RU2778068C2 - Ionizer equipped with ion flow accelerator, in particular, for protection from mosquitos - Google Patents

Abstract

FIELD: medical equipment.

SUBSTANCE: invention relates to medical equipment, namely to device (1) for air ionization. The device contains case (2) containing fan (7), which contains rotor (8) for generation of a pulsating air flow, and exhaust pipe (9) for direction of the specified flow. The case includes device (14) for ion production, which contains high-voltage electric generator (15), electrode (16) connected to generator (15). Free end (17) of the electrode, formed of a bundle of threads (18) made of conductive material passes to the right from exhaust pipe (9) for release of ions due to a corona discharge. The device additionally contains diffusor (38) equipped with pipe (39), which passes in the elongation of exhaust pipe (9) and determines boundaries of compression chamber (40). The diffusor has expander (41), which elongates pipe (39) and contains a number of channels (42), which pass from inner side (43) of expander (41), adjacent to compression chamber (40), in the direction to opposite outer side (44).

EFFECT: ionizer, capabilities of which are increase due to moderate electricity consumption, which allows for diffusion of ions into a significant volume.

10 cl, 6 dwg

Description

The invention relates to the field of ionizers.

Ionizers are usually used for air purification. The principle, quite simple, is based on a corona discharge: one electrode (or several) connected to a high voltage (and low intensity) source causes ionization of the environment, accompanied by electrical discharges.

In practice, the electrode may be formed (on at least one free end) of very thin filaments (eg, made of glass or carbon fiber, treated to conduct electricity). These filaments are in the purge airflow which removes the ions.

Ions bind to particles suspended in the air, which contributes to their lowering to the ground.

A typical ionizer using this technology is described in US Patent US5268009.

It has recently been discovered that an ionizer can help keep insects (particularly Diptera) normally attracted by body odor (particularly female mosquitoes) at bay. Indeed, these body odors are carried by particles (particularly sweat), which proves the possibility of gliding to the ground under the action of binding with ions coming from the ionizer.

In other words, with the help of an ionizer, it is possible to continuously deodorize a person (or animal) in contact with insects (in particular, mosquitoes). A person (or animal) who has become somehow invisible to them is protected from their proboscis (or stings).

It has been suggested that the ionizers be worn around the neck or on the wrist. Wearing ionizers, however, is limited and cannot protect multiple people at the same time.

To increase the wear of the ionizer, the simplest thing is to increase the purge power. But this leads to an increase in the consumption of electricity by the ionizer, which is incompatible, in particular, with prolonged use when traveling or in areas without an electrical supply.

Therefore, the first object of the present invention is to provide an ionizer whose performance is enhanced by a moderate consumption of electricity.

The second object of the invention is to provide an ionizer that allows the ions to diffuse into a significant volume, in particular with the aim of making people in this volume invisible to the sense of smell of insects and, in particular, mosquitoes.

For this purpose, an air ionization device (ionizer) is proposed, which contains a housing and in this housing:

- a fan that includes a rotor to generate a pulsating air flow and an exhaust pipe to direct this flow;

- a device for obtaining ions, which contains:

∙ high voltage power generator;

∙ at least one electrode connected to the generator, and the free end of the electrode, formed from a bundle of threads made of conductive material, extends to the right of the exhaust pipe, to release ions due to corona discharge;

- diffuser equipped with:

∙ a pipe that extends into the exhaust pipe extension and defines the boundaries of the compression chamber, and

∙ an expander that extends this pipe and contains a series of channels that extend from the inside of the expander, adjacent to the compression chamber, towards the opposite outer side.

The diffuser has the property of accelerating the airflow that passes through it, increasing the capacity (and therefore efficiency) of the ionizer.

Various additional features may be provided individually or in combination. Thus, for example:

- These channels will propagate from each other from the inside of the expander to its outside.

- Each channel tapers from the inside of the dilator to its outside.

- The ionizer contains a metal ring surrounding the free end of the electrode.

- This metal ring has an expanding part (in particular, a conical or pyramidal shape) that surrounds the bundle of electrode filaments.

- A metal ring is attached to the electrode.

- The metal ring is made of copper.

- The metal ring is silver on the surface.

- The body contains a base and a cover provided with perforations at least to the right of the diffuser.

- The ionizer contains an electronic control board equipped with a switch for opening or closing the electric power supply circuit of the generator, and the housing is equipped with a button connected to this switch.

Other objects and advantages of the present invention will become apparent from the description of the embodiment given below with reference to the accompanying drawings, where:

- Fig. 1 is an exploded perspective view showing an air ionization device;

- Fig. 2 is an exploded perspective view showing the fan and its associated diffuser;

- Fig. 3 is a partial sectional view showing the fan and its diffuser in assembly;

- Fig. 4 is a sectional view of the fan and diffuser along the section plane IV-IV in Fig. 3;

- Fig. 5 is a sectional view along the plane V-V in Fig. 4;

- Fig. 6 is a partial sectional view showing the assembled ionization device.

Figure 1 shows an air ionization device, hereinafter simply referred to as an ionizer 1. This ionizer 1 is designed to produce one or more pulsating streams of ions to combine with airborne particles of opposite electric charge.

Molecules (or groups of molecules) formed by the combination of pulsating ions and particles are heavy and plan to the ground under the influence of their mass.

The ionizer 1 is advantageously designed to generate negative ions (anions), typically CO ₃ ions. Below will show how.

The ionizer 1 contains, firstly, a body 2.

In the illustrated example, the housing 2 comprises a base 3 and a lid 4.

The base 3 can rest on a support (eg a table), be attached to a wall or partition (surface mount) or also be attached to the ceiling (ceiling mount).

In the illustrated example, the base 3 has a substantially square edge (with preferably rounded corners).

The lid 4 is predominantly pyramidal, coinciding with the edge of the base 3.

Together, the base 3 and the cover 4 define the internal volume 5, in which the various components of the ionizer 1 are located.

The lid 4 is provided with holes 6. These holes 6 are designed to allow air to pass through the lid 4.

Secondly, the ionizer 1 contains at least one fan 7. This fan 7 includes a rotor 8 to generate a pulsating air flow and an exhaust pipe 9 to direct this flow.

In the illustrated example, the fan 7 is in the form of a fan. The fan 7 comprises, in this case, a housing 10 (here cylindrical) in which a rotor 8 is rotatably mounted. The housing 10 carries a stator (not shown) energized and designed to generate a rotating magnetic field to turn the rotor 8.

In the illustrated example, the rotor 8 comprises a shaft 11 which, during the rotation of the rotor 8, generates an air flow.

According to the preferred embodiment shown in FIG. 1, the ionizer 1 comprises two fans 7. The fans 7 are installed, for example, one behind the other, i. the generated flows pulsate in opposite directions.

As shown in particular in FIG. 1, the housing 10 is equipped with an air inlet (here formed by an opening 13 just below the rotor 8). The exhaust pipe 9 is here formed by an opening made on the side of the housing 10. In the illustrated example, the exhaust pipe 9 has a rectangular (or square) section, but it may be round or oval.

Thirdly, the ionizer 1 contains an ion production device 14 which contains:

∙ high voltage generator 15;

∙ at least one electrode 16 connected to the generator 15, one free end 17 of the electrode, formed in the form of a bundle of threads 18 made of conductive material, passes into the exhaust pipe 9 to release ions by corona discharge.

The high voltage generator 15 is connected to an electrical voltage source (eg battery, cell or mains through a transformer). Generator 15 is designed to produce high voltage (a few thousand volts, even several tens of thousands of volts) and low intensity (a few milliamps, even a few microamps).

In the illustrated example, where the ionizer 1 contains two fans 7, the ion receiving device 14 contains two electrodes 16, each connected to the fan 7.

Each electrode 16 includes a conductor 19 connected to a generator. To minimize losses, conductor 19 is surrounded by a sleeve 20 (eg, made of a flexible insulating polymer) for at least part of its length. As can be seen in figure 2 and figure 3, the free end 17 of the electrode (ie the bundle of threads 18) is exposed.

Threads 18 may together form the conductor 19 along its entire length, or form only a part of the conductor 19, joining a wire (for example, metal) attached to the generator 15.

As can be seen in Fig.1 and Fig.5, fourthly, the ionizer 1 contains control electronics in the form of an integrated board 21, which includes electronic components and forms a circuit for electrical power supply of the generator 15.

In the illustrated example, the board 21 contains a transformer 22 adapted to generate a medium voltage (about 12 V) intended to power other components and fed by a high voltage generator 15.

The board 21 also contains terminals 23 to which conductors 24 are connected for the electrical supply of the generator 15, as well as conductors 25 for the electrical supply of this (or each) fan 7. More specifically, the electrical conductors 25 are connected to the stator of each fan 7.

Turning on the ionizer 1 can be controlled remotely, for example, by remote control (infrared or radio frequency) or by means of a remote switch installed in the power supply circuit of the ionizer 1.

The inclusion of the ionizer 1 can also be performed by direct action on it. Thus, according to the embodiment shown in Figures 1 and 5, the board 21 is equipped with a switch 26 for closing or opening the power supply circuit of the generator 15.

This switch 26 comprises, for example, a rod 27 mounted in a movement between a high position in which the circuit is open (generator 15 and each fan 7 are not electrically powered) and a low position in which the circuit is closed (generator 15 and each fan 7 are power supply).

From the point of view of architecture, as shown in figure 1 and figure 5, the generator 15 is mounted on the bottom wall 18 of the base 3. This (or each) fan 7 is mounted on a plate 29 (made of plastic material, for example). This plate 29 is fixed on the base 3. In the example shown, the plate 29 is mounted on the tubes 30, which protrude from the bottom wall 28 of the base 3. The plate 29 is fixed on the tubes 30, for example, using screws 31.

As shown in FIG. 1, each fan 7 is placed in a respective room 32 formed by projections on the plate 29. Each fan 7 is fixed to the plate 29, for example, with screws.

According to the preferred embodiment shown in Figures 1 and 5, the electronic board 21 is mounted on top of the fans. In this case, the board 21 is installed on the pins 33, which protrude from the plate 29. The fastening of the board 21 on the pins 33 is performed, for example, using screws 34.

In the illustrated example, the lid 4 is in the form of a truncated pyramid and is crowned with a cover 35, for example of a hemispherical shape.

A gap 36 is advantageously provided between the perimeter of the cover 35 and the cover 4.

This gap 36 may firstly form an air inlet for supplying fresh air to the fans 7.

Then, the gap 36 may form a passage for the light emitted by the operating light indicator of the ionizer 1, such as a light emitting diode (LED) 37 mounted on the electronic control board 21.

According to the preferred embodiment shown in Figures 1 and 5, in which the activation of the ionizer 1 is performed by direct manual action, the cover 35 forms a button connected to the switch 26. The action on the cover 35 (by simply pressing with a finger or hand) allows by means of the rod 27 of the switch 26 close or open the electric power supply circuit of the generator 15 and fans. According to the embodiment shown in FIG. 5, the cover 35 is forcefully inserted onto the rod 27, which thus supports it.

In operation, this (or each) rotor 8 generates a pulsating airflow through the exhaust pipe 9. The filaments 18 of the electrode 16 (powered at high voltage by the generator 15) generate electrical discharges (corona discharge), accompanied by the production of ions in large quantities. These ions are removed by the air flow and thrown out of the ionizer 1 through holes 6 of the cover 4.

To increase the capabilities of the ionizer 1, i.e. the distance at which ions are ejected, the ionizer 1 contains, fifthly, a diffuser 38 for each fan 7.

This diffuser 38 is equipped with:

∙ a pipe 39 which extends into the exhaust pipe extension 9 and defines the boundaries of the compression chamber 40, and

∙ expander 41, which extends the pipe 39 and contains a number of channels 42, which extend from the inner side 43 of the expander 41, adjacent to the compression chamber 40, towards the opposite outer side 44.

In the illustrated example, the diffuser 38 is a single piece, preferably made of a plastic material.

The pipe 39 has a section identical to or complementary to the exhaust pipe 9. Thus, in the illustrated example, the pipe 39 has a rectangular (or square) section.

The diffuser 38 may be fixed directly to the casing 10 of the fan 7. In the illustrated example, the diffuser 38 is equipped with a male nozzle 45 which protrudes from the pipe to force (or snap) into the exhaust pipe 9.

As shown in FIG. 2, the diffuser 38 and/or the fan 7 is provided with a cut-out 46 allowing the insertion (FIG. 2) and passage (FIG. 3) of the electrode 16 so that the bundle of filaments 18 extends to the right of the exhaust pipe 9. In the illustrated example diffuser 38 and housing 10 of fan 7 are provided with matching cutouts 46 which, when diffuser 38 is mounted on housing 10, together form an opening 47 through which electrode 16 passes, the filaments of which 18 thus extend into the connection between exhaust pipe 9 and pipe 39.

In the illustrated example (see in particular FIG. 3) there are nine channels 42, but this number is only indicative. Channels 42 may be less or more.

Channels 42 preferably diverge from each other from the inner side 43 of the expander 41 to its outer side 44. The sum of the flow areas of the channels 42 is less than the flow area of the exhaust pipe 9 (and pipe 39). Therefore, the air is compressed in the compression chamber 40 upstream and close to the inner side 43 of the expander 41.

As a result, the air velocity (charged with ions) is greater in the channels 42 than the air velocity in the exhaust pipe 9 (the air flow is shown by the white arrows in Fig. 5).

In other words, the diffuser 38 provides in the expander 41 the acceleration of the air flow entering through the inner side 43. As a result of this, the ions are ejected from the outside of the ionizer 1 to a distance greater than the distance they would be ejected without the diffuser 38. From this possibility (and, therefore, , efficiency) of ionizer 1 increase.

In addition, according to the preferred embodiment, each channel 42 tapers from the inner side 43 of the dilator 41 to its outer side 44, which also increases the effect of accelerating the flow and hence the capability of the ionizer 1.

Openings 6 in cover 4 extend at least to the right of this (or each) diffuser 38. This will ensure that each channel 42 opens to the right of opening 6 to minimize reflections of the escaping airflow. In the illustrated example, holes 6 are provided over the entire surface of the cover 4.

The outer side 44 of the dilator is preferably located as close as possible to the lid 4. According to a preferred embodiment, the outer side 44 of the dilator forms the interior of the lid 4.

To increase the density of ions produced at a given level of filaments 18, the ionizer 1 may include a metal ring 48 surrounding the free end 17 of the electrode 16.

This zero potential ring 48 creates an electrical ground that provides a reinforcing effect by increasing the number of electrical discharges (and hence ion production) at a given free end 17 level of electrode 16.

According to the preferred embodiment shown in FIGS. 2 and 3, the metal ring 48 has a flared portion 49 which surrounds the filament bundle 18 of the electrode 16. This flared portion 49 has the function of forming a tuft of filaments 18 that actually tend to diverge from each other. friend. According to the embodiment depicted in solid line in FIG. 2, the flared portion 49 of the ring is tapered. According to another embodiment, depicted in dotted line in FIG. 2, the flared portion 49 is pyramidal (polygonal based) and has a large number of sides (greater than or equal to three).

The metal ring 48 is preferably attached to the electrode 16. As shown in FIG. 3, the metal ring 48 is preferably inserted into the hole 47. The metal ring 48 may be made of copper. In one embodiment, the metal ring is silver on the surface. This can be presented in the form of weaving or mesh.

Claims (18)

1. Device (1) for air ionization, which contains a housing (2) containing: - a fan (7), which contains a rotor (8) for generating a pulsating air flow and an exhaust pipe (9) for directing said flow; - a device (14) for obtaining ions, which contains: • high voltage electric generator (15); • at least one electrode (16) connected to the generator (15), wherein the free end (17) of the electrode, formed from a bundle of threads (18) made of conductive material, extends to the right of the exhaust pipe (9), to release ions due to corona discharge; moreover, the device (1) is characterized in that it additionally contains: - diffuser (38) provided with: • a pipe (39) that extends into the exhaust pipe extension (9) and defines the boundaries of the compression chamber (40), and • an expander (41) that extends the pipe (39) and contains a number of channels (42) that extend from the inner side (43) of the expander (41) adjacent to the compression chamber (40) towards the opposite outer side (44) . 2. The device (1) according to claim 1, characterized in that the channels (42) diverge from each other from the inner side (43) of the expander (41) to its outer side (44). 3. Device (1) according to claim 1 or 2, characterized in that each channel (42) tapers from the inner side (43) of the dilator (41) to its outer side (44). 4. Device (1) according to one of the preceding claims, characterized in that it comprises a metal ring (48) surrounding the free end (17) of the electrode (16). 5. Device (1) according to claim 4, characterized in that the metal ring (48) has an expanding part (49) which surrounds the thread bundle (18) of the electrode (16). 6. Device (1) according to claim 4 or 5, characterized in that the metal ring (48) is crimped onto the electrode (16). 7. Device (1) according to one of paragraphs. 4-6, characterized in that the metal ring (48) is made of copper. 8. Device (1) according to one of paragraphs. 4-6, characterized in that the metal ring (48) is silver on the surface. 9. Device (1) according to one of the preceding claims, characterized in that the housing (2) comprises a base (3) and a cover (4) provided with holes (6) at least to the right of the diffuser (38). 10. The device (1) according to one of the previous paragraphs, characterized in that it contains an electronic control board (21) equipped with a switch (26) for closing and opening the power supply circuit of the generator (15), and in that the housing (2) equipped with a button (35) connected to a switch (26).

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