AT516431B1 - drying device - Google Patents

Abstract

The invention relates to a drying device for drying buildings comprising a blower device (12) arranged in a housing, which is connected to a flexible line (1) for transporting the drying air out of the housing, wherein at the free end of the line (1) Outlet opening (7) is arranged, and an ionizer (5) for generating air ions and / or ozone in the drying air. The ionizer (5) is arranged in the free end of the line (1) facing away from the blower device (12) immediately adjacent to the section having the outlet opening (7), and that the ionizer (5) has a current generator (3) which via a wind turbine (2) or a turbine, which is (s) disposed within the conduit (1) for air transport, is drivable.

Description

Description: The invention relates to a drying device for drying buildings comprising a blower device arranged in a housing, which is connected to a flexible line for transporting the drying air out of the housing, an outlet opening at the free end of the line is arranged, and an ionizer for generating air ions and / or ozone in the drying air.

In the drying of buildings or components, there is often the problem that it comes to a contamination of the wet components, in particular organic materials such as plastics or wood. Even small traces of organic materials in buildings are enough to create a massive mold load.

As a solution, it is attempted to influence the microbial contamination by means of ozone. Larger buildings that require drying require long air ducts to carry hot air to bring the heat to the desired locations. Ozone generators are known in the air blowers, but the ozone disintegrates quite quickly and the effect on the Einblasstelle, which is partly far away from the blower, is significantly reduced. The same is true of ionization: its advantage is the charging of particles by the free electrons in the air, which binds very small particles normally floating in the air, such as fungal spores, to arbitrary surfaces. Also for the ionization it applies that with long distribution lines a big part of the effect is lost.

In JP H10249097 A, AN 201692365 DU and JP 2002191681 A devices for drying, disinfecting and / or deodorizing Trocknungsgiitern Or closed-off premises, such as the interior of motor vehicles, described in which inter alia Ozone Or ionized gases are routed via a hose or into the drying area.

In the JP H10249097 A this air is sucked from the outside into a housing, heated after the blower, ionized by means of electrodes or ozone is generated, passed over dihedrons into a tube and passed from this fiber or in the drying area.

In the CN 201692365 U, the subject of the application consists of a housing in which two air streams are sucked. In one of these, ozone is generated by means of electrodes. Subsequently, the two air streams are still combined in the housing and blown by means of a hose in the interior of a motor vehicle.

The device according to JP 2002191681 A has an oxygen supply, for example a pressure bottle, and a compressor for the air supply. The oxygen is partially converted into ozone by plasma discharge and the sucked air is first dried. The thus pretreated gas streams are first separated, i. for example, coaxially, routed out of the apparatus via a hose and united together in a Diisenvorrichtung immediately before exiting into a space to be dried.

In all the above-mentioned documents, the disadvantage already described results in that the generation of ozone or ionized gas does not take place immediately before exiting the hose. On the one hand, said devices have an increased space requirement and can not be operated independently of a power source in a compact design.

It is therefore an object of the present invention to provide a drying device to sheep-fen, which eliminates the disadvantages mentioned above, is inexpensive to produce and operable and improves the lonisationsgrad the drying air at the site.

This object is achieved in that the ionizer is disposed in the remote from the fan device free end of the line immediately adjacent to the outlet opening portion having, and that the ionizer fiber has a power generator, which via a wind turbine or a turbine, which within the

Line for the air transport is arranged, can be driven. In order to avoid the ozone transport through the long lines, it is proposed that the ozone or lonisationsgenerator, hereinafter called ionizer, in the line near the outlet opening, for example, in a blow-Diise Or the connector to install Diisse. Thus, the ozone or the ions only have to travel a distance of a few centimeters to decimetres until they reach the point of use. In order to avoid the power lines altogether, it is intended to use the air flow in the line for the drying air as an energy source.

By developing very efficient ionizers with less than 5 watts of electrical power consumption, this proportion of energy can be obtained from the air stream, without any detriment to the function of the drying. The ionizer thus forms a completely autonomous construction part which, depending on the application, can be used modularly with existing blower devices.

Another feature of the invention is that the ionizer is a Kleinspannungsionisa-gate, which is operable with a maximum voltage of 42 volts. The required ionizer can be made very small so that it can be accommodated in the line. This eliminates the expensive cables and protective devices for the otherwise used high-voltage ionizers. It suffices a thin low voltage line for the supply of the ionizer with a low voltage below 42 volts. The use of low voltages offers the great advantage that the risk potential of the current and damage caused by a cable supply is considerably reduced.

As a further feature of the invention, it is provided that the free end of the line from the ionizer to the outlet opening is formed in the form of a Diise whose inside is electrically insulated and the outside of which at least partially electrically conductive material having over a connecting portion with is connected to the ground terminal of the ionizer. If an above-mentioned autonomous ionizer is used, a corresponding grounding is required for the ionizer. The internal insulation prevents accumulation of the free electrons already in the area of the nozzle, while the external, conductive coating forms the grounding via a contact with, for example, a building wall. If this grounding is ignored, then relatively high, static charges of the Diise can take place. These are not immediately hazardous to humans because of their low capacity, but they can liberate gases or dusts when they are overheated. Although the ionization currents are relatively low, in the range of a few microamps, the charge can accumulate in the region of the generator. In any case, provide sufficient grounding.

Another feature of the invention is that the ionizer and / or the Gebläsevor- direction has / have a control unit, and that a freely placeable sensor is provided for measuring the ionisationsgrads degree of air at the point to be treated, wherein the data from the sensor to the control unit (s) are available, which in turn controls the ionizer or the blower device on the basis of the received data in comparison with preset values. It is also proposed to control the ionization rate or the release of ozone as needed. For this purpose, a sensor is provided in the treated room, which measures the ionization degree or the ozonization at a location other than the outlet opening. For the measurement measuring chambers are provided, with which the conductivity of the air can be determined by ions. The air to be measured is moved through the measuring chambers with a small blower. The conductivity of the air provides the measure of the ionization, the sensitivity being sufficient to detect critical values for a workstation and to control the ionization or ozonization. In addition, the air temperature and humidity are measured on site. This will ensure that in critical applications such as museums, libraries, cultural-historical buildings, and the like, full control in the most vulnerable areas is possible. The power supply for the sensor can be done via storage elements such as batteries or accumulators, but also via the power grid or other, alternative power sources.

According to an embodiment of the present invention, the communication connection between the sensor and the control unit is wireless. The data connection between control unit of the ionizer and sensor takes place by means of near-field communication (NFC). Again, every line on a construction site is a problem, while an NFC brings complete freedom in positioning the sensor. The control unit has the task of switching off the ionizer when critical values can be preselected by the user depending on the application. This control unit can also control the air conditioning by the blower or an air heater, and thus the temperature and air volume. Accordingly, several different sensors can be in communication with the control unit.

For the transmission of information all wireless options are provided, such as sound, light, radio, etc. It may also be provided to record the measurements from the sensors and to save as evidence of the treatment. A connection to the Internet for measurement and control purposes is also envisaged for the purpose of controlling and / or controlling a large number of devices from a distance.

Finally, it is a feature of the present invention that the communication link between the sensor and the control unit is conducted. As a simple, cost-effective alternative Or in applications where a wireless connection is not possible, the communication link can also be established over a single line.

The invention will now be described in more detail with reference to the attached figures, wherein Fig. 1 shows a schematic sectional view of the line in the region of the outlet opening with an ionizer disposed therein, and Fig. 2 shows a schematic representation of a drying device with freely anordenba - rem measuring sensor shows.

Constructively, the ionizer 5 consists of a housing with the generator 4 and an arrangement for emitting the electrons with tip electrodes 6. The housing itself has holes for the air, which leads to the tip electrodes 6 and the both the electrons for ionization , as well as derive the ozone.

Fig. 1 shows schematically a possible embodiment of an autonomous ionizer 5, which is installed in the line 1 for the air transport of a drying plant directly angren-zend to the outlet opening 7. The section from ionizer 5 to the outlet opening 7 is designed as a nozzle 8 in the example shown. The ionizer 5 has a wind turbine 2, which is connected to a power generator 3. The power generator supplies the high-voltage part 4 of the ionizer, which in turn is equipped with needle electrodes 6 in order to discharge the charges into the passing gas. The needle electrodes 6 are exemplary of the known types of ozone generation and ionization. The entire ionizer 5 is fastened with at least one connecting portion 10 in the conduit 1, wherein the connecting portion 10 has an electrically conductive connection to an externally attached to the Diise 8, electrically conductive layer. The arrow 9 shows the flow direction of the air flow.

Fig. 2 shows schematically the arrangement of the control means of sensor. The blower device 12 may also have a heater for heating the drying air in addition to a fan. Starting from the blower device 12, the line 1 is provided for air transport, at the end of which the ionizer 5 is arranged directly adjacent to the outlet opening 7. Both the ionizer 5 and the fan device 12 each have a control unit in the example shown. The information from a sensor 11 which determines the degree of ionization of the air is exchanged in this embodiment via the wireless connections 14 between the ionizer 5, the blower device 12 and the sensor 11. In addition to the sensor for determining the degree of ionization, further sensors can be provided, for example for determining the temperature or the air humidity, which also exchange data with the control units.

In the exemplary illustration, only one drying device has been shown. For larger rooms or entire buildings also several drying devices and sensors may be provided, which are interconnected in corresponding pairings. The desired limits for the individual measured parameters can be preset at the drying device and serve the control unit in comparison with the data determined by the sensors for controlling the device.

Claims (6)

claims: 1. drying device for drying buildings comprising a housing arranged in a fan device (12) which is connected to a outgoing from the housing flexible conduit (1) for the transport of the drying air, wherein at the free end of the conduit (1) has an outlet opening ( 7), and an ionizer (5) for generating air ions and / or ozone in the drying air, characterized in that the ionizer (5) in the free end of the line (1) facing away from the fan device (12) immediately adjacent to the outlet opening (7) having portion is arranged, and that the ionizer (5) has a power generator (3) which via a wind turbine (2) Or a turbine, which (s) within the conduit (1) for the air Transport is arranged, is drivable. 2. Drying device according to claim 1, characterized in that the ionizer (5) is a low-voltage ionizer, which is operable bar with a voltage of 42 volts maximum. 3. Drying device according to claim 1 or 2, characterized in that the free end of the line (1) from the ionizer (5) to the outlet opening (7) in the form of a Diise (8) is formed, the inside of which is electrically insulated and the outside thereof at least sectionally comprises electrically conductive material, which is connected via a Verbindungsab-section (10) with the ground terminal of the ionizer (5). 4. Drying device according to one of claims 1 to 3, characterized in that the ionizer (5) and / or the blower device (12) has / has a control unit, and in that a freely positionable sensor (11) for measuring the ionization The data from the sensor (11) to the control unit (s) can be transmitted, which in turn on the basis of the received data in comparison with preset values, the ionizer (5) or the blower before direction (12) controls. 5. Drying device according to claim 4, characterized in that the communication connection (13) between the sensor (11) and the control unit is wireless. 6. Drying device according to claim 4, characterized in that the communication connection (13) between the sensor (11) and the control unit is wired. For this 1 sheet drawings