DE20320280U1 - Radial fan for a domestic burner comprises a laminar element arranged in front of an air inlet and having in a bypass a sensor for determining a parameter of the medium flowing through the air inlet - Google Patents

Abstract

Radial fan (1) comprises a housing (2) containing a fan wheel (3), an air inlet (4), an air outlet (5), and a pressure chamber between the air inlet and air outlet. A laminar element (7) arranged in front of the air inlet has in a bypass (8) a sensor (9) for determining at least one parameter of the medium flowing through the air inlet. Preferred Features: The laminar element consists of an arrangement of flow channels (10) surrounded by an outer cylinder (11).

Description

The invention relates to a radial fan with a laminar flow element and bypass. The radial fan has a housing and an impeller located inside, an air inlet and an air outlet, being between the air inlet and the air outlet Pressure chamber is formed.

Such radial blowers are frequently with burners for the house technology used. It is particularly so with such burners when the system works on the electronic compound principle, required that the system parameters be recorded as precisely as possible, to adapt the respective control exactly to the required requirements.

Usually such furnaces are equipped with a pneumatic network, i.e. Valves are pneumatically controlled, the control pressure is provided by the pressure generation of the impeller or is tapped at a corresponding point on the air inlet. This is it is always necessary to maintain a minimum working pressure must become, to the necessary control forces applied.

This means greater power consumption for one Drive motor is required than would be necessary to only achieve the desired heating output to provide.

A major improvement will be achieved when the control is based on the principle of electronic Verbund led becomes. In the electronic network, the control commands for the respective valves no over pneumatic forces, but passed on to the valves as electrical impulses. The electrical impulses are sent from a computer unit to the valves controlled. The respective control signals depend on the power called up, and this in turn can specify a speed for the drive motor. The amount of fuel to be added is controlled depending on the air mass, the above a suitable sensor is detected. In the same way, the fuel mass, usually gas, can also be detected and taken into account be added to the quantity under computer control.

However, one problem is that Placement of the sensors for the air mass or gas quantity measurement.

The invention is based on the object centrifugal blower to specify the type mentioned, in which in less expensive Wise one if possible exact mass measurement for a subsequent needs-based control is achieved.

The object is achieved in that in front of the air intake Laminar flow element is arranged in a molded therein Bypass a sensor to record at least one parameter of the medium flowing through the air inlet having. By arranging a laminar flow element in front of the Air intake is guaranteed that the inflow quasi laminar, independent of the speed and other device parameters. The special placement of the sensor for recording a parameter of the medium flowing through the air inlet allows a largely trouble-free Capture the desired Parameter.

In an advantageous embodiment it can be provided that the laminar flow element consists of an arrangement of flow channels, that of an outer cylinder are enclosed. It can advantageously be provided that the flow channels in one Are formed insert, which is inserted in the outer cylinder, wherein the bypass is formed between the two components. To this The way is simple machining and production of the component possible.

A particularly advantageous embodiment can can be seen in that the bypass has an entry gap and a Has exit gap, each between the insert and the Outer cylinder formed are. Due to the gap between two different components it's easy to do the volume flow through the bypass in relation to the volume flow in the main flow the wished Adjust dimension. By providing a gap as an inflow for the bypass will for that Care is taken that the sensor is supplied with laminar flow, so that the most accurate Measurement results be achieved. In particular, it can be provided that the entry gap in flow connection with an inflow opening of the tongue element stands, advantageously a calming chamber behind the inlet gap to calm the air flow is provided and the sensor is arranged in a sensor channel, the over an inlet and an outlet opening with the calming chamber in flow connection stands. Through this fluidic measure becomes a maximum of reassurance for the medium to be measured is reached, which increases the quality of the measurement result even more is.

Between the laminar flow element and the air intake of the housing is an influx for another medium is formed, this inflow advantageously via the Circumference of the air inlet evenly distributed is. This measure will the best possible Mixing of the air with the combustion medium is achieved.

The further medium is advantageously via a Supply element supplied, in which also a sensor for tapping predetermined parameters is provided. This sensor is also advantageously in one Bypass arranged, which extends between an insert and an outer ring. The rest Training with calming chamber and flow connection of the bypass channel is similar designed as in connection with the bypass in the laminar flow element.

In the following the invention with reference to exemplary embodiments shown in the drawing explained in more detail.

Show it:

1 1 shows a sectional view of a schematic illustration of a part of a radial blower with housing, impeller, air inlet and supply element for further media,

2 a representation of the detail I in 1 .

3 a representation of the detail II in 1 .

4 a representation of the detail III in 1 .

5 a representation of the detail IV in 1 .

6 an alternative embodiment in section acc. 1 .

7 a representation of a section along the line AA in 6 and

8th a representation of the detail V in 6 ,

1 shows an axial section through the air inlet area of a radial fan 1 according to a first embodiment. The radial fan 1 has a housing 2 with an impeller located in it 3 on. In the schematic representation, it is essentially centrally on a side wall of the housing 2 an air intake 4 and, shown schematically, an air outlet 5 designed for the radial delivery of a mixture of media.

Between the air intake 4 and the air outlet 5 a pressure room extends 6 in which the impeller 3 increases the pressure and speed of the medium flowing through.

In the usual way is the air intake 4 provided with an inlet curve. In front of the air intake 4 is a laminar flow element 7 arranged. The laminar flow element has an arrangement of flow channels 10 on by a variety of in the laminar flow element 7 formed passages are formed. These passages can be circular, but can also have any other suitable cross-sectional shape.

The flow channels 10 are in use in the illustrated embodiment 12 trained in an outer cylinder 11 is used. For this purpose, the outer cylinder has a circumferential inner rib 28 on where the stake 12 with one shoulder 29 rests.

Between the inflow opening 4 ' of the laminar flow element and the outflow area 29 of the laminar flow element is a bypass 8th educated. In the way of this by pass 8th is a sensor 9 provided, by means of which the desired parameter of the medium flowing through the bypass is tapped as a reference value for medium passing through the laminar flow element.

The bypass has a design according to the invention on that in particular to calm the medium flow leads in the area of the sensor.

In the exemplary embodiment shown, the bypass is in the flow direction from an inlet gap 13 , a first calming chamber 15 ' , an inflow opening 17 , a sensor channel 16 , an outflow opening 18 , a second calming chamber 15 " and an exit gap 14 educated.

In the 2 to 5 are details I to IV of the 1 reproduced enlarged. Detail I shows the entrance area of the bypass 8th , The outer cylinder 11 has at its upper free end an inward shoulder that runs around the entire circumference 11 ' on. The laminar flow element 7 does not close to the shoulder 11 ' of the outer cylinder 11 but forms with its upper face 7 ' and the opposite surface 11 " the shoulder 11 ' a circumferential annular gap, which subsequently leads to the flow chamber to the calming chamber 15 ' is expanded. In the illustrated embodiment branches from the calming chamber 15 ' in the upper area the sensor channel 16 at an inflow opening 17 from. In the lower area of the sensor channel 16 is again a calming chamber 15 " trained over the outflow opening 18 with the sensor channel 16 is in flow connection. The calming chamber 15 ' again stands over the exit gap 14 with the passage of air in the outflow area 29 of the laminar flow element in flow connection. Immediately following the exit gap 14 is the outflow area 29 to a nozzle 30 narrows. This nozzle 30 reduces the cross section of the outflow area to the cross section of the air inlet 4 ,

At a suitable point is in the sensor channel 16 the sensor 9 arranged. The sensor 9 can be set up to tap different parameters of the flowing medium, for example temperature and flow velocity.

Due to the immediate vicinity of the outflow gap 14 to the nozzle 30 in the outflow area, the pressure difference ensures that a continuous flow in the bypass is maintained.

As in 3 you can see the sensor 9 on an insert 9 ' arranged in a corresponding recess in the outer cylinder 11 is used. The recess in turn opens towards the sensor channel so that the sensor can come into direct contact with the flowing medium.

How further out 1 the nozzle ends 30 at a predetermined distance from the air intake 4 of the housing 3 , Between the nozzle 30 and the air intake 4 a circumferential annular gap is provided which is via an inflow channel 19 in flow connection with a feed element 20 stands for another medium. The one between the wall of the nozzle 30 and the air intake 4 The gap formed is preferably on the feed element 20 opposite side wider than on the side facing the feed element. By a such design is ensured that over the circumference of the air inlet 4 the additional medium is evenly distributed to the first medium.

The additional medium, in the present case fuel gas, is fed through a feed element 20 fed. The supply element 20 has a connection 31 for a gas pipe. This connection is in flow connection with a cylinder ring 32 , in which an inner ring 33 is used. The supply element 20 is also with a sensor 21 equipped in a bypass 22 is arranged. The bypass design corresponds essentially to the training as it is in connection with the laminar flow element 7 has been described. The bypass 22 thus essentially consists of an entry gap 26 , which is in the area of the transition between the connection 31 for the gas pipe and the inner ring 33 located. At the entrance gap 26 an upper calming chamber closes 23 ' to which there is an inflow opening in the upper area 24 for the sensor channel 35 followed. The sensor channel 35 stands in its lower area over a drain 25 with the lower calming chamber 23 " in flow connection. The lower calming chamber 23 " stands over the exit gap 27 with the outflow opening 36 in flow connection. The outflow opening 36 merges into the inflow channel 19 , the second medium in the manner described above to the air inlet 4 of the housing.

In 6 Another embodiment of the laminar flow element according to the invention is shown. In this variant, the inflow channel opens 19 the other medium does not have an annular gap which widens and diminishes evenly over the circumference, but rather via a large number of openings 19 ' in the area of the air intake 4 or the nozzle area of the air inlet. The openings 19 ' are evenly distributed over the circumference, but have an increasing distance from the supply element 20 a larger passage cross-section. In this way it can also be ensured that a uniform mass flow of the gas over the circumference of the air inlet 4 is fed to the pressure chamber.

The invention is not shown on and described training forms limited. For example in the illustrated embodiment only one sensor is provided, but it can be used for more precise detection of the scope several sensors of the laminar flow element can be arranged, their measurement result evaluated accordingly in a computer and the inflow of gas is adjusted accordingly.

Claims (13)

Radial fan ( 1 ) with a housing ( 2 ) and a fan wheel arranged in it ( 3 ), an air inlet ( 4 ) and an air outlet ( 5 ), with a pressure space between the latter ( 6 ) is formed, characterized in that in front of the air inlet ( 4 ) a laminar element ( 7 ) is arranged, which is formed in a bypass ( 8th ) a sensor ( 9 ) for recording at least one parameter of the air inlet ( 4 ) flowing medium. Radial fan according to claim 1, characterized in that the laminar element ( 7 ) from an arrangement of flow channels ( 10 ) consisting of an outer cylinder ( 11 ) are enclosed. Radial fan according to claim 1 or 2, characterized in that the flow channels ( 10 ) in one operation ( 12 ) are formed, which in the outer cylinder ( 11 ) is used, the bypass ( 8th ) is formed between the two components. Radial fan according to one of claims 1 to 3, characterized in that the bypass ( 8th ) an entry gap ( 13 ) and an exit gap ( 14 ), each between the use ( 12 ) and the outer cylinder ( 11 ) are trained. Radial fan according to claim 4, characterized in that the inlet gap ( 13 ) and the exit gap ( 14 ) in flow connection with the inflow opening ( 4 ' ) of the laminar element ( 7 ) or its outflow area ( 29 ) stand. Radial fan according to one of claims 4 to 3, characterized in that the bypass ( 8th ) behind the entry gap ( 13 ) a calming chamber ( 15 ' ) to calm the air flow. Radial fan according to one of claims 5 to 6, characterized in that the sensor ( 9 ) in / on a sensor channel ( 16 ) is arranged, which has an inlet and an outlet opening ( 17 ; 18 ) in flow connection with a calming chamber ( 15 ' . 15 " ) stands. Radial fan according to one of claims 1 to 7, characterized in that between the laminar element ( 7 ) and the air inlet ( 4 ) of the housing ( 2 ) an inflow channel ( 19 ) is designed for another medium. Radial fan according to claim 8, characterized in that the further medium over the circumference of the air inlet ( 4 ) flows in evenly. Radial fan according to one of claims 1 to 9, characterized in that the further medium via a feed element ( 20 ) is supplied. Radial fan according to claim 10, characterized characterized that supply line element ( 20 ) a sensor ( 21 ) for the other medium. Radial fan according to claim 11, characterized in that the sensor ( 21 ) in a bypass ( 22 ) is arranged, the a calming chamber ( 23 ) having. Radial fan according to claim 12, characterized in that the sensor ( 21 ) in a sensor channel ( 35 ) arranged with the calming chamber ( 23 ) via an inflow and outflow ( 24 . 25 ) is in flow connection.