RU1796080C - Apparatus for air displacement by means of electric wind (its options) - Google Patents

Abstract

SUBSTANCE: corona electrode is made in the form of a rectilinear wire electrode element extended along or parallel to the axis of said channel. One end of the corona electrode is provided with means for reducing the electric field strength at this end to a value less than the electric field strength on the break surface of the electrode element, 4 s. and 1 s: .. f-ly, 7 ill.

Description

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The invention relates to electrical engineering, in particular to devices for conveying air by means of ion wind or corona wind.

The purpose of the invention is to increase efficiency.

In FIG. 1-4 are variations of a first embodiment of the invention, according to which the corona electrode is made extended along or parallel to the axis of the air channel, in particular in FIG. Figure 1 shows this device for moving air, in which the end of the corona electrode facing the target electrode is provided with a body to reduce the electric field strength, and the other end of the corona electrode is fixed to. holder; in FIG. 2 - a device in which both ends of the corona electrode are fixed in holders; in FIG. 3 is a device in which one end of the corona electrode is surrounded by a shielding element, and the other end of the corona electrode is fixed in the holder; in FIG. 4 - a device in which only one end of the crown electrode is fixed in the holder; Fig. 5 shows a second embodiment of this device, in which the corona electrode is made of several rectilinear electrode elements symmetrically located at an angle to the axis of the air channel; in FIG. 6 is a third embodiment of this device, in which the corona electrode is made in the form of a U-shaped wire element; in FIG. 7 shows a fourth embodiment of this device in which the corona electrode is made in the form of a closed ring or loop without free ends.

In all embodiments of the invention, the device for moving air by means of an electric ionic wind comprises an air channel 1 for moving air, the direction of movement of which is indicated by arrow 2, a crown electrode 3, a target electrode 4. which are located in channel 1.

Each corona electrode 3 and the target electrode 4 are connected to a respective terminal of the DC voltage source 5. In the illustrated in FIG. In an embodiment of the invention, it is assumed that the channel 1 has a tubular structure with a round or similar cross section, the target electrode 4 has a cylinder shape that corresponds to the shape of the air flow channel 1, and in this embodiment, the target electrode 4 is located almost adjacent to the channel wall 1 of the air stream or is in the form of an electrically conductive coating applied directly to the inner surface of said wall.

The corona electrode 3 in the embodiment of the device of FIG. 1 consists mainly of a straight wire of electrically conductive material, this wire being axially located in the passage 1 of the air flow passage, and it is better to be located along the axis of symmetry of the said channel. The upstream end of the wire-shaped electrode element is fixed in a holder 6, which is suitably (not shown) mounted in the air flow passage 1, and the downstream end of the same electrode element is oriented towards the target electrode 4 and provided with a bulb - a body or a droplet-like body 7, which can be made of an electrically conductive or electrically insulating material and which has a significantly larger diameter than the diameter of the wire. The body 7, which we will simply call the terminal base below, eliminates the possibility of concentration of the field, and consequently, of the concentration of the corona discharge at that end of the wire-shaped electrode element of the corona electrode 3, which faces toward the target electrode 4. In fact, in this case a corona discharge forms e, which is distributed over the entire peripheral surface of the electrode element in the desired manner, in the central part of the cross-sectional area of the air passage channel 1, in order to eliminate ings which are typical of pointed or needle-like corona electrodes used hitherto in such air supply devices.

In FIG. 2 shows a device in which the electrode of the corona 3 is represented by a wire-shaped electrode element, which although located exactly like the corona electrode of the device in FIG. 1, however, this time both ends of the crown element are attached to the respective electrode holders 6. Since the wire-like element of the crown electrode 3 shown in FIG. 2 devices do not have free ends, i.e. Since both ends are fixed in holders 6, the effective elimination of the concentration of pointed corona discharges is easily achieved, and the corona discharge actually occurs on the entire peripheral surface of the electrode element of the corona electrode 3 in the desired manner.

In the device of FIG. 3, the downstream end of the wire-shaped element of the electrode of the crown 3, facing the target electrode 4, is surrounded by a shield element 8 in the form of a tube or sleeve, which performs the function of shielding the end of the wire element of the electrode of the crown 3 so that concentration does not occur sex and so that no concentrated corona discharge occurs. The shielding of the end of the wire electrode element can also be achieved by shielding elements having a different configuration, and not just the tube configuration.

It should be borne in mind that shown in FIG. 1 and 3, the electrodes of the crown 3 may have a different arrangement, in which case the efficiency of the entire device remains still high. So, for example, the holder 6 of the wire element of the electrode 3 can be positioned downstream, i.e. as close as possible to the target electrode 4, and the end of the wire element of the electrode 3, which is equipped with a terminal body 7 or a shielding element 8, will be facing upstream, i.e. away from the target electrode 4. And nevertheless, as a rule, on the upstream free end of the wire element of electrode 3, i.e. at the free end, facing away from the target electrode 4, large field concentrations do not form, and therefore, in this case there is no greater risk that a concentrated corona discharge will occur. Thus, in accordance with the present invention, the corona electrode 3, the shape shown in FIG. 4 can be made. In this latter case, the corona electrode 3 will also contain a wire-shaped electrode element, the lower end of which is facing toward the target electrode 4, is fixed in the holder 6, while its free non-fixed end will face upstream, i.e. . away from the target electrode 4. In this case, the risk of the formation of a point-like corona discharge at this free end of the wire element of the electrode 3 will be minimal. It is quite clear that, if necessary, a terminal body of a larger diameter can be made at the upstream end of the wire element of the electrode 3 in comparison with the diameter of the electrode wire itself.

Shown in FIG. 5, the second embodiment of the crown electrode 3 contains two or more

wire electrode elements that are attached at one end to the holder 6 and which are located on the peripheral surface of an imaginary symmetrical cone, the axis of symmetry of which coincides with the axis of the channel 1 for the passage of air flow 1. The ends of the wire electrode elements facing the target electrode 4 are provided terminal bodies 7 in exactly the same way as shown in i in FIG. 1, which will exclude the possibility of the formation of concentrated corona discharges at the ends of the wire electrodes 3, the upper angle of the imaginary cone, around which the wire electrodes 3 are located, can vary and in the extreme case it can reach 180 ° to the maximum so that the wire electrodes 3 were in the same plane at right angles to the longitudinal axis of the air passage channel 1.

It is possible to abandon the formation of terminal bodies 7 without any risk that concentrated point-like corona discharges will occur at the ends of the wire elements of the electrode 3, if the loose ends of the elements of the electrode 3 are oriented towards the air stream 2.

The crown electrode 3 may have various shapes. The only important feature of this electrode 3 is that it contains one or more wire electrode elements located inside the central part of the cross section of the air passage channel 1 and that these electrode elements have a projection onto a plane perpendicular to the longitudinal axis of channel 1 for air flow, the length of which will be significantly less than the transverse dimension of the channel 1 for air flow, and it is better that the length of this projection is 25% less than the transverse size of the aforementioned channel 1. A distinctive feature of this electrode 3 is that the wire electrode elements do not have ends at which the electric field exceeds the field strength on the peripheral surface of the respective electrode elements, so that the formation of point-like corona discharge concentrations on these the ends of the electrode element and limit the corona discharge to the peripheral surfaces of the electrode elements.

In FIG. 6 schematically shows another embodiment of the present invention. In this embodiment, the crown electrode 3 is represented by a U-shaped thin wire electrode element that is attached to the holder 6 so that both ends of the wire electrode element remain loose, both ends directed towards the air flow 2 and in the opposite direction from the target electrode 4. If necessary, these free ends of the wire electrode element can be provided with terminal bodies by the aforementioned method.

In FIG. 7 shows yet another embodiment of the present invention. In this embodiment, the electrode of the crown 3 is represented by a wire electrode element, which is made in the form of a ring or loop and which. attached to the holder 6. Since both ends of this wire electrode 3 shown in FIG. 7 options are held in a state fixed in the holder 6, then no concentrated or punctiform corona discharges can occur. The ring-shaped or loop-shaped electrode element can also be oriented in a plane extending perpendicular to the longitudinal axis of the air passage passage 1,

The essence of the invention has been described above with the indication that the channel 1 for conveying air has a circular cross section or a cross section: an identical configuration. However, the present invention also relates to devices for moving air containing channel 1

for conveying air of an elongated rectangular or spline-shaped cross section in which a large number of

According to the invention, the corona electrodes are located at the same distance from each other in the plane of symmetry of the air flow supply channel, which has a longitudinal axis of an elongated rectangular cross section of the air flow passage. Each such corona electrode is intended to form air ions in a corresponding part of the entire air passage channel.

According to the present invention, the corona 3 electrode wire elements are recommended to be made of or coated with a material that will be resistant to ultraviolet radiation and ozone. The electrode element, for example, may comprise nickel-coated carbon fiber wires.

The above detailed description of the air moving device relates to the configuration of the corona electrode. Channel 1 has physical walls surrounding the electrodes. Moreover, upstream of the electrode of the crown 3 there is a corresponding screen (not shown),

in order to exclude the possibility of the ion flow passing upstream from the corona electrode, the Device can also be equipped (to increase its efficiency) with an excitation electrode.

The formula of the invention 1. A device for moving air using an electric ionic wind containing at least one corona electrode mounted in the air channel or near the axis of symmetry of the channel, at least one breathable target electrode mounted in the specified channel with an axial a shift with respect to the corona electrode in the direction of the desired movement of air, and a constant current source, the first terminal of which is connected to the corona electrode, and the second terminal is connected to the target electrode, and The configuration of the corona electrode and the voltage value of the current source are selected from the condition that a corona discharge is generated on the corona electrode, which creates air ions, characterized in that, in order to increase the efficiency, the corona electrode is made in the form of a rectilinear wire electrode element extended along or parallel to the axis of the specified channel, at least one end of which, facing the target electrode, is equipped with a means of reducing the electric field at this end to a value less than the electric field strengths on the side surface of the electrode element to prevent the occurrence of a corona discharge at the end of the electrode element and to limit the location of the corona discharge on the side surface of the electrode element.

2. Device pop. 1, characterized in that the said tool is made in the form of a holder or body fixed to the corresponding end of the electrode, the transverse dimensions of which are selected to be larger than the diameter of the electrode element, or in the form of a corresponding end surrounding

electrode element of the shielding element.

3. Device for moving air using an electric ionic wind, containing at least one corona electrode mounted in the air channel or near the axis of symmetry of the channel, at least one air-permeable target electrode mounted in the specified channel with an axial shift with respect to the electrode corona in the direction of the desired movement of air, and a DC source, the first terminal of which is connected to the electrode of the corona, and the second terminal of which is connected to the target electrode, and the configuration the corona electrode and the voltage value of the current source are selected from the condition of generating a corona discharge on the corona electrode, which creates air ions, as a result In addition, in order to increase the efficiency, the corona electrode is made in the form of several rectilinear wire electrode elements, one of the ends of which is attached to a common holder located on or near the axis of symmetry of the channel, and at the other free ends of which facing the target electrode, bodies are fixed whose transverse dimensions exceed the diameter of the electrode elements, and the electrode elements are located symmetrically to the axis of the channel on which the holder is located, at equal angles to the longitudinal axis channel, on which the holder is located so that the length of the electrode elements in the direction perpendicular to the axis of symmetry of the channel is less than the transverse size or diameter of the channel.

4. Device for moving air using an electric ion wind, containing at least one corona electrode mounted in the air channel or near the axis of symmetry of the channel, at least one breathable target electrode mounted in the specified channel with an axial shift with respect to the electrode corona in the direction of the desired movement of air, and a constant current source, the first terminal of which

connected to the corona electrode, and the second terminal of which is connected to the target electrode, wherein the configuration of the corona electrode and the voltage value of the current source are selected from the condition that a corona discharge is generated on the corona electrode, which creates air ions, characterized in that, in order to increase the efficiency , the corona electrode is made in the form of a U-shaped wire electrode element, which is fixed in the middle part to a holder located on the axis of symmetry of the channel or near this axis, and the branches of the electrode element and diverging symmetrically to the longitudinal axis of the channel on which the said holder, in a direction opposite the target position of the electrode so that the extent of the electrode element in a direction perpendicular to said axis, smaller transverse dimension or diameter of the air passage,

5. A device for moving air using an electric ionic wind, comprising at least one breathable target electrode mounted in said channel with an axial shift relative to the corona electrode in the direction of the desired air movement, and a constant current source, the first terminal of which is connected to the corona electrode, and the second terminal is connected to the target electrode, and the configuration of the corona electrode and the voltage value of the current source are selected from the condition of generation on the corona electrode This type of discharge, which creates air ions, is also related to the fact that, in order to increase efficiency, the corona electrode is made in the form of a wire electrode element in the form of a closed ring or loop without free ends located in the longitudinal plane of the cross section of the air channel is symmetrical to the axis of symmetry of the channel or symmetrically passing along the longitudinal axis of the channel, and has a length measured in a direction perpendicular to the longitudinal axis of the channel less than the transverse size or diameter of the channel.

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