DE29914892U1 - Control device for volume flow control, in particular of a blower - Google Patents

Description

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Description

Control device for volume flow control, in particular of a fan

The invention relates to a control device for controlling the volume flow of a fan, consisting of a sensor system that detects the volume flow, a volume flow controller and a frequency converter for a drive unit of the fan.

Such control devices are known from the prior art and are used, for example, in connection with building air conditioning to control the volume flow of an air volume flow conveyed by a fan. The fan is usually made up of a ventilation wheel and a drive unit that drives the ventilation wheel. Depending on the intended use, the fan can be used as a fresh air or exhaust air fan. The fan's drive unit is speed-controlled to set a predefined volume flow to be conveyed by the fan. The following applies: the higher the speed of the fan wheel, the greater the volume flow conveyed by the fan.

A measuring device is provided to record the volume flow actually delivered by the fan (actual value) and to compare it with the previously specified volume flow (setpoint value), which is used to measure the differential pressure. A frequency converter is provided for controlling the volume flow, which is electrically connected directly to the drive unit and is in turn coupled to a volume flow controller. The signals delivered to the volume flow controller by at least two pressure sensors or a differential pressure sensor are evaluated by the latter, which then sends a corresponding signal to the frequency converter following a setpoint-actual value comparison. The disadvantage of such a control device is that

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The disadvantages of this direction are, on the one hand, the high installation effort and, on the other hand, the susceptibility to failure.

To install the control device, the sensor system consisting of at least two pressure sensors must first be installed in the line carrying the volume flow. These sensors must then be electrically connected to the volume flow controller arranged on the fan. Finally, the volume flow controller must in turn be connected to the frequency converter. This complex assembly for installing the control device is not only disadvantageous as part of initial equipment, but also particularly during retrofitting or in the event of repairs. In addition, the control device, which consists of a relatively large number of individual parts, is particularly susceptible to failure, and troubleshooting can be extremely difficult depending on the assembly or repair space available. Another disadvantage is that the previously known control devices cannot be pre-assembled at the factory due to the fact that assembly is carried out depending on the respective application situation, which results in relatively high overall costs for installation.

Based on this prior art, it is therefore the object of the present invention to provide a control device which avoids the above-mentioned disadvantages and which has a compact, easy-to-handle design and is at the same time cost-effective to manufacture.

To solve this problem, the invention proposes that the sensors and the volume flow controller are integrated in the frequency converter and form a common structural unit together with the frequency converter.

With this development according to the invention, a structural unit is created which comprises the entire control device and which can be assembled using the simplest means and with minimal assembly effort.

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wall can be connected directly to the drive unit of the blower. The combination of all the individual components of the control device into a common unit advantageously creates a compact design that allows pre-assembly to be carried out at the factory regardless of the subsequent area of application of the control device. In this way, the overall costs for installing the control device can be significantly reduced, because the drive units, which are already provided with a pre-assembled control device at the factory, only need to be connected to the corresponding sensors on site. Coordinating the individual components with one another and wiring on site can be omitted. The control device according to the invention is also of considerable advantage in the context of retrofitting or in the event of repairs. For example, in the event of repairs, it is only necessary to replace the defective unit with a new unit with minimal assembly work. Retrofitting the control device according to the invention is also particularly simple, since the structural unit containing the entire control device is easy to handle even under adverse installation conditions and, after establishing an electrical connection with the drive unit, only needs to be connected to the corresponding sensors.

According to a feature of the invention, a common microcontroller is provided for the volume flow controller and the frequency converter. The use of only one common microcontroller is advantageous, particularly with regard to manufacturing costs. A second microcontroller is no longer required and the microcontroller used jointly by the volume flow controller and the frequency converter therefore takes over both the processing and the control of the signals sent by the sensors to the volume flow controller and the processing of the data sent by the volume flow controller by the frequency converter. Both the volume flow controller and the frequency converter

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can be housed together on a microcontroller board, so that potentially laborious and complex cabling is completely eliminated.

According to a further feature of the invention, the assembly containing the sensors, the volume flow controller and the frequency converter can be connected to the power supply of the drive unit. This measure advantageously makes the control device independent of the power supply, which may be difficult to access in the installed position of the fan. Instead, the control device can be connected in a pre-assembly at the factory to the power supply connections already present on the drive unit. When assembling on site, it is then no longer necessary to provide both the drive unit and the control device with a separate power supply, which reduces the amount of cabling required.

According to a further feature of the invention, the structural unit is designed in such a way that it can be arranged within the housing, which accommodates the connection terminals, of a motor having the drive unit. In this way, on the one hand, a space-saving accommodation of the control device can be achieved, and on the other hand, it is not necessary to provide an additional housing arrangement for accommodating the control device. Furthermore, the arrangement of the control device within the housing having the connection terminals offers the advantage of the possibility of easily attaching the control device to the power supply.

According to a further feature of the invention, at least part of the volume flow conveyed by the fan can be used to cool the frequency converter. To ensure the operational safety of the control device, it is necessary to protect the frequency converter itself and the microcontrol system used jointly by the frequency converter and volume flow controller.

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This can be achieved, for example, by means of a cooling fan. However, in the event that a volume flow conveyed by the fan can be guided directly past the fan, an alternative embodiment of the invention proposes that, instead of using an additional cooling fan, part of the volume flow conveyed by the fan be guided past the frequency converter for cooling.

According to a further feature of the invention, the control device is connected to a communication line and at least two pressure hoses. The communication line serves to connect to a higher-level control computer and the at least one pressure hose connects the sensors arranged within the structural unit to the line carrying the volume flow. The wiring effort for connecting the control device according to the invention is thus limited to establishing a communication connection with a higher-level control computer and connecting to the line carrying the air flow. Complex wiring is not required.

According to a further feature of the invention, a fallback level is provided in the event of a communication failure.

The presence of such a fallback level ensures that the control system continues to operate even if an unexpected fault interrupts communication between the higher-level master computer and the control system. Without a complete failure resulting from faulty communication, the control system operates in fallback mode until the fault is rectified and the communication link between the higher-level master computer and the control system is restored. For example, an electronic component with a microcontroller can be used as a fallback level and controls the fan via an emergency program in the event of a communication fault.

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The control device according to the invention for volume flow control is not limited to use in connection with air-conveying fans, but rather extends to all media-conveying devices. For example, the control device according to the invention can also be used in connection with the use of liquid or solid media-conveying units, such as a water pump. In some circumstances, it may only be necessary to adapt the sensors depending on the medium being conveyed.

Further details and advantages of the invention will become apparent from the following description with reference to the drawings, in which:

FIG 1 schematic representation of the functioning of the control device;

FIG 2 schematic representation of a motor provided with a control device according to the invention.

FIG 1 shows a schematic representation of the functioning of the control device according to the invention. The control device shown here is part of a fan for conveying a volume flow symbolically shown in the drawing with an arrow 2. This volume flow 2 is conveyed through the line marked with 1. A sensor system consisting of two pressure sensors 3 is provided to detect the pressure prevailing within the volume flow, whereby the two pressure sensors 3 are arranged at a distance from one another within the volume flow-carrying line. Both pressure sensors 3 are each connected to the volume flow controller 6 via a signal line 5. The values recorded by the two pressure sensors 3 are converted into corresponding signals and fed to the volume flow controller 6 via the respective signal line 5. The volume flow controller 6 in turn processes the measured values supplied by the two pressure sensors 3, creates a comparison between the determined actual value and the specified target value.

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12 and sends a corresponding signal to the frequency converter 8 via the signal line 7. Depending on the signal reaching the frequency converter 8, the drive unit 10 is controlled via the control line 9 connecting the frequency converter 8 and the drive unit 10. The drive unit 10 is in turn connected via the control line 11 to the unit 4 that changes the pressure in the volume flow 2. Depending on the control signal supplied by the frequency converter 8, the drive unit 10 reacts in such a way that the pressure change unit 4 arranged between the two pressure sensors 3 moves and a change in speed or a change in pressure in the volume flow 2 is the result.

The control device shown in FIG 1 with regard to its function is shown in FIG 2 in an exemplary installation position. Shown here is a drive unit 10 in the form of an electric motor, which is provided with a fan wheel 13 as a pressure change unit. The entire control device is combined in a compact form in a common structural unit 14 and arranged within the housing 18 which accommodates the connection terminals. In order to determine the pressure curve within a volume flow not shown here, the sensors belonging to the structural unit 14 are pressure-connected to the volume flow to be controlled via pressure hoses 17. A power cable 15 is provided to supply power to the control device, which also serves to supply power to the drive unit 10. A communication line 16 is provided for communication with a higher-level master computer not shown in this figure.

According to the invention, the control device is formed by a structural unit 14 comprising the sensor system 3, the volume flow controller 6 and the frequency converter 8. The structural unit 14 is advantageously designed in such a way that it can be installed in a space-saving manner within the housing accommodating the connection terminals.

the housing 18 of the drive unit 10. This also makes it possible to supply the control device with energy via the existing energy supply of the drive unit 10. It is therefore no longer necessary to provide increased cabling, but instead to use only one power cable 15 to supply the drive unit and control device with energy. In addition to this one power cable 15, it is only necessary to establish a pressure connection between the sensors and the volume flow to be controlled and a communication connection to a higher-level master computer for the ready-to-use connection of the control device.

The control device according to the invention is easy to handle and install due to its compact design, less susceptible to external influences due to its protected arrangement and inexpensive to manufacture due to less complex assembly.

Claims (9)

1. Control device for volume flow control of a fan, consisting of a sensor system ( 3 ) which detects the volume flow ( 2 ), a volume flow controller ( 6 ) and a frequency converter ( 8 ) for a drive unit ( 10 ) of the fan, characterized in that the sensor system ( 3 ) and the volume flow controller ( 6 ) are integrated in the frequency converter ( 8 ) and together with the frequency converter ( 8 ) form a common structural unit ( 14 ). 2. Control device according to claim 1, characterized in that a common microcontroller is provided for the volume flow controller ( 6 ) and the frequency converter ( 8 ). 3. Control device according to one of claims 1 and 2, characterized in that the structural unit ( 14 ) can be attached to the power supply ( 15 ) of the drive unit ( 10 ). 4. Control device according to one of claims 1 to 3, characterized in that the structural unit ( 14 ) is designed such that it can be arranged within the housing ( 18 ) of the drive unit ( 10 ) accommodating the connection terminals. 5. Control device according to one of the preceding claims, characterized in that at least a part of the volume flow conveyed by the fan can be used to cool the frequency converter ( 8 ). 6. Control device according to one of the preceding claims, characterized in that it is connected to a communication line ( 16 ) and at least one pressure hose ( 17 ). 7. Control device according to one of the preceding claims, characterized in that a fallback level is provided in the event of a communication failure. 8. Control device according to claim 7, characterized in that an electronic component is provided as a fallback level. 9. Control device according to claim 8, characterized in that the electronic component comprises a microcontroller.