WO2012045367A1

WO2012045367A1 - Method and arrangement for increasing the concentration of negative ions in a closed space

Info

Publication number: WO2012045367A1
Application number: PCT/EP2010/065099
Authority: WO
Inventors: Rudolf Weyergans; Rudolf Rotmann
Original assignee: Rudolf Weyergans; Rudolf Rotmann
Priority date: 2010-10-08
Filing date: 2010-10-08
Publication date: 2012-04-12
Also published as: EP2596556A1; EP2596556B1

Abstract

The invention relates to an arrangement for increasing the concentration of negative ions in the breathing air of a closed space. In order to make possible a more uniform distribution of the negative ion concentration inside the space without exceeding the permissible limits for ozone in the breathing air, the invention proposes that - at least one conductor pair is arranged in the closed space, - the conductor pair has a first non-insulated conductor, which is switched as the anode, and a second non-insulated conductor, which is switched as the cathode, with the first and second conductors being arranged mutually parallel at a distance, - a voltage source with an output voltage of between 5 kV - 10 kV is connected to the first and second conductors and - the distance between the first and the second conductor is between 10 - 30 mm.

Description

Method and arrangement for increasing the concentration of negative ions in a closed space

The invention relates to an arrangement and a method for increasing the concentration of negative ions in the breathing air of a closed space.

The breathable air contains about 21% oxygen (O ₂ ). From this oxygen the lungs take up about 25% and

transport it via the blood into the capillaries and to the cells. Depending on the environment, negative air ions in a concentration of 200 to 4000 per cm ³ respiratory air are contained in the respiratory air. Especially in closed rooms, like

For example, conference and seminar rooms, is the

Concentration in the lower range. If in the

With the length of time a person lives, the concentration of negative ions is reduced because they are released from the breathed oxygen to the organism of the persons. As a result, people in closed rooms are often prematurely exhausted, tired and unfocused, since the organism, especially the brain, no sufficient energy

Available .

With known Luftionisationsgeräten negative ions are only selectively generated within the room. The

Ambient air is delivered from an inlet through an electric field to an outlet of the air ionization apparatus. In the electric field, the gas ionization occurs at the value of the field at which the gas atom or gas molecule on the so-called free path length reaches an energy which is greater than the ionization energy of the gas itself derived particles. The voltage causing such a field strength - also called threshold voltage - depends mainly on the shape and placement of the

From each other electrodes. A disadvantage of the known

Luftionisierungsgeräten is that the negative ions discharge very quickly behind the field again and therefore only occasionally an increase in the concentration of negative ions

takes place. From DE 28 09 054 C2, for example, as a

Air ionization device with a device connected to a high voltage source and a spaced from the wire, on a

High voltage potential of the same polarity lying and the wire partially surrounding reflector screen known. Of the

Reflector screen to improve the emission of negative ions by the unwanted charging of surrounding components and the associated potential drop are avoided around the emission wire.

Also, this prior art does not change the disadvantage that in closed rooms, especially in larger

Conference and meeting rooms, the negative ions are not effective over the entire room in an optimal concentration

be distributed. As a result, the negative ions can have their beneficial effect on the well being in the

unfold persons located only in the immediate vicinity of Luftionisationsgerätes. Another disadvantage of the prior art is that in the endeavor a sufficient concentration of negative ions in the breathing air of the closed space to In many cases, too high concentrations of negative ions per cm ^{3 of} respiratory air are generated, resulting in an exceedance of the permissible levels

Maximum ozone levels above 0.2 ppm.

Based on this prior art, the invention is therefore the object of an arrangement and a method for increasing the concentration of negative ions in the

To suggest breathing air of a closed space, which allows a more even distribution of the negative ion concentration within the room without exceeding the permissible limits for ozone in the breathing air.

The solution is based on the idea to move away from only locally effective Luftionisationsgeräten and integrated into the closed space arrangement of conductors

suggest that causes the production of negative ions. The conductors are arranged over a large area, in particular space-spanning, and therefore emit ions evenly into the respiratory air, without producing too high ion concentrations locally.

In detail, the task is in an arrangement of

in the aforementioned type achieved in that at least one pair of conductors is arranged in the closed space, the

Pair of conductors a first connected as an anode, not

insulated conductor and a second connected as a cathode, non-insulated conductor, wherein the first and the second conductor are arranged at a distance parallel to each other, at the first and second conductor, a voltage source with an output voltage between 5 kV - 10 kV is connected and the distance between the first and the second

Head is between 10 - 30 mm. With the aid of the pair of conductors arranged directly in the breathing air of the closed space, the negative ions can be emitted in the entire room, but at least in large parts of the room. For the delivery of the negative ions to the

Breathing air in the closed space requires that the pair of conductors comprise a first non-insulated conductor connected as an anode, and a second non-insulated conductor connected as a cathode, wherein the first and second conductors are spaced apart in parallel. For optimal release of the negative ions are elongated electrical conductors, in particular cables, wires or electrically conductive rods or rods. In the closed space at least one pair of conductors is arranged. Depending on the size, however, several pairs of conductors in the room can be clamped to a uniform as possible

To generate concentration of negative ions. The conductor pairs can be clamped, for example, in a plane of the room parallel to the floor and / or ceiling surface, but also in different spatial levels with intersecting course.

To generate a sufficient amount of negative ions in the breathing air of the closed space, but one

To avoid exceeding the ozone levels, is at the first and second conductor, the voltage source with the

Output voltage between 5 kV to 10 kV connected, wherein the distance between the first and second conductor is between 10 - 30 millimeters. If the aforementioned distance is exceeded, too little negative ions are produced, while too small a distance between the conductors, the ozone levels increase too much. The distance between the first and second conductors is preferably determined such that a concentration of the negative ions in the respiratory air between the first and second conductors between 5,000,000 to 10,000,000 negative ions per cm ^{3 of} breathing air. For an output voltage of 5 kV, the distance between the first and second conductors is between 10 and 20 millimeters to achieve an optimum negative ion concentration, while at a

Output voltage of the voltage source at the upper limit of 10 kV, the distance between the first and second conductor is 15-30 millimeters, in order to achieve an optimum concentration of the negative ions in the breathing air. Dodge the

Concentration of the negative ions from the optimum value, there is a danger of the formation of free radicals.

The voltage source of the device preferably has means for limiting the maximum current flowing to at most 2 mA, preferably to at most 0.5 mA, in order to avoid injury to the persons present in the closed room by unintentionally touching the non-insulated conductors.

The non-insulated metallic conductors are made

preferably of an oxide-free, but at least low-oxide metal. Particularly preferably, the conductors consist of a noble metal, in particular gold or gold threads. One

Alternative preferred conductor material is tungsten.

In order to achieve the widest possible distribution of the negative ions in the closed space, preferably all conductor pairs are arranged in the closed space such that they extend over at least half of the Length of one of the spatial axes extend. Preferably

The pairs of conductors extend over the entire length of one of the spatial axes. This means that the pair of conductors extends, for example, in a rectangular space over its entire width or length or even over its entire height from floor to ceiling. However, good results are already achieved when the

Pair of conductors extends over at least half the length of one of the spatial axes.

A particularly preferred arrangement of the conductor pairs takes place in an imaginary plane parallel and close to the

Ceiling surface of the room along one of the spatial axes, as a result of the freedom of movement within the room by the inventive arrangement of conductors not

is restricted. The connecting cables, which connect the conductors of the pair of conductors to the voltage source, can be routed especially in the area of the walls of the room. Visually appealing the connection lines can also be guided by a passage in a suspended ceiling of the room and connected to a concealed voltage source, which is located for example above the suspended ceiling. Starting from the pair of conductors are distributed there

generated negative ions due to the natural

Air movement, especially as a result of convection, in the rest of the room. As a result, the negative ions are inevitably absorbed by the people staying in the room and increase their well-being, in particular their ability to concentrate. To be even better

Distribution of the conductor pair or conductor pairs To produce generated ions within the space, the arrangement comprises in an advantageous embodiment of the invention means for generating an air movement, in particular

at least one fan, which is preferably arranged in the vicinity of the conductor pairs. By aligning the

Fans can specifically target the airflow

Common areas in the closed room,

for example, workplaces. The invention will be explained in more detail with reference to FIG 1.

FIG. 1 shows the plan view of a closed room (1), for example a seminar room with a door opening (2) and a window opening (3). In particular, when the door and window opening (2, 3) closed sinks in a seminar in which several people in the room, the

Concentration of the negative ions significantly, whereby the performance, in particular concentration ability of the persons in the room decreases.

The space (1) is through the opposite

frontal walls (4 a, b) and the side walls (5 a, b) limited. At the front-side walls (4 a, b) are located at a small distance below the ceiling, for example, at a distance of about 10 - 20 centimeters to the ceiling, two wall brackets (6 a, b) at which a first conductor (7 a) and a second conductor (7 b) of a

Fix the pair of wires (7). The conductor pair (7) extends over the entire longitudinal axis of the space (1) between the end walls (5 a, b). Due to the considerable width of the room (1) are in the present Embodiment two pairs of conductors between the end walls (4 a, b) spanned. As a result, a particularly uniform concentration of the negative ions generated by the conductor pairs (7) results within the space (1).

The first and second conductors (7a, b) of each of the two

Conductor pairs (7) is connected via connecting lines (8 a, b) to a voltage source (9), which in the illustrated embodiment of a power supply (9 a) and a

High voltage generator (9 b) exists. The power supply (9 a) is on the primary side to the house power supply (230 V / 50 Hz)

connected. On the secondary side is a DC voltage of 12 V, which formed in the cascade

High voltage generator (9 b) is set to 10 kV, which is applied to the terminals (10 a, b) of the high voltage generator (9 b). The high voltage generator (9 b) comprises means for limiting the maximum current flowing to 0.5 mA. The voltage of 10 kV is applied via the connection lines (8 a, b) to the two conductor pairs (7). The not shown to scale in the figure distance (14) between the first conductor (7 a) and the second conductor (7 b) each

Conductor pair (7) is 30 millimeters in the illustrated embodiment. As a result, between the executed as wires first and second conductors (7 a, b) a

Concentration between 5,000,000 to 10,000,000 negative ions per cm ³ breath produced. To improve the distribution of the between the conductors (7 a, b) respectively generated negative ions between the two pairs of conductors (7), a fan (11) is arranged, the one Air movement generated in the room (1). The fan (11) is supplied via connecting lines (12 a, b) with the DC voltage in the amount of 12 V of the power supply (9 a). Depending on requirements, the fan (11) can be switched on and off by means of the switch (13).

LIST OF REFERENCE NUMBERS

No. Designation No. Designation

1 room 8a, b connecting cable

2 door opening 9 power source

3 window opening 9a power supply

4a, b end walls 9b high voltage generator

5a, b side walls 10a, b clamps

6a, b wall brackets 11 fan

7a first conductor 12a, b connecting cables

7b second conductor 13 switch

7 pair of wires 14 distance

Claims

Arrangement for increasing the concentration of negative ions in the respiratory air of a closed room,

characterized in that at least one pair of conductors (7) in the closed space (1) is arranged, the conductor pair (7) has a first as the anode

switched, non-insulated conductor (7a) and a second connected as a cathode, non-insulated conductor (7b), wherein the first and the second conductor (7a, b) at a distance (14) are arranged parallel to each other that at the first and second conductor (7a, b) a voltage source (9) having an output voltage between 5 kV - 10 kV is connected and the distance (14) between the first and the second conductor (7 a, b) is between 10 - 30 mm.

Arrangement according to claim 1, characterized in that at least one conductor pair (7) is arranged in the closed space such that it extends over at least half the length of one of the spatial axes.

Arrangement according to claim 1 or 2, characterized in that the distance (14) between the first and the second conductor (7a, b) is determined such that between the first and second conductors (7a, b) a concentration of the negative ions in the air between 5 million - 10

Millions of negative ions per cubic centimeter of respiratory air. Arrangement according to one of claims 1 to 3, characterized in that the voltage source (9) has means for limiting the maximum current flowing to at most 2 mA.

5. Arrangement according to one of claims 1 to 4, characterized

characterized in that the first and / or second conductor (7a, b) consist of oxide-free metals.

Arrangement according to one of claims 1 to 5, characterized in that the first and / or second conductor (7a, b) consists of a noble metal.

Arrangement according to one of claims 1 to 6, characterized in that the first and / or second conductor (7a, b) consists of tungsten. 8. Arrangement according to one of claims 1 to 7, characterized in that the arrangement comprises means for generating an air movement (11) in the closed space.

9. A method for increasing the concentration of negative ions in the breathing air of a closed room,

characterized in that a non-insulated first conductor (7a) and a non-insulated second conductor (7b) of a conductor pair (7) at a distance between 10 - 30 mm parallel to each other in the closed space (1)

are attached and to the anode connected to the first conductor (7a) and the cathode connected to the second conductor (7b), a voltage between 5 kV - 10 kV is applied.

A method according to claim 9, characterized in that the conductors (7a, b) are arranged over at least half the length of one of the spatial axes.