BE1011773A3 - Improved device for setting the movable the state of a fan grille. - Google Patents

Abstract

Improved device for adjusting the position of the movable part of a ventilation grille, characterized in that in the ventilation grille (1) a channel (14) is provided which connects the outside of the ventilation grille (1) to the inside thereof and wherein in this channel (14) at least one sensor (15) is arranged which communicates with a processing unit (17) which itself communicates with a first switch controlling the power supply of the sensor (15), on the one hand, and with a switch (18 ) which controls the power supply of a drive motor (13) of the movable part or drum (4) of the ventilation grille, on the other hand.

Description

       

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  Improved device for adjusting the position of the movable part of a ventilation grille.



  The present invention relates to an improved device for adjusting or regulating, respectively, the position of the movable part, a ventilation grille, more specifically a device that allows automatic adjustment of such a ventilation grille, a. W. set the position of this ventilation grille to automatically determine the amount of flow air.



  Such a device is the object of the Belgian patent no. 1003867 of the Applicant, in which protection is mainly claimed for a device in which two sensors are placed in the through-flow opening of the ventilation grille, a first sensor of which measures the temperature of the through-air and passes this value on to a processing unit, and the second sensor of which is brought to and maintained at a temperature higher than the temperature of the first sensor and wherein the power required to maintain the second sensor at the higher temperature is also communicated to the aforementioned processing unit in order to control the power supply of the sensor's heating unit;

   and on the movable part defining the through-flow opening of the ventilation grille, driving means for this movable part, the power supply of which is also controlled by the aforementioned processing unit.



  Although such a device gives very good results according to the aforementioned Belgian patent no. 1003867, it has been found that this known device has certain drawbacks.

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 Indeed, the aforementioned sensors in this known device are arranged in the actual through-flow opening of the ventilation grille, whereby various drawbacks can arise.



  A first drawback is that, because these sensors are placed in the flow-through opening, measurement is no longer possible when the moving part of the ventilation grille closes off the flow-through opening, a. W. when the ventilation grille is closed.



  Another drawback of this arrangement of the sensors in the flow-through opening is that these sensors get dirty relatively quickly, which is also disadvantageous for a correct measurement.



  Yet another disadvantage of this arrangement of the sensors is that they can be easily touched when cleaning the ventilation grille or the like, either being bent or damaged.



  Another drawback of the aforementioned sensor arrangement is that insects or the like can come into contact with the heated sensor, as a result of which such insects or the like will burn and stick to the sensor, which will again result in an incorrect measurement.



  The object of the present invention is an improved device which excludes the aforementioned and other drawbacks of the known device.



  Initially, the current improvements therefore consist of removing the sensors from the aforementioned flow opening of the ventilation grille in order to

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 be positioned so that they cannot normally be touched when cleaning the ventilation grille; that they get dirty less quickly; that insects or the like cannot come into contact with it and that they always allow the same measurement regardless of the position of the movable part of the ventilation grille.



  According to a second feature of the present invention, one will use either a single sensor which alternately measures the temperature and air velocity of the flow air, or two sensors one of which measures the temperature of the flow air and the other the speed of the flow air.



  The improved device according to the invention, which exhibits the aforementioned and other advantages, mainly consists for this purpose of a ventilation grille provided with a channel connecting the outside of the ventilation grille to the inside thereof and in which at least one sensor is arranged which is connected with a processing unit which itself communicates with a first switch that controls the power supply of the sensor, on the one hand, and with a switch that controls the power supply of a drive motor of the movable part or drum of the ventilation grille, on the other hand.



  With the insight to better demonstrate the features according to the invention, a preferred embodiment is described below, by way of example without any limiting character, with reference to the accompanying drawings, in which:
Figure 1 shows a schematic cross section of a

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 rotary ventilation grille equipped with an improved device according to the invention; figure 2 shows on a larger scale the part indicated by F2 in figure 1; figure 3 represents a schematic view according to arrow
F3 in Figure 1; Figures 4 and 5 are views similar to that of Figure 1, but for embodiment variants.



  In the aforementioned figures, a rotary ventilation grille 1 is schematically shown, which, in the illustrated embodiment, mainly consists of profiles 2-3 in which a movable part 4 is rotatably arranged in the form of a drum.



  The movable part or drum 4 is arranged in airtight manner in the profiles 2 and 3 by means of brushes or the like 5 and is formed, for example, by two shells 6-7 which are connected at their free ends, for example by means of discs 8 -9 and wherein, for example, a mesh 10 is provided between the shells 6 and 7.



  In the position as shown in figure 1, the rotary ventilation grille is in the open position, the through-flow opening S being maximum and equal to B x L.



  It is sufficient to turn the movable part or drum 4 to partially or completely close the flow opening.



  The disks 8 and 9 can each be mounted on a shaft, 11 and 12, respectively, which are located in the aforementioned profiles 2

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 and 3 are bearing-mounted, and a drive motor 13 is connected to one of these shafts 11.



  According to the invention, a channel 14 is provided between the outside and the inside of the ventilation grille 1, which channel directly connects the outside air to the room to be ventilated and in which measurements 14 are carried out in this channel to allow the flow opening S to be regulated namely the measurement of the air velocity and the measurement of the temperature of the air flowing through the channel 14.



  It is clear that the speed of the air through the channel 14 is representative of the air speed through the actual ventilation grille and that the temperature of the air in the channel 14 will always be equal to the temperature of the air in the ventilation grille.



  The aforementioned measurements are carried out in the example of Figures 1 to 3 by means of a sensor 15 which is arranged in the channel 14, this sensor 15 being formed by an electrical resistor connected via a switch 16 to a suitable current source .



  This sensor 15 will measure the air velocity flowing through the channel 14 and pass this value on to the processing unit 17.



  In this case, an accurately known amount of electric current is sent through the sensor 15 by means of the above-mentioned processing unit 17, whereby the sensor 15 heats up to, for example, a temperature of 100 ° C above the temperature of the air flowing through the channel 14.

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  Due to the very small inherent mass of the sensor 15, only little energy is required for this and this high temperature does not pose any danger.



  As a result of the air flow, the sensor 15 will be cooled, such that the exact temperature of the sensor 15 is a function of the air flow flowing through the channel 14.



  From the actual temperature that the sensor 15 has and the known temperature without air flow, the processing unit 17 will then calculate the air flow through the ventilation grille 1 and then displace the movable part or drum 4, by controlling it via the switch 18 of the motor 13. that the desired air flow through the ventilation grille 1 is obtained.



  In the embodiment according to figure 4, the sensor 15 is designed and connected to the processing unit 17 in such a way that the temperature of the air flowing through the channel 14 is alternately measured and the speed of this air.



  The signals from the sensor 15 will be supplied to a processing unit 17 which acts on the switch 16, through which the aforesaid electrical resistance is brought to a desired temperature.



  It is noted that the ventilation grille can always be set in advance at, for example, an air speed of approximately 1.7 m / sec, which corresponds to approximately 150 m of air flow per hour.

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 The desired flow-through opening S is then calculated by the processing unit 18 with the formula
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 Q (desired air exchange or air flow) S = V (air speed or wind speed). The air exchange is indicated in m3 per hour and the wind speed in meters per hour.



  The signals thus obtained are forwarded by the processing unit 17 to the switch 18 which commands the motor 13.



  It is clear that the processing unit 17 can be programmed in such a way that from a certain temperature of the air flow passing through the opening S, the movable part or drum 4 of the ventilation grille 1 is placed in the fully open position as shown in figure 1. . This temperature could for instance be set at 30 C.



  As energy source for controlling the motor 13, on the one hand, and / or heating the aforementioned electrical resistance, on the other hand, use can be made both of mains power and of a battery, as well as of solar cells or the like.



  In the embodiment according to Figure 5, the measurements as discussed in the embodiment according to Figure 4 are carried out separately, respectively a temperature measurement with a sensor 15 and an air or wind speed measurement by means of a sensor 19, the signals coming from

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 the sensors 15 and 19 can be simultaneously fed to the processing unit 17.



  The channel 14 is schematically shown in the accompanying figures and arranged through the profiles 2 and / or 3.



  It is clear that such channel 14 can be provided in any other way, for example by forming a channel that leaves on the outside of a building at the bottom of the ventilation grille to open out into the building itself at the top of the ventilation grille, so that one obtains that such channel 14 is placed completely outside the influence of rain, snow and the like, on the one hand, and, the opening on the inside becomes completely invisible, on the other hand.



  Finally, such channel 14 can be provided either through profiles 2 and / or 3 as shown in the drawings, or be provided next to one of the disks 8 or 9.



  It is clear that the present invention is not limited to the exemplary embodiments described in the accompanying drawings, but that such improved apparatus for adjusting the position of the movable portion of a ventilation grille can be realized in various shapes and sizes. without departing from the scope of the invention.


    

Claims (11)

Conclusions.   1. - Improved device for setting the position of the movable part of a ventilation grille, characterized in that in the ventilation grille (1) a channel (14) is provided which connects the outside of the ventilation grille (1) to the inside thereof and wherein in this channel (14) at least one sensor (15) is arranged, which is connected to a processing unit (17) which itself is connected to a first switch that controls the power supply of the sensor (15), on the one hand, and with a switch (18) that controls the power supply of a drive motor (13) of the movable part or drum (4) of the ventilation grille, on the other hand.   Improved device according to claim 1, characterized in that the channel (14) passes through a profile (2) and / or (3).   Improved device according to claim 1, characterized in that the channel (14) is provided next to one of the disks (8) or (9).   Improved device according to claim 2 or 3, characterized in that the channel (14) opens at the bottom of the ventilation grille on the outside thereof and at the top.  EMI9.1  on the ventilation grille on the inside. Improved device according to any of the preceding claims, characterized in that the sensor (15) measures the temperature of the air passing through the duct (14)  <Desc / Clms Page number 10>  flows and passes this value to the processing unit (17).   Improved device according to claim 5, characterized in that the sensor (15) is formed by a resistor.   Improved device according to any one of claims 1 to 4, characterized in that the sensor (15) measures the air velocity of the air flowing through the duct (14) and passes this value on to the processing unit (17).   Improved device according to any one of claims 5 to 7, characterized in that the processing unit (17) sends an accurately known amount of electric current to the sensor (15), so that the latter heats up to, for example, a temperature of 100 degrees C above the temperature. of the air flowing through the duct (14), whereby, by this air flow, the sensor (15) will be cooled so that the exact temperature of the sensor (15) is a function of the air flow flowing through the duct (14) after which , from the actual temperature that the sensor has and the known temperature without air flow, the processing unit (17) will calculate the air flow through the ventilation grille (1) and then control the motor (13) in such a way that the movable part (4)  is moved to form a flow-through opening (S) that determines the desired amount of air flow through the ventilation grille.   Improved device according to any one of claims 1 to 7, characterized in that the sensor (15) is alternating  <Desc / Clms Page number 11>  measures the air velocity of the air flowing through the duct (14) and the temperature of this air.   Improved device according to any one of claims 1 to 7, characterized in that two sensors are provided in the channel (14), namely a first sensor (15) that measures the temperature of the air flowing through the channel (14) and a second sensor (19) that measures the speed of this air.   Improved device according to claim 9 or 10, characterized in that the sensor (15) is heated for a short time to a temperature higher than that of the air flowing through the channel (14), the sensor (15) will be cooled by the air flowing past and the power required to keep the sensor (15) at the desired temperature will be registered by the processing unit (17) which will convert this data into a signal from which the speed will be derived from the air passing through the flow opening (S).