DE202020003124U1 - Turbo machine and control for a turbo machine - Google Patents

Abstract

Turbo machine (1), in particular fan or fan heater, for circulating and / or tempering room air, comprising a housing (2) with at least one air inlet (3) and at least one air outlet (4) connected to the air inlet (3) in a fluid-conducting manner, with between at least one fan is provided for the air inlet (3) and the air outlet (4), characterized in that at least one suspended matter filter (7) is arranged upstream and / or downstream of the fan.

Description

The present invention relates to a turbomachine, in particular a fan or fan heater, for circulating and / or tempering room air according to the features in the preamble of claim 1. Furthermore, the present invention relates to a controller for a turbomachine having the features of claim 7.

The design of flow machines used in rooms or buildings ranges from mobile ventilators and ventilators to central and, in this respect, stationary ventilation devices. Depending on the type of construction, these enable a circulation through to temperature control of the room air. In addition to pure circulation, such machines can also have at least a connection for the supply of fresh air and / or for the removal of exhaust air. In addition to temperature control in the form of cooling and / or heating of the room air, for example using a fan heater, it is also possible to change its humidity.

With the exception of ventilators without a housing, turbomachines usually have a housing. So it was with the KR 10 178 26 30 B1 and the EP 2 789 926 A1 in each case a fluid flow machine is known which has a housing with at least one air inlet designed to suck in room air and / or fresh air. This is in a fluid-conducting connection with an air outlet of the housing. At least one fan arranged between the air inlet and the air outlet within the housing ensures the necessary air flow from the air inlet to the air outlet.

In addition to the circulation, temperature control and / or change in air humidity, there is an increasing need to reduce any suspended matter contained in the room air. In addition to fine dust particles, the focus is also increasingly on microorganisms and / or viruses or virions. The terms “viruses” and “virions” are often used synonymously. Strictly speaking, virion or viron means a single virus particle that is located outside of a host cell and is therefore extracellular, infectious. For the purposes of the conceptual simplification, the term viruses are therefore understood to mean both viruses and virions in the context of the invention. In contrast, the term microorganisms used in the context of the invention includes, for example, bacteria and / or fungi and / and algae and / and protozoa, which - unlike viruses or virions - are living beings.

Viruses as well as microorganisms can, for example, adhere to solid particles or be contained in or in water droplets as part of the room air. The latter experience additional enrichment through breathing and any body reactions, such as sneezing or coughing. The use of a flow machine ensures that such suspended matter is circulated and distributed accordingly. In addition, the air movements that inevitably occur can contribute to the whirling up of suspended matter that has already sunk, so that as a result the proportion contained in the room air increases. Previously known configurations of turbomachines used in rooms have so far not contained any countermeasures worth mentioning, so that their configuration and use still offer room for improvement.

Against this background, the present invention is based on the object of further developing a turbomachine in such a way that it enables a reduction of suspended matter, in particular viruses and / or microorganisms, present in room air. Furthermore, the invention is based on the object of providing a control for a turbomachine in order to reduce viruses and / or microorganisms present in room air and / or on a surface. Ultimately, a use for a turbomachine is to be shown in order to reduce viruses and / or microorganisms present in room air and / or on a surface.

According to the invention, this object is achieved in a fluid flow machine according to the features of claim 1 and in a controller with the features of claim 7. Furthermore, this object is achieved by a use according to the features of claim 13. Advantageous further developments are the content of the dependent claims 2 to 6 and 8 to 12 as well as 14 and 15.

At this point it should first be pointed out that the features and / or measures listed individually in the following description can of course be combined with one another in any desired and technically meaningful manner and thus show further embodiments of the invention. Furthermore, the invention is not limited to the exemplary embodiments mentioned and the contents mentioned by way of example, so that the basic concept of the invention is also to be regarded as part of the embodiments that extend it.
The core idea of the turbomachine according to the invention is that it has at least one suspended matter filter. This can be arranged upstream and / or downstream of the fan. In its capacity as a depth filter, the suspended matter filter can contribute to a significant separation of suspended matter from the air flow passing through the turbo machine, in particular room air. This way you can get the share reduce the amount of suspended matter contained in the room air in the desired manner. A further entry of suspended matter into the room air is also effectively counteracted. In addition to continuous filtering, the proportion of suspended matter in the room air can also be reduced to a desired level, for example before entering the respective room. For those skilled in the art, the period of time required for separating the suspended matter results from the performance of the turbomachine and the volume of space to be filtered. In particular with regard to viruses and / or microorganisms, the flow machine according to the invention enables a reliable reduction of the same in the room air. This can be of great advantage, for example, in those areas in which several and / or changing people are or / and meet in order to reduce or even prevent any transmission of disease-causing viruses and / or microorganisms between them.

With regard to the particulate filter, it should be emphasized that its performance for separating particulate matter differs significantly by definition from the degree of separation of conventional filters. A particulate filter of the type in question enables the separation of particles whose aerodynamic diameter is below 1.0 micrometer (µm), which corresponds to 1,000 nanometers (nm). For example, although virions can only have a diameter of approximately 15 nm, in the air they usually adhere to at least one other larger particle, so that the particulate filter can then contribute to their joint separation

According to a particularly preferred development of the basic concept of the invention, the particulate filter can be designed to separate particles with a size of 0.1 to 0.3 micrometers (μm) with an overall efficiency of over 99.995%. Alternatively or in an advantageous manner in addition to this, the suspended matter filter can be designed to separate said particles with a local efficiency of over 99.975%. The term “overall efficiency” means the degree of separation through the entire particulate filter. In contrast, the "local efficiency" means that area of the particulate filter which, for example, has the poorest degree of separation due to its design. In other words, the area of the particulate filter showing the worst degree of separation should also have an efficiency of over 99.975% for separating particles with a size of 0.1 to 0.3 micrometers (μm). In this way, for example, bacteria, viruses, pollen and aerosols can be excreted in an extremely effective manner from the air flow that passes through the turbomachine during operation.

The particulate filter can preferably be a high-performance particle filter in the form of at least one HEPA filter (High Efficiency Particulate Air filter). This can particularly preferably correspond to filter class E14.

In an advantageous manner, the invention further proposes that the turbomachine according to the invention can have at least one heating element. This can be arranged between the air inlet and the air outlet. The arrangement of the heating element can be selected such that it is spaced apart from the particulate filter or is arranged in its area. It is also conceivable that the heating element is in physical contact with at least one area of the particulate filter and / or is an integral part of the particulate filter. In either case, said heating element can be located upstream or downstream of the fan. The heating element can serve to temper an air flow passing through the turbo machine in the sense of heating. The heating element can be designed in such a way that the air flow can be heated to a temperature that leads to at least regional heating around the turbomachine, so that any areas heated in this way with the room air heated in this way in Viruses or / and microorganisms that are in contact or that come into contact can be inactivated and / or killed or destroyed.

The arrangement and / or design of the heating element can particularly preferably be such that the particulate filter can be heated at least indirectly by this. This can take place via direct heating of the particulate filter by the heating element, as can be achieved, for example, by its arrangement having physical contact with the particulate filter and / or at least partial integration into the particulate filter. As an alternative or in addition to this, the heating element can also heat the particulate filter in such a way that the air flow passing through the turbomachine serves to transfer the thermal energy from the heating element to the particulate filter. This indirect heat transfer can take place through a corresponding temperature control of the air flow via the heating element, for which purpose the heating element is to be arranged upstream of the particulate filter. Depending on the configuration of the heating element, the air flow can be passed through and / or past the heating element, at least in some areas, in order to achieve the required temperature control of the air flow, which then leads to the desired heating of the particulate filter. In a particularly preferred manner, the suspended matter filter can be heated to a temperature which leads to inactivation and / or killing or destruction of any viruses and / or microorganisms located on or / and in the particulate filter.

In principle, the invention proposes an embodiment of the turbomachine in a way that makes it possible to heat its suspended matter filter to a temperature or temperature range used for virus inactivation. This ensures that suspended solids separated by the particulate filter can be subjected to a thermal treatment, as a result of which any disease-causing viruses contained therein are inactivated. Alternatively or additionally, the invention proposes an embodiment of the turbo machine in a way that makes it possible to heat the room air that can be tempered by this to a temperature or temperature range, so that the room air located in or / and in contact with the room air heated in this way Viruses located on the surface can be inactivated. Said heating can take place in a particularly preferred manner by at least one heating element of the turbo machine according to the invention.
The previously explained inactivation of any viruses can of course also apply to microorganisms separated in the suspended matter filter and / or in the room air or / and on surfaces in contact with the room air.

• - von 55°C bis 120°C,
• - von 55°C bis 100°C,
• - von 55°C bis 70°C.

With regard to the thermal treatment possible with regard to viruses and / or microorganisms by means of the turbo machine according to the invention, an embodiment is proposed for this which heats the suspended matter filter and / or the room air to at least one of the temperature ranges mentioned below or at least one within at least one of the following Temperature range allows:

• - from 55 ° C to 120 ° C,
• - from 55 ° C to 100 ° C,
• - from 55 ° C to 70 ° C.

It is usually assumed that in the case of viruses at a temperature of 55 ° C to 70 ° C, denaturation occurs within a few minutes, which leads to their inactivation.

In principle, a fan attachment for a turbomachine, in particular a fan or fan heater, for circulating and / or tempering room air is also conceivable, which includes a particulate filter as described in more detail above or at least has a receptacle for such a particulate filter. This fan attachment can be used to equip or retrofit a fluid flow machine in order to reduce viruses and / or microorganisms present in the room air and / or on a surface. It is conceivable that such a fan attachment has its own heating element in order to provide the previously explained properties for the thermal treatment of the particulate filter and / or the room air. Alternatively or in addition, it is conceivable that said fan attachment comprises a control according to the invention as described above.

The turbomachine according to the invention now presented already offers, in its basic configuration, an easily implementable possibility of significantly reducing the proportion of suspended matter present in room air. With regard to viruses and / or microorganisms, the turbomachine also provides an extremely effective device for eliminating their infectious properties. This effect already begins with the separation of the same inside the particulate filter, which leads to a significant reduction in their proportion in the room air. This effect is reinforced by the possibility of eliminating the viruses and / or microorganisms separated in this way by means of a heat treatment of the suspended matter filter. Ultimately, the room air that can be heated by the turbo machine can be used in an extremely advantageous manner to render viruses and / or microorganisms contained therein harmless by being subjected to thermal exposure over a sufficient period of time. In this way, viruses and / or microorganisms can also be reached that do not get into the turbomachine via the air inlet and are separated out by its particulate filter. In addition, the targeted heating of the room air also enables the surface temperatures of floor, wall and / or ceiling areas in contact with it and of objects and devices in the room, such as tables, furniture and chairs as well as telephones and keyboards, to be increased to name a few possibilities in a non-exhaustive list.

In particular in commercial or public buildings and other facilities, such as authorities, medical practices, hospitals, (university) schools, hotels, offices, canteens, restaurants, bars, day care centers, homes, care and rehabilitation facilities as well as sports centers, the fluid flow machine according to the invention offers an extremely inexpensive, easy to use and effective means to effectively counteract their known distribution properties in relation to pathogenic viruses and / or microorganisms. In addition, it can also be used in mobile rooms, such as those found in buses and trains as well as on ships and in airplanes, to name but a few.

The invention is also directed to a controller for a turbo machine. The turbomachine has at least one fan and at least one suspended matter filter arranged upstream or downstream of the fan and at least one heating element. With regard to the turbomachine, it can preferably be the turbomachine according to the invention. The controller comprises a control module which is designed to operate the heating element provided for at least indirect heating of the particulate filter and / or room air for a predetermined or predeterminable period of time.

The advantages resulting from this have already been explained in more detail above in connection with the turbomachine according to the invention, so that reference is made to the corresponding explanations at this point in order to avoid repetitions.

According to a particularly preferred development of the control according to the invention, the control module can be activated and / or deactivated manually and / or automatically. This means that the control module can be activated and / or deactivated for example by a human input via a physical switch or button or an emulated surface. As an alternative or in addition to this, the activation and / or deactivation can take place automatically, the automation then being able to take place, for example, on the acquisition of any parameters and / or a time specification.

For example, at least partial automation using a time module is conceivable. This can serve to maintain the activity of the turbomachine as a whole and / or its heating element over a period of time. The time module itself can be used for said activation and / or deactivation. In this context, it is conceivable, for example, to have a predefined schedule that includes fixed times for activating and / or deactivating the turbo machine. In the simplest case, for example, the turbo machine can be activated manually, whereupon the time module is used to automatically deactivate it.

In a particularly advantageous manner, the temperature of the heating element can be adapted by the control module. This ensures that the particulate filter and / or the room air reach the desired temperature. The temperature of the heating element can be adjusted, for example, on the basis of a measured value that can be recorded by a sensor. Said sensor can for this purpose, for example, detect the temperature of the particulate filter and / or the air flow passing through the turbomachine and / or the room air and report it to the control module.

In principle, the controller can have at least one sensor connected at least indirectly to the control module in order to detect a temperature that can be generated by the heating element in the area of the particulate filter and / or the room air. Such a sensor can be a probe which requires direct contact with a component or direct exposure to a fluid in order to detect its respective temperature. As an alternative or in addition to this, a contactless sensor is also conceivable, such as an IR sensor which, for example, detects the temperature prevailing on a surface, in particular at a distance from the turbomachine.

The invention provides that the control module of the controller can be designed in such a way that the suspended matter filter and / or the room air can be heated at least indirectly by the heating element to a temperature or temperature range used for virus inactivation. In other words, the control module ensures that the level of temperature control by the heating element is adapted so that the particulate filter and / or the room air reach the desired temperature. This property can of course also be used in relation to microorganisms, such as bacteria.

According to a preferred development of the control according to the invention, it can have a time module which is designed to heat the suspended matter filter and / or the room air at least indirectly for a predetermined or predeterminable period of time by the heating element to a temperature or temperature range used for virus inactivation. In other words, the time module ensures that the duration of the temperature control by the heating element is adapted in such a way that the particulate filter and / or the room air maintain the desired temperature for a required period of time. This property can of course also be used in relation to microorganisms, such as bacteria.

In principle, it is conceivable that the time module itself can be a component of the control module.

The control according to the invention can be used to upgrade an already existing turbomachine equipped with at least one sufficiently powerful heating element so that it can be used to reduce viruses and / or microorganisms present in room air and / or on a surface.

A turbo machine serving to circulate and / or temper room air, in particular the turbo machine according to the invention, can be used to reduce viruses and / or microorganisms present in room air and / or on a surface.

For this purpose, the part of the room air flowing through the turbo machine can at least partially be passed through a suspended matter filter, whereby the proportion of suspended matter, in particular viruses and / or microorganisms, in the room air can already be significantly reduced by separating them out through the suspended matter filter.

A possible temperature control of the part of the room air flowing through the turbomachine can take place in such a way that the room air having an actual temperature is heated to a setpoint temperature. The target temperature can have a value or a range of values which is used for disinfection and / or virus inactivation. In addition to the possible thermal treatment of the room air itself, the room air heated in this way can be used to indirectly heat surfaces that come into contact with it in order to neutralize viruses and / or microorganisms located on them.

• 1 einen erfindungsgemäße Strömungsmaschine in einer perspektivischen Darstellung sowie
• 2 einen Ausschnitt aus der erfindungsgemäßen Strömungsmaschine aus 1 in einer ebenfalls perspektivischen Darstellung.

The invention is explained in more detail below with reference to an exemplary embodiment shown schematically in the figures, from which further advantageous details and effects emerge. Show it:

• 1 a turbomachine according to the invention in a perspective view and
• 2 a section of the turbomachine according to the invention 1 also in a perspective view.

1 shows a flow machine according to the invention 1 for the circulation and / or temperature control of room air in a perspective view. In the present purely exemplary embodiment, this is a fan heater. The turbo machine 1 includes a housing 2 with an air inlet arranged here on the side or on its front 3 and one at the top of the housing 2 located air outlet 4th . On the air outlet 4th In the present case, a fan attachment is purely exemplary 5 arranged, which here only indicated fastening means S. with the case 2 the turbo machine 1 connected is. In the embodiment of the turbomachine that is only shown as an example here 1 includes these two roles 6th , of which only a single role due to the perspective representation 6th can be seen. The roles 6th serve the mobility of the fluid machine, which is designed to be movable here 1 .

Inside the case 2 is the air inlet 3 in a manner not shown in a fluid-conducting manner with the air outlet 4th connected. Between the air inlet 3 and the air outlet 4th a fan, also not shown in detail, is arranged, which generates an air flow through the housing 2 ensures through. With the help of the fan that is in operation, room air can be fed through the air inlet 3 in the housing 2 which are then sucked in from the air outlet 4th exit. In the present case, there is a particulate filter downstream of the fan 7th (indicated by crossing grid lines) in the area of the air outlet 4th arranged, which serves to separate suspended matter, in particular viruses and / or microorganisms, from the room air. The particulate filter can be seen 7th directly below the fan attachment 5 located. The fan attachment 5 itself can be a receptacle for the particulate filter 7th own, so that the particulate filter 7th quasi an, in particular exchangeable, part of the fan attachment 5 can be.

Due to the arrangement of the particulate filter shown here purely as an example 7th is it possible to one the housing 2 the active turbo machine 1 passing air flow in relation to any suspended matter before exiting the air outlet 4th to filter.

In its preferred embodiment, the particulate filter is 7th able to separate particles with a size of 0.1 to 0.3 micrometers with an overall efficiency of over 99.995% and / or a local efficiency of over 99.975% from the air flow.

The flow machine according to the invention can also be used in a manner not shown in greater detail 1 also comprise at least one heating element, which is then between the air inlet 3 and the air outlet 4th inside the case 2 is arranged. The heating element can be arranged upstream or downstream of the fan. The heating element can be arranged or designed in such a way that the particulate filter 7th is at least indirectly heated by this. For this purpose, the heating element can be located in the immediate vicinity of the particulate filter, in particular in direct contact with it or at least partially integrated in it, or else at a distance from it. Depending on the arrangement, the particulate filter is 7th heatable either directly or via the air stream that can be heated beforehand by the heating element. This enables the particulate filter to be heated 7th to a temperature or temperature range that causes virus inactivation in the particulate filter 7th deposited viruses. The heating element can also be designed and / or controlled in such a way that the room air can be heated to a temperature or temperature range that serves to inactivate viruses. Alternatively or in addition In this way any separated microorganisms and / or microorganisms in the room air can also be inactivated.

The temperature of the particulate filter that can be at least indirectly achieved via the heating element 7th or / and the room air ranges from 55 ° C to 120 ° C. This can preferably be from 55 ° C to 100 ° C, in particular from 55 ° C to 70 ° C.

Furthermore, the turbo machine according to the invention 1 a control only hinted at here 8th have. The control 8th comprises a control module which is designed to at least indirectly heat the suspended matter filter 7th and / or to operate the heating element provided by room air for a predefined or predefinable period of time. In principle, the control module can be activated and / or deactivated in a manual or / and automatic manner in order to appropriately manipulate the turbomachine 1 , in particular their fan and / or heating element. The temperature of the heating element can be adjusted by the control module to the required temperature in relation to the particulate filter 7th and / or to maintain the room air. This can be done, for example, on the basis of measured values of at least one sensor that is not shown in detail. Said sensor can be wired or wirelessly connected to the control module. In its capacity, the sensor serves to measure the temperature in the area of the particulate filter that can be generated by the heating element 7th and / or to detect the room air and report it to the control module. In any case, the control module is designed to control the particulate filter 7th and / and to heat the room air at least temporarily, at least indirectly, by the heating element to a temperature or temperature range serving for virus inactivation. As an alternative or in addition, a time module can be present which is designed for the purpose of the particulate filter 7th and / and to heat the room air at least indirectly for a predefined or predefinable period of time by the heating element to a temperature or temperature range serving for virus inactivation.

2 shows a detail of the turbomachine according to the invention 1 . This essentially shows the fan attachment 5 while the case 2 is only indicated by broken lines. This illustration shows the dimensions of the particulate filter 7th visible, which is via the air outlet 4th in the housing 2 the turbo machine 1 extends into it. In a manner not shown in greater detail, the underside of the particulate filter, which cannot be seen here, can be used 7th or the fan attachment 5 an adapter can be arranged, which can then be used for coupling to a separate air distributor. In this embodiment it is conceivable to use the fan attachment 5 in such a way that it can be turned by 180 °, so that, depending on the application, either the adapter or one that can be seen here with individual blow-out openings 9a equipped hood 9 of the fan attachment 5 the upper end of the turbomachine 1 forms, while the opposite part of the fan attachment 5 inside the case 2 lies.

List of reference symbols

1 -

Turbo machine

2 -

Housing from 1

3 -

Air inlet from 2

4 -

Air outlet from 2

5 -

Fan attachment from 1

6 -

Role of 1

7 -

HEPA filter from 1

8th -

Control of 1

9 -

Hood of 5

9a -

Exhaust opening from 5 in 9

S -

Fasteners

QUOTES INCLUDED IN THE DESCRIPTION

This list of the documents listed by the applicant was 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.

Patent literature cited

• KR 101782630 B1 [0003]
• EP 2789926 A1 [0003]

Claims (12)

Turbo machine (1), in particular fan or fan heater, for circulating and / or tempering room air, comprising a housing (2) with at least one air inlet (3) and at least one air outlet (4) connected to the air inlet (3) in a fluid-conducting manner, with between at least one fan is provided for the air inlet (3) and the air outlet (4), characterized in that at least one suspended matter filter (7) is arranged upstream and / or downstream of the fan. Turbo machine (1) after Claim 1 , characterized in that the suspended matter filter (7) is designed to separate particles with a size of 0.1 to 0.3 micrometers with an overall efficiency of over 99.995% and / or a local efficiency of over 99.975%. Turbo machine (1) after Claim 1 or 2 , characterized in that at least one heating element, in particular upstream or downstream of the fan, is arranged between the air inlet (3) and the air outlet (4). Turbo machine (1) after Claim 3 , characterized by an arrangement and / or design of the heating element in such a way that the suspended matter filter (7) can be heated at least indirectly by the heating element, in particular by means of an air flow that can be tempered by the heating element. Turbo machine (1) after Claim 3 or 4th , characterized in that the suspended matter filter (7) and / or the room air, in particular by the heating element, can be heated to a temperature or temperature range serving for virus inactivation. Turbo machine (1) according to one of the Claims 3 to 5 , characterized in that the suspended matter filter (7) and / or the room air, in particular by the heating element, can be heated to at least one of the temperature ranges mentioned below or at least one temperature lying within at least one of the temperature ranges mentioned below: - from 55 ° C to 120 ° C, - from 55 ° C to 100 ° C, - from 55 ° C to 70 ° C. Control (8) for a fan and at least one upstream or downstream of the fan arranged particulate filter (7) and at least one heating element having turbomachine (1), in particular according to one of the preceding claims, comprising a control module which is designed to allow at least indirect heating of the particulate filter (7) and / or the heating element provided by the room air for a predefined or predefinable period of time. Control (8) Claim 7 , characterized in that the control module can be activated and / or deactivated manually and / or automatically, in particular by a time module. Control (8) Claim 7 or 8th , characterized in that the temperature of the heating element can be adjusted by the control module, in particular on the basis of a measured value that can be detected by a sensor. Control according to one of the Claims 7 to 9 , characterized in that at least one sensor connected at least indirectly to the control module is provided in order to detect a temperature that can be generated by the heating element in the area of the suspended matter filter (7) and / or the room air. Control (8) according to one of the Claims 7 to 10 , characterized by a design of the control module in such a way that the particulate filter (7) and / or the room air can be heated at least temporarily at least indirectly by the heating element to a temperature or temperature range used for virus inactivation. Control (8) according to one of the Claims 7 to 11 , characterized by a time module which is designed to heat the particulate filter (7) and / or the room air at least indirectly for a predetermined or predeterminable period of time by the heating element to a temperature or temperature range serving to inactivate viruses.

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