DE102015223527A1 - Apparatus and method for drying process air and killing pathogens contained therein - Google Patents

Abstract

Apparatus and method for drying a process air and killing pathogens, comprising a process air supply to a first segment of a cylindrical sorption body rotating about an axis of rotation, and supplying secondary air to a heater and a conduit with the heated secondary air from the heating device can be fed to at least one second segment of the sorption body and flows through the at least second segment of the sorption body. There is first in the region of the first segment of the sorbent adsorption. As a result of the rotation of the sorption body, this first segment of the sorption body reaches the region in which heated secondary air flows through the sorption body. The adsorbed substances are removed as a result of desorption from the first segment of the sorption body. The at least one second segment of the sorption body reaches the region of the feed for process air and with the at least second segment an adsorption of substances takes place. The secondary air laden with the substances desorbed from the sorbent body is discharged through a conduit. With an irradiation device emitting electromagnetic radiation in the region of the ultraviolet light, the dried air is irradiated and removed via a line.

Description

The invention relates to an apparatus and a method for drying a process air and for killing pathogens contained therein.

Within pharmaceutically and medically used areas, but also in the food industry, people and products can be contaminated by bacteria, viruses and germs during packaging processes, for example.

In known systems for drying process air filters are used, which must be replaced regularly or at least removed from the system and cleaned or dried. Alternatively, sorption rotors are used. The process air is dried in such systems, but in any of the known systems bacteria, viruses and germs are killed. These remain in the dried process air and the filter (s), where they continue to contribute to contamination within the process air and thus pose a health risk.

It is therefore an object of the invention to provide a device and a method to dry process air and kill pathogens.

According to the invention, this object is achieved with a device having the features of claim 1 and a method that can be carried out with the features of claim 9. Advantageous embodiments and further developments of the invention can be realized with features described in the subordinate claims.

A device according to the invention for drying a process air and for killing pathogens contained therein has a feed for process air to a first segment of a cylindrical sorption body rotating about a rotation axis. Secondary air is guided through a line from the heating device to at least one second segment of the sorption body in a direction opposite to the process air and through this second segment via a further feed.

The heating device may be formed by a region of the housing enclosing the sorption body and / or with elements within the sorption body. This area of the housing and / or these elements can be designed as electrical resistance heating, steam heating or for inductive heating.

There is first in the region of the first segment of the sorbent adsorption of substances contained in the process air. As a result of the rotation of the sorbent body, this first segment of the sorbent body is moved into the area in which heated secondary air flows through the sorbent body and the adsorbed substances are removed from the first segment of the sorbent body as a result of the desorption achievable with the heated secondary air, while the at least one second sorbent body Segment of the sorbent enters the region of the supply of process air and with at least one second segment adsorption of substances from the process air takes place.

The sorbent body and the irradiation device can be arranged together in a housing or in a first housing and in a second housing and connected to one another via a line. With at least two housings, a modular design can be achieved. The housing or a region of the housing in which the irradiation device is arranged can be produced with a reflective inner surface and / or made of stainless steel.

The secondary air laden with the substances desorbed from the sorbent body is discharged through a conduit. It can be led to a heat exchanger, through which the secondary air supplied to the device is guided before entering the heating device, so that thermal energy of the secondary air laden with the desorbed substances can be transferred to the supplied secondary air.

In the direction of the process air passed through the sorption body after the sorption body, an electromagnetic radiation is arranged in the region of the ultraviolet light emitting irradiation device, the irradiation device and the electromagnetic radiation on the dried air and / or, as explained below, on at least one surface of another Filter is directed.

The intensity and the duration of the electromagnetic radiation can be controlled and / or regulated. The electromagnetic radiation used may preferably have wavelengths in the range of 100 nm to 300 nm.

Downstream of the irradiation device in the flow direction of the dried air, a further filter can be arranged, through which the dried air is passed. The further filter and / or the charge introduced therein as a filter material can advantageously be loaded with activated carbon, whereby optionally formed ozone can be converted into oxygen molecules.

The dried and freed by the irradiation of pathogens air is discharged through a conduit.

In a method according to the invention for drying process air and for killing pathogens contained therein with the described device, process air is passed through a first segment of a cylindrical sorption body rotating about a rotation axis and dried by adsorption on / in the sorption body. The sorption body can preferably be rotated at a speed in the range of 1 U / h to 30 U / h.

The process air supplied to the sorption body can be passed through a first filter and / or a cooling device before a segment of the sorption body flows through. With a first filter, substances contained in the process air in solid form can be removed from the process air. With the cooling device, the process air can be cooled so that it is pre-dried and improved temperature conditions for the adsorption process can be achieved.

Secondary air is preheated by means of a heating device, preferably to a temperature of at least 90 ° C., and flows in at least one second segment of the sorption body in one of the process air in the same direction, so that a desorption of substances adsorbed by the sorption body from the process air is achieved. As a result of the rotation of the sorbent body takes place in a first segment of the sorbent first adsorption and after further rotation, the adsorbed substances are removed due to the achievable with the heated secondary desorption from the first segment. At the same time, substances from the process air are adsorbed with the at least one second segment.

For desorption, it is preferable to heat to a temperature above 100 ° C. in order to be able to safely kill pathogens in the sorption body and the secondary air.

By means of an irradiation device, electromagnetic radiation is directed in the region of the ultraviolet light with a defined intensity and for a defined duration on dried air emerging from the sorption body.

The dried air can be passed through another filter, which is used to influence the duration of the irradiation. In addition, the electromagnetic radiation can alternatively or additionally be directed to the surface of the further filter.

The sorption body can be cooled and / or rinsed in a third segment following in the direction of rotation of the first and the second segment by passing a non-heated partial flow of the secondary air.

With the device according to the invention and the method which can be carried out with it, moist gases can be dried and pathogens contained therein can be killed.

The invention will be explained in more detail below with reference to an example. Showing:

1 a basic structure of an example of a device according to the invention.

In an exemplary embodiment of a device according to the invention moist process air P by means of a supply 4 through a first filter 12 guided and then in a cooling device 13 cooled to a temperature of 10 ° C. Thereafter, it becomes a first segment of a sorbent body rotating about a rotation axis 1 guided. The sorbent body 1 is as a first module of a housing 9 surround. In the first segment of the sorbent body 1 in particular, the adsorption of water contained in the process air takes place.

The dried air is passed through a pipe 11 in a second module with an irradiation device 3 and another filter 14 guided. They are from a housing 10 , which is made of stainless steel, enclosed. From the irradiation facility 3 UV-C radiation with a wavelength of 264 nm for a duration of 0.5 s is applied to the dried air and the surface of the further filter which has flowed over it 14 directed to kill contained therein or there attached pathogens. The other filter 14 is loaded with activated carbon. Due to the carbon contained in it, ozone formed in the UV irradiation in the dried air reacts to CO ₂ and oxygen.

Following the irradiation, the dried air A freed of pathogens is passed through a conduit 8th dissipated.

A secondary air S is sent by a pipe 5 through a heat exchanger 15 to a heater 2 guided. There, the secondary air S is heated to a temperature in the range of 110 ° C to 140 ° C. Subsequently, she is through a line 6 in a direction opposite to the process air P direction through a second segment of the sorbent body 1 guided.

As a result of the rotation of the sorbent body 1 The area loaded with adsorbed substances in the first segment was moved into the area through which the heated secondary air S flows. This achieves desorption of the previously adsorbed water. The air laden with the desorbed water is passed through a pipe 7 to the heat exchanger 15 guided. There, thermal energy of the air laden with the desorbed water is transferred to the supplied secondary air. Thereafter, the laden with the desorbed water air is removed. By acting at the desorption temperature pathogens can be killed in the secondary air.

As another filter 14 In particular, an activated carbon filter or a filter loaded with activated carbon can be used. With the other filter 14 there is a throttling of the flow of the dried process air P, whereby the time of irradiation can be influenced. Depending on the permeability of the other filter 14 and the prevailing dynamic pressure can be the size of the area of the further filter through which the process air P flows 14 be chosen so that a sufficient time for the killing of pathogens time for the irradiation is given.

The irradiation time of the process air can also be influenced by the geometry of the flowed-through space.

Claims (13)

Device for drying a process air and killing pathogens contained therein, with a supply ( 4 ) for process air (P) to a first segment of a cylindrical, rotating about a rotation axis sorption body ( 1 ), and a feeder ( 5 ) of secondary air (S) to a heating device ( 2 ) and a line ( 6 ), with the heated secondary air (S) from the heater ( 2 ) to at least a second segment of the sorbent body ( 1 ) can be supplied and flows through the at least second segment of the sorbent body, wherein first in the region of the first segment of the sorption body ( 1 ) adsorption of substances contained in the process air, and as a result of the rotation of the sorbent body ( 1 ) this first segment of the sorbent body ( 1 ) in the area in which the heated secondary air (S) the sorption body ( 1 ) flows through the adsorbed substances due to the desorption with the heated secondary air (S) from the first segment of the sorbent body ( 1 ) are removable, and the at least one second segment of the sorbent body ( 1 ) in the area of the feeder ( 4 ) for process air (P) and with the at least second segment adsorption of substances from the process air (P) takes place, a line ( 7 ) for discharging the secondary air (S) loaded with the substances desorbed from the sorption body (S), and an irradiation device emitting electromagnetic radiation in the region of the ultraviolet light ( 3 ), wherein the irradiation device ( 3 ) is arranged in the direction of the process air (P) guided through the sorption body (S) after the sorption body (S) and the electromagnetic radiation is directed onto the dried air (A), and a line ( 8th ) for the removal of the dried air which has been freed from pathogens (A). Device according to claim 1, characterized in that the sorption body ( 1 ) in a first housing ( 9 ) and the irradiation device ( 3 ) in a second housing ( 10 ) and via a line ( 11 ) are interconnected. Apparatus according to claim 1 or 2, characterized in that the irradiation device ( 3 ) in the flow direction of the dried air (A) downstream of another filter ( 14 ) is arranged, through which the dried air (A) is guided. Apparatus according to claim 3, characterized in that the further filter ( 14 ) and / or one introduced therein as a filter medium bed with activated carbon is loaded. Device according to one of the preceding claims, characterized in that the intensity and the duration of the electromagnetic radiation can be controlled and / or regulated. Device according to one of the preceding claims, characterized in that the electromagnetic radiation used has wavelengths in the range of 100 nm to 300 nm. Device according to one of the preceding claims, characterized in that the housing ( 10 ) is made with a reflective inner surface and / or stainless steel. Device according to one of the preceding claims, characterized in that the heating device ( 2 ) of a region of the sorption body ( 1 ) enclosing housing ( 9 ) and / or is formed with elements within the sorbent body. A process for drying process air and killing pathogens contained therein with an apparatus according to any one of the preceding claims, wherein process air (P) passes through a first segment of a cylindrical one about an axis of rotation rotating sorption body ( 1 ) and by adsorption on / in the sorption body ( 1 ) and secondary air (S) by means of a heating device ( 2 ), preferably preheated to a temperature of at least 90 ° C and at least a second segment of the sorbent body ( 1 ) flows through, so that a desorption of with the sorption ( 1 ) is reached from the process air (P) adsorbed substances, wherein due to the rotation of the sorbent body ( 1 ) in a first segment of the sorbent body ( 1 ) adsorption takes place and, after further rotation, the adsorbed substances become due to the desorption with the heated secondary air (S) from the first segment, and adsorbed with the at least one second segment substances from the process air, and by means of an irradiation device ( 3 ) electromagnetic radiation in the range of ultraviolet light with a defined intensity and for a defined period of time from the sorption body ( 1 ) exiting dried air (A) is directed. Method according to claim 9, characterized in that the sorption body ( 1 ) supplied process air (P) by a first filter ( 12 ) and / or a cooling device ( 13 ) is passed before a segment of the sorbent body ( 1 ) is flowed through. A method according to claim 9 or 10, characterized in that the dried air (A) is passed through a further filter, with which an influence on the duration of the irradiation is achieved. Method according to claim 11, characterized in that by means of an irradiation device ( 3 ) is directed electromagnetic radiation in the range of ultraviolet light in a defined intensity and for a defined duration on at least one surface of the further filter. Method according to one of claims 9 to 12, characterized in that the sorption body ( 1 ) is cooled and / or rinsed in a third segment following in the direction of rotation of the first and the second segment by passing a non-heated partial flow of the secondary air (S).

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