DE102016009598A1 - Ventilation unit of building technology with a measuring unit - Google Patents

Abstract

The invention relates to a ventilation device (100) of building technology, in which a fan unit (800) with a measuring unit (500) is arranged. The measuring unit (500) has a pressure difference measuring device (505) which is connected to a first air-carrying line (501) and a second air-carrying line (502). The first air-carrying line (501) and the second air-carrying line (502) are arranged at a different distance from an inflow opening (805) of a fan (803) on the fan unit (800), wherein the first air-carrying line (501) a greater distance (T) to the inflow port (805) than the second air-carrying conduit (502). The first air-carrying line (501) is arranged with its air inflow opening (503) in a predominantly tangential orientation to the inflow opening (805) of the fan (803) in a calmed zone (804) on the fan unit (800). The second air-carrying line (502) is arranged with its opening (504) at a close distance tangential to the inflow opening (805) of the fan (803) on the fan unit (800).

Description

The invention relates to a ventilation device of building services with a fan unit having measuring unit for measuring an air flow within the ventilation unit

Air movement systems or ventilation devices, in particular fan units, for the ventilation of rooms that have a fan and a measuring device are known in the market. Such fan units are used to regulate the amount of air to be transported and to provide for a certain minimum air flow rate. This is important to avoid contamination of the air within a building and to ensure that the temperature and / or humidity are not too far away from the acceptable target values.

On the air control of the room, the arrangement of the measuring unit to the inlet opening of the fan has influence. So it is said in the EP 2 357 365 A2 in that the measuring device of the fan unit consists of two differently oriented measuring tubes. A first measuring tube, referred to as a first pressure tap, is arranged tangentially to the fan at the end of the inlet opening. In contrast, the second measuring tube, referred to as a second pressure tap, is located at a distance radially to the inlet opening of the fan. Furthermore, the second measuring tube in the plane of the front side of the fan unit, spaced, ie remote to the front side of the fan unit, arranged in a very different plane than the first measuring tube, which rests with its opening directly on the housing wall, close to the rotor blades of the backward curved fan ,

In the US 5 586 861 A is also called a fan unit with a measuring device that detects the slightest changes in the air flow. In this case, measuring tubes are provided at various points within the inlet opening, which measure the static pressure. Thus, the pressure measurement takes place on the one hand on the expanded inlet opening with the largest diameter and on the other hand on the slightly inner narrowing with the smallest diameter. The detection of the pressure thus takes place in different planes of the inflow opening.

The object of the invention is to improve the air quality and comfort in one of a ventilation device of the building services, in particular a fan unit ventilated space. In addition, the control behavior of the transported air volume should be improved and compliance with the setpoint air quantity must be ensured.

The achievement of the object according to the invention is specified in claim 1. The subclaims relate to advantageous further embodiments of the invention.

The ventilation device of domestic technology advantageously has a fan unit with a measuring unit. The measuring unit consists of a pressure difference measuring device, which is connected to a first air-carrying line and a second air-carrying line.

Advantageously, the first air-carrying line and the second air-carrying line are arranged at a different distance from an inlet opening of a fan on the fan unit. Advantageously, the first air-conducting line has a greater distance from the inlet opening than the second air-conveying line.

An advantageous idea of the invention is to arrange the first air-conducting line with its air-inflowing opening in a predominantly tangential orientation to the inlet opening of the fan. In particular, the first air-conducting line is to be arranged on a front side of the fan unit in a calmed zone on the fan unit. Advantageously, the first air-carrying line is mounted at a distance from the inlet opening in a calmed zone. This distance corresponds to the distance between a circular tangent which bears against the inflow opening circle and a straight line running through the first air-carrying line and running parallel to the circular tangent. The straight line passing through the first air-bearing line is referred to as an inflow port tangent. It runs at 90 degrees to the inflow opening circle.

In a particularly advantageous embodiment, the distance from the inflow opening to the inflow opening is 0.2 times to 0.7 times the width of the fan unit, in particular very roughly 0.4 times the width of the fan unit. If another embodiment proves to be more advantageous, the distance may deviate from the measure given here.

It is predominantly tangential that the first air-conducting line is not radially aligned with the inflow opening in the calmed zone.

In an advantageous embodiment, an angle exists between the first air-carrying line and the Einströmöffnungstangente, which is greater than or equal to 0 degrees and less than 45 degrees. In particular, the angle is between 0 degrees and 40 degrees. In a further preferred embodiment, the angle is roughly 25 degrees. If the angle is 0 degrees, the first air-conveying line is arranged exactly tangential to the inlet opening.

Whether the first air-conveying line is advantageously arranged on the left-hand side in the upper corner in the calmed zone or is advantageously arranged on the right-hand side in the upper right-hand corner in a calmed zone depends on the individual case of the application. The tangency or the predominantly tangential arrangement is met in any advantageous embodiment.

Advantageously, the second air-carrying line is arranged with its opening at a close distance tangential to the inlet opening of the fan on the fan unit. Advantageously, the second air-conducting line is positioned with its opening on the end face of the fan unit at a close distance tangential to the inflow opening in a living zone below the inflow opening and the center centrally to an axis of the fan. In a particularly advantageous embodiment, the distance from the second air-carrying line to the inlet opening is between 1 mm and 8 cm, in particular between 0.5 cm and 5 cm. Particularly advantageously, the distance from the second air-carrying line to the inlet opening is very roughly 2 cm.

Advantageously, the first air-carrying line and the second air-carrying line partially or entirely made of metal or plastic.

To determine the flowing air quantity of an air flow, the pressure difference measuring device generates a signal. The signal is a pressure difference between a static pressure present at the first air-conveying line and a dynamic pressure prevailing at the second air-conveying line.

Due to the different pressure conditions creates an air flow within the first air-carrying line and the second air-carrying line. Thus, during operation of the ventilation device, air flows upstream into the first air-carrying line, where a higher pressure prevails, and flows out again from the second air-conveying line, where a low pressure prevails.

Advantageously, the pressure difference measuring device is arranged at one point, in particular in the interior of the fan unit. This arrangement is advantageous because the pressure difference measuring device is shielded from the upstream air guide space and the air streams flowing therein. The pressure difference measuring device is arranged in the interior of the fan unit, in particular on the housing of the fan unit, on a fastening device. In an advantageous embodiment, the pressure difference measuring device connected to the fastening device is easily accessible.

Furthermore, at least one fastening device for fastening the pressure difference measuring device is advantageously provided in the interior of the fan unit. Advantageously, the fan unit has two fastening devices in order to use the fan unit both as a supply air fan and as an exhaust fan. As a result, either one fastening device for the supply air fan or the other fastening device for the exhaust fan can be used.

Another advantageous idea of the invention is that the housing of the fan unit consists of a thermoseal cast (TSG).

In a further aspect of the invention, the ventilation device has a homogenizing device. The homogenizing device advantageously serves to equalize an air flow conveyed by a fan. Advantageously, the equalization device is arranged at a distance from the fan unit. In a particularly advantageous embodiment, the homogenizing device for the fan unit is located at a distance in an air guiding space.

The homogenizing device is designed as a perforated plate. Advantageously, the perforated plate has a breadboard with a bore diameter of 5 mm and a bore spacing of 8 mm. In a further embodiment of the homogenizing device, the holes can also be present as triangles or combined geometries with different dimensions.

Furthermore, the homogenizing device is arranged predominantly parallel to an end face of the housing of the fan unit or to a first wall in the air guiding space. Advantageously, the distance between the end face of the housing and the equalizing device is 0.2 to 0.7 times the dimension of the diameter of the inlet opening of the fan housing, in particular the angle is 0.2 to 0.5 times the dimension. In a preferred embodiment, the angle is roughly 0.36 times the diameter of the inlet opening of the fan housing.

An embodiment of the invention will be explained in more detail below with reference to the drawings. It shows:

1 the ventilation device of the building services with two fan units and with a spaced apart homogenizer in the front perspective view;

2a the fan unit according to 1 with two air-conducting lines of the measuring unit in the perspective front view;

2 B a schematic representation of the fan unit according to 2a with a staggered arrangement of the two air ducts in the front view;

3a . 3b two schematic representations of the fan unit according to 1 with two different orientations of the first air duct in front view;

4 a section of the fan unit and the equalization device according to 1 in a perspective view;

5 a schematic representation of the equalization device in the front view according to 1 ;

6 a schematic representation of the fan unit and the equalization device in the side view according to 1 ,

The 1 shows a ventilation unit ( 100 ) of building services, consisting of a housing ( 101 ), with two fan units ( 801 . 802 ), each one measuring unit ( 500 ) exhibit. A first fan unit ( 801 ) is in the upper left corner of the ventilation unit ( 100 ) and a second fan unit ( 802 ) is in the lower right corner of the ventilation unit ( 100 ) on the housing ( 101 ) of the ventilation unit ( 100 ) arranged. Furthermore, in the exemplary embodiment, one for the first fan unit ( 801 ) spaced equalization device ( 880 ) in an air guidance space ( 870 ) arranged to equalize a sucked air stream ( 820 ) serves.

In the ventilation unit ( 100 ) is a heat exchanger ( 300 ) on the left wall of the housing ( 101 ) below the first fan unit ( 801 ) arranged. A bypass ( 890 ) is located above the heat exchanger ( 300 ) and on the right side of the first fan unit ( 801 ) spaced equalization device ( 880 ). To guide the air flow ( 820 ) from the outside into a room to be ventilated are at least two air ducts in the ventilation unit ( 100 ) intended. In this case, the outside air via an outside air duct ( 811 ) into the ventilation unit ( 100 ) and then via a supply air duct ( 812 ) transported in the room to be ventilated. In the embodiment, four air channels are provided, an outside air duct ( 811 ), a supply air duct ( 812 ), an exhaust duct ( 813 ) and an exhaust air duct ( 814 ).

Furthermore, the fan unit ( 801 ), as in 2a shown with a measuring unit ( 500 ), which has a first air-carrying line ( 501 ) with an air inflow opening ( 503 ) and a second air-conveying line ( 502 ) with an opening ( 504 ) having. Advantageously, the first air-carrying line ( 501 ) upstream in a calm zone ( 804 ), away from the inlet ( 805 ) of a fan ( 803 ) with backward curved rotor blades, in the upper left corner on the front side ( 811 ) of the housing ( 810 ) of the fan unit ( 801 ) arranged. The first airline ( 501 ) is also in a predominantly tangential orientation to the inlet opening ( 805 ) of the fan ( 803 ) appropriate.

Advantageously, the second air-carrying line ( 502 ) with its opening ( 504 ) at a close distance tangential to the inlet opening ( 805 ) of the fan ( 803 ) on the fan unit ( 801 ) arranged. Advantageously, the second air-carrying line ( 502 ) with its opening ( 504 ) on the front side ( 811 ) of the fan unit ( 801 ) at a close distance tangential to the inlet opening ( 805 ) in a busy zone ( 808 ) below the inlet opening ( 805 ) and the center (M) central to an axis (A) of the fan ( 803 ). In a particularly advantageous embodiment, the distance (D) from the second air-carrying line ( 502 ) to the inflow opening ( 805 ) between 1 mm and 8 cm, in particular between 0.5 cm and 5 cm. Particularly advantageously, the distance (D) from the second air-carrying line ( 502 ) to the inflow opening ( 805 very roughly 2 cm.

For fixing the first air-carrying line ( 501 ) and / or the second air-conveying line ( 502 ) on the fan unit ( 801 ) fasteners ( 999 ). As fastening elements ( 999 ) can terminals, brackets, grommets, hooks, snapper or other commercially available holding elements are used.

In a further advantageous embodiment, as in 2 B shown, is the first air-bearing line ( 501 ) in the upper right corner of the fan unit ( 801 ) in the calm zone ( 804 ) on the front side ( 811 ) of the housing ( 810 ). In this proposed advantageous embodiment, the second air-carrying line ( 502 ) mirrored to the inlet opening ( 805 ) of the fan ( 803 ) in the busy zone ( 808 ) arranged. This version corresponds functionally to the in 2a illustrated advantageous embodiment, but with the difference that the first air-conducting line ( 501 ) and the second air-carrying line ( 502 ) not on the left side, but on the right side of the inflow opening ( 805 ) are positioned.

According to the invention, the first air-conveying line ( 501 ) in tangential orientation on the front side ( 811 ) of the fan housing ( 810 ) arranged. It is furthermore advantageous that the first air-conveying line ( 501 ) predominantly tangential to the inflow opening ( 805 ) of the fan ( 803 ) is arranged.

In one or more further embodiments of the invention, as in 3a , and 3b shown, is the first air duct ( 501 ) in different tangential orientations to the inlet opening ( 805 ) of the fan ( 803 ). 3a . 3b . 2a and 2 B differ in which angle (α) the first air-conducting line ( 501 ) to an inflow port tangent ( 900 ) runs. The inflow port tangent ( 900 ) is a tangential, at 90 degrees to the inflow opening circle ( 807 ) through the first air-carrying line ( 501 ) straight line.

In an advantageous embodiment, an angle (α) between the first air-conveying line ( 501 ) and the inflow port tangent ( 900 ) in about 35 degrees. In another advantageous embodiment, the angle (α) is between 0 degrees and 50 degrees, wherein an angle (α) of 0 degrees to the embodiment in 3a equivalent. In this case, the first air-conducting line ( 501 ) exactly tangential to the inflow opening ( 805 ) is arranged.

Further advantageous is the first air-carrying line ( 501 ) at a distance (T) to the inlet opening ( 805 ) in a calm zone ( 804 ) appropriate. This distance (T) corresponds to the distance between a circular tangent which is at the inflow opening circle ( 807 ) and that through the first air-carrying line ( 501 ) extending parallel to the circular tangent Einströmöffnungstangente ( 900 ).

In a particularly advantageous embodiment, the distance (T) from the Einströmöffnungstangente ( 900 ) to the inflow opening ( 805 ) 0.2 times to 0.7 times the width (b) of the fan unit ( 801 ), in particular very roughly 0.4 times the width (b) of the fan unit ( 801 ). If another embodiment proves to be more advantageous, the distance (T) may deviate from the dimension given here.

Due to the advantageous arrangement of the first air-conveying line ( 501 ) in the calm zone ( 804 ) of the fan unit ( 801 ) and the second air-conveying line ( 502 ) near the inlet ( 805 ) of the fan ( 803 ) in the busy zone ( 808 ) results in a pressure difference (D1 - D2). This pressure difference results from the first air-carrying line ( 501 ) prevailing higher pressure (D1) and on the second air-carrying line ( 502 ) existing lower pressure (D2).

For determining the pressure difference (D1 - D2) and for determining the flowing air quantity of an air flow ( 820 ) serves a pressure difference measuring device ( 505 ), which generates a signal. In the embodiment in 4 such a pressure difference measuring device is shown. According to the invention, the pressure difference measuring device ( 505 ) advantageous with the first air-carrying line ( 501 ) and the second air-conveying line ( 502 ) connected.

Advantageously, the pressure difference measuring device ( 505 ) in one place, especially in the interior ( 813 ) of the fan unit ( 801 ) arranged. This arrangement is advantageous because the pressure difference measuring device ( 505 ) so from the upstream air duct space ( 870 ) and the air streams flowing in ( 820 ) is shielded. The pressure difference measuring device ( 505 ) is in the interior ( 813 ) of the fan unit ( 801 ), in particular on the housing ( 810 ) of the fan unit ( 801 ) on a fastening device ( 520 ) arranged. In an advantageous embodiment, the with the fastening device ( 520 ) connected pressure difference measuring device ( 505 ) easily accessible.

Furthermore, it is advantageous in the interior ( 813 ) of the fan unit ( 801 ) at least one fastening device ( 520 ) is provided for fixing the pressure difference measuring device. Advantageously, the fan unit has two fastening devices ( 520 ) to the fan unit ( 801 ) to be used both as a supply air fan and as an exhaust fan. As a result, either the one fastening device ( 520 ) for the supply air fan or the other fastening device for the exhaust fan.

Another advantageous idea of the invention is that the housing ( 810 ) of the fan unit ( 801 ) consists of a thermal injection molding (TSG).

Further advantageous, as in particular in 2a . 2 B . 3a and 3b shown on the front ( 811 ) of the fan unit ( 801 ) arranged first and second air-conducting line ( 501 . 502 ) Different tube lengths. The pipe section (I1) of the first air-conveying line ( 501 ) corresponds advantageously in about one fifth of the length of the pipe section (I2) of the second air-carrying line ( 502 ). In another preferred embodiment, the ratio I1 to I2 a measure between 0.05 to 0.6, in particular between 0.1 and 0.4.

Also advantageous is the equalization device ( 880 ), as in 5 and 6 shown, designed as a perforated plate. Further advantageous is the equalization device ( 880 ), as in 4 shown with at least one fastening device ( 898 ) on a first wall ( 871 ) and a second wall ( 872 ) in the air guidance space ( 870 ) of the ventilation unit ( 100 ) attached.

Furthermore, the perforated plate ( 880 ) from a breadboard, in particular with round holes ( 264 ), as in 5 is shown. The bore diameter (d) is advantageously between 0.5 mm and 15 mm, in particular between 2 mm and 8 mm. In an advantageous embodiment, the bore diameter (d) is very roughly 5 mm. The hole spacing (a) advantageously entered between 2 mm and 15 mm, in particular between 4 mm and 10 mm. In an advantageous embodiment, the bore spacing (a) is very roughly 8 mm.

In a further embodiment of the homogenizing device ( 880 ) are the holes ( 264 ) as slits, triangles or combined with different dimensions.

Furthermore advantageous, as in 4 and 6 the equalization device ( 880 ) predominantly parallel to a front side ( 811 ) of the housing ( 810 ) of the fan unit ( 801 ) arranged. A further aspect of the invention is an equalization device ( 880 ) to even out a fan ( 803 ) transported air stream ( 820 ) spaced from the fan unit ( 801 ) in an air guidance space ( 870 ), as in 4 is shown. Advantageously, the distance (f) between the end face ( 811 ) of the housing ( 810 ) and the equalization device ( 880 ) between 0.1 and 0.9 times, in particular between 0.1 and 0.5 times the diameter (g) of the inflow opening ( 805 ) of the fan housing ( 810 ). In a particularly preferred embodiment, the distance (f) is roughly 0.3 to 0.4 times the dimension ( 6 ).

The second air-carrying line ( 502 ) of the measuring unit ( 500 ) is in the embodiment, as in 2a . 2 B . 3a and 3b shown, advantageously in the close distance (D) to the inlet opening ( 805 ) of the fan ( 803 ) arranged. Furthermore advantageously, the second air-carrying line ( 502 ) directly on the front side ( 811 ) of the fan unit ( 801

In a particularly advantageous embodiment, the second air-carrying line ( 502 ) with its opening ( 504 ) at a distance (D) to the inlet opening ( 805 ), as in 6 shown. Preferably, the distance (D) from the second air-carrying line ( 502 ) to the inflow opening ( 805 ) between 1 mm and 8 cm, in particular between 0.5 cm and 5 cm. Particularly advantageously, the distance (D) from the second air-carrying line ( 502 ) to the inflow opening ( 805 very roughly 2 cm.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• EP 2357365 A2 [0003]
• US 5586861 A [0004]

Claims (10)

Ventilation unit ( 100 ) of the building services engineering, comprising at least one fan unit ( 800 ), one in the fan unit ( 800 ) arranged measuring unit ( 500 ) with a pressure difference measuring device ( 505 ), which are connected to a first air-conveying line ( 501 ), a second air-carrying line ( 502 ), the first air-conveying line ( 501 ) and the second air-carrying line ( 502 ) at a different distance to an inlet opening ( 805 ) of a fan ( 803 ) are arranged, wherein the first air-conducting line ( 501 ) a greater distance (T) to the inlet opening ( 805 ) than the second air-conveying line ( 502 ), characterized in that the first air-conveying line ( 501 ) with its air inflow opening ( 503 ) in a predominantly tangential orientation to the inflow opening ( 805 ) of the fan ( 803 ) in a calm zone ( 804 ) on the fan unit ( 800 ) is arranged and the second air-carrying line ( 502 ) with its opening ( 504 ) at a close distance tangential to the inlet opening ( 805 ) of the fan ( 803 ) on the fan unit ( 800 ) is arranged. Ventilation unit ( 100 ) of the building services according to claim 1, characterized in that the first air-carrying line ( 501 ) with its air inflow opening ( 503 ) on a front side ( 811 ) of the fan unit ( 800 ) at a distance (T) predominantly tangential to the inflow opening in a calmed zone ( 804 ) is arranged. Ventilation unit ( 100 ) of the building services according to claim 1 and 2, characterized in that the distance (T) from the first air-carrying line ( 501 ) to the inflow opening ( 805 ) about 0.2 to 0.7 times the width of the fan unit (b) ( 800 ), in particular very roughly 0.4 times the width (b) of the fan unit ( 800 ) is. Ventilation unit ( 100 ) of the building services according to claim 1, characterized in that the second air-carrying line ( 502 ) with its opening ( 504 ) on the front side ( 811 ) of the fan unit ( 800 ) at a close distance (D) tangential to the inflow opening ( 805 ), in a busy zone ( 808 ), below the inflow opening ( 805 ), central to an axis (A) of the fan ( 803 ) is positioned. Ventilation unit ( 100 ) of the building services according to claim 1 and 4, characterized in that the distance (D) from the second air-carrying line ( 502 ) to the inflow opening ( 805 ) between 1 mm and 8 cm, in particular between 0.5 cm and 5 cm, in a particularly advantageous embodiment is very roughly 2 cm. Ventilation unit ( 100 ) of the building services according to one of the preceding claims, characterized in that the pressure difference measuring device ( 505 ) for determining the flowing air quantity of an air stream ( 820 ) used signal generated. Ventilation unit ( 100 ) of the building equipment according to claim 1, characterized in that the ventilation device ( 100 ) a homogenizing device ( 880 ), the equalization device ( 880 ) to even out a fan ( 803 ) transported air stream ( 820 ) spaced from the fan unit ( 800 ) is arranged. Ventilation unit ( 100 ) of the building services according to claim 6, characterized in that the homogenizing device ( 880 ) is designed as a perforated plate, wherein the perforated plate has a breadboard with a hole diameter (d) of 5 mm and hole spacing (a) of 8 mm. Ventilation unit ( 100 ) Of the home automation according to claim 6, characterized in that the smoothing device ( 880 ) predominantly parallel to a front side ( 811 ) of a housing ( 810 ) of the fan unit ( 800 ) or to a first wall ( 871 ) in the air duct ( 870 ) is arranged. Ventilation unit ( 100 ) of the building services according to claim 6, characterized in that the distance (f) between the end face ( 811 ) of the housing ( 810 ) and the equalization device ( 880 ) about 0.1 times to 0.5 times the measure of the diameter (g) of the inflow opening ( 805 ) of the fan housing ( 810 ) is, in particular very roughly 0.3 to 0.4 times the measure.

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