5b show that the guide channel 7 is clamped in the frame 9 by means of a fixture 10 extending between the guide channel 7 and the frame 9. The fixture 10 has a substantially airtight portion 10a extending from the wall 8 of the guide channel 7 over a distance J extends in the direction of the frame 9. Figure 5a shows that the wall 8 of the guide channel 7 at the location of section A is entirely formed by the guide part 8a of the wall 8, so that in section A relatively little air of the cooled air flow through the guide part 8b of the wall 8 flows (indicated by the relatively short zigzag arrows F). Figure 5b shows that at sections B of the guide channel 7 the upper part of the wall 12 is formed by the guide part 8b of the wall 8, while the lower part of the wall 8 is formed by the outflow part 8a of the wall 8 of guide channel 7, so that relatively little air from the cooled air stream flows through the guide portion 8b of the wall 8 from the upper portion 5 of the wall 8 (indicated by the relatively short zigzag arrows F) and that from the lower portion of the wall 8 flows relatively much air from the cooled air flow through the guide portion 8a of the wall 8 (indicated by the relatively long zigzag arrows G). Figures 5a and 5b also show that the substantially airtight part 10a of the fixture 10 prevents relatively hot air from the environment 14 in the direction of arrow K 15 from being entrained with the cooled air flowing out of the outflow part 8a of the wall 8 air. Figure 5b also shows that a part of the cooled air flowing out of the outflow part 8a (indicated by the relatively long zigzag arrows G) is deflected under the influence of gravity.

Figures 6a and 6b show a cross-sectional schematic representation of an alternative embodiment of the guide channel of Figures 5a and 5b. In this alternative embodiment, the cross-section of the guide channel has a semi-circular shape instead of a circular shape as in the embodiment as shown in Figs. 5a and 5b.

The cross-section of the guide channel 7 of figures 5a, 5b, 6a, and 6b can also have a different shape, such as square, rectangular, triangular, etc.

The light-tight portion of the fixture 10 of Figs. 5a, 5b, 6a and 6b can also extend over only a portion of the distance J from the wall 8 towards the frame 9.

Claims (11)

Device for supplying a cooled air flow to at least one location to be cooled, comprising: - a cooling unit for generating a cooled air flow; and - a guide channel for guiding the cooled air flow from the cooling unit to the at least one location to be cooled; - wherein substantially the entire wall of the guide channel is permeable to the air from cooled air flow; - wherein an outflow portion of the wall of the guide channel has a first air permeability; - wherein a guide portion of the wall has a second air permeability; - wherein the outflow part of the wall can be placed near the at least one location to be cooled; 20. wherein the air permeability of the outflow portion of the wall is higher than the air permeability of the guide portion of the wall; - wherein the outflow part of the wall of the guide channel can be placed above the at least one location to be cooled; - wherein the device also comprises a frame with which the outflow part of the wall of the guide channel can be placed above the at least one location to be cooled; and 30. wherein the guide channel is tensioned in the frame by means of a clamp extending between the guide channel and the frame. Device as claimed in any of the foregoing claims, wherein the temperature of the cooled air flow is at least 2 ° C lower than the temperature of the ambient air. 5 3. Device as claimed in claim 1 or 2, wherein the outflow part of the wall of the guide channel at a distance of preferably between 100-300 cm, more preferably between 150-250 cm, and even more preferably substantially 200 cm above the at least one location to be cooled can be placed. 4. Device as claimed in any of the foregoing claims, wherein the fixture has a substantially airtight part which extends from the wall of the guide channel over a distance of preferably at least 10 cm, more preferably at least 20 cm, and even more preferably extends at least 30 cm in the direction of the frame. 20 5. Device as claimed in any of the foregoing claims, wherein the cooling unit comprises a suction mouth for sucking in an air flow to be cooled, which suction mouth can be placed under the outflow portion of the wall of the guide channel. Device as claimed in any of the foregoing claims, wherein the wall of the guide channel is of textile. 30 Device as claimed in any of the foregoing claims, wherein the air outflow rate of the cooled air flow from the outflow portion of the wall of the guide channel is preferably between 0.04 - 0.12 m / s 5, more preferably between 0 .06 is 0.10 m / s, and even more preferably is essentially 0.08 m / s. 8. Device as claimed in any of the foregoing claims, wherein the air permeability of the outflow part of the wall is preferably between 200 - 1400 m3 / m2 / hour at a static pressure of 120Pa, more preferably between 400 - 1200 m3 / m2 / hour , and even more preferably between 600 - 1000 m3 / m2 / hour. Device as claimed in any of the foregoing claims, wherein the air permeability of the guide part of the wall is preferably between 10 - 80 m3 / m2 / hour at a static pressure of 120 Pa, more preferably between 15 - 70 m3 / m2 / hour, and even more preferably between 20 - 60 m3 / m2 / hour. A method for supplying an air flow to at least one location with a device according to any one of claims 1-9. 25 A method according to claim 10, comprising the step of placing the outflow portion of the wall of the air permeable guide channel above the at least one location to be cooled.