JP2023044239A - Nozzle for electrospray, and electrospray device - Google Patents

Abstract

To spray a large amount of liquid with a fine particle size.SOLUTION: A nozzle for an electrospray, which is a nozzle for an electrospray for spraying a liquid by an electrospray ionization method, includes a droplet formation member that is formed into a cylindrical shape, is configured to pass a liquid along its cylindrical inner peripheral surface and flow out the liquid of the cylindrical tip, and supplies an excessive charge to the liquid flowing out of the cylindrical tip by a power source supplied from the outside, wherein the droplet formation member has a plurality of groove parts formed by notching toward a base end side from the cylindrical tip side on the tip side of the droplet formation member, and the tip part is formed between mutually adjacent groove parts.SELECTED DRAWING: Figure 1

Description

Embodiments of the present invention relate to electrospray nozzles and electrospray devices.

In recent years, the electrospray method has attracted attention as a technique for applying chemicals, paints, and the like. In the electrospray method, by applying a high voltage between a nozzle and a counter electrode, a high voltage is applied between the liquid puddle at the tip of the nozzle and the counter electrode, causing the liquid to become excessively charged. It is a technique of forming fine droplets with tinges, spraying them toward the counter electrode, and drawing and applying to the counter electrode.

In the electrospray method, when a high voltage is applied between the liquid ejected from a nozzle and a counter electrode, the tip of the nozzle forms a conical shape called a Taylor cone. The liquid discharged from the nozzle is split into a large number of fine droplets, that is, in the form of mist from the tip of the Taylor cone and sprayed onto the counter electrode.

By the way, when droplets are generated by a single system of Taylor cone, the amount that can be stably sprayed is limited, depending on the physical properties of the liquid used. Therefore, in the conventional configuration, there is room for improvement in spraying a large amount of fine particles in applying the electrospray method to various fields.

JP 2016-131961 A

SUMMARY OF THE INVENTION The present invention has been made in view of the above circumstances, and an object thereof is to provide an electrospray nozzle and an electrospray apparatus capable of spraying a large amount of liquid with fine particle diameters.

An electrospray nozzle of an embodiment is a nozzle for electrospray that sprays a liquid by an electrospray ionization method, and is formed in a cylindrical shape, and the liquid is passed along the inner peripheral surface of the cylindrical shape. a droplet forming member configured to allow liquid to flow out from a tip portion, and for supplying an excess electric charge to the liquid flowing out from the cylindrical tip portion by a power source supplied from the outside, the droplet forming member has a plurality of grooves formed on the distal end side of the droplet forming member by notching the tubular shape from the distal end side toward the proximal end side, and the distal end portion is located between the grooves adjacent to each other. formed in

An electrospray apparatus according to an embodiment includes the electrospray nozzle, a power supply device that supplies power to the nozzle, and a liquid supply device that supplies liquid to the liquid flow path.

1 is a diagram schematically showing the schematic configuration of an electrospray apparatus according to one embodiment; FIG. 1 is a cross-sectional view schematically showing an example of the configuration of an electrospray nozzle according to one embodiment; FIG. 1 is a perspective sectional view schematically showing an example of the configuration of an electrospray nozzle according to one embodiment; FIG. FIG. 2 is a view of an example of the configuration around the tip of an electrospray nozzle according to one embodiment, viewed from the nozzle tip side; 1 is a perspective view schematically showing an example of the configuration of a droplet forming member according to one embodiment; FIG. FIG. 2 is an exploded view schematically showing an example of the configuration of a droplet forming member according to one embodiment; FIG. 2 shows an enlarged view of the arrow X7 part in FIG. FIG. 4 is a diagram showing a liquid spray pattern when using an electrospray device according to one embodiment;

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, embodiments of the present invention will be described with reference to the drawings. In the following embodiments, substantially the same elements are denoted by the same reference numerals, and descriptions thereof are omitted.

The electrospray device 1 shown in FIG. 1 is a device capable of spraying a liquid such as a chemical solution or paint by an electrospray method, thereby applying the liquid to a counter electrode 90 . The electrospray device 1 includes a liquid supply device 10, a power supply device 20, a control device 30, a fixing member 40, and an electrospray nozzle 50, as shown in FIG. In the following description, the electrospray nozzle 50 will simply be referred to as nozzle 50 . In this embodiment, the lower side of the paper surface in FIG. end side.

The liquid supply device 10 is for supplying a liquid such as a chemical solution or paint to the nozzle 50 . The liquid supply device 10 can be configured with, for example, a liquid tank 11 and a liquid supply pump 12 . The liquid tank 11 is configured to be able to store a liquid such as a chemical solution or paint. The liquid supply pump 12 is for supplying the liquid in the liquid tank 11 to the nozzle 50 at a predetermined discharge pressure. A suction port of the liquid supply pump 12 is connected to the liquid tank 11 via a liquid hose 13 . A discharge port of the liquid supply pump 12 is connected to the nozzle 50 via the liquid hose 13 and the fixing member 40 . In the case of this embodiment, the liquid hose 13 is made of, for example, a synthetic resin having electrical insulation. Further, the liquid supply pump 12 is configured by, for example, a syringe pump, and can control the amount of liquid supplied to the nozzle 50 with high accuracy. Note that the liquid supply pump 12 is not limited to a syringe pump.

The power supply device 20 has a function of applying a high voltage of several kV to ten and several kV, for example, between the nozzle 50 and the counter electrode 90 . The power supply device 20 has a booster circuit and a rectifier circuit, and supplies the power required to drive the electrospray device 1, that is, the DC high voltage required to charge the liquid. The output side of the power supply device 20 is connected to the nozzle 50 via the power cable 21 or the like. Also, the power supply device 20 and the counter electrode 90 are grounded through the ground wire 22 .

The control device 30 is configured by a microcomputer having a CPU (not shown), a ROM, a RAM, and the like. The control device 30 is electrically connected to the liquid supply pump 12 and the power supply device 20 as shown in FIG. can. Thereby, the controller 30 can automatically or semi-automatically control the amount of liquid supplied to the nozzle 50 and the voltage applied to the liquid.

Note that the electrospray device 1 does not necessarily have to include the control device 30 . If the electrospray device 1 does not include the control device 30, the user of the electrospray device 1 manually adjusts the liquid supply pump 12 and the power supply device 20 to adjust the amount of liquid supplied and the applied voltage. be able to. That is, the adjustment of the amount of liquid supplied by the liquid supply pump 12 and the adjustment of the voltage applied to the liquid are performed by the user manually adjusting the control parameters of the liquid supply pump 12 and the power supply device 20 while checking the spraying state of the liquid. It can be configured to be manually performed by, for example, changing.

The fixing member 40 is for supporting the nozzle 50 by attaching the nozzle 50 and connecting the liquid hose 13 and the nozzle 50 . The fixing member 40 is made of, for example, an electrically insulating resin member. The fixing member 40 is configured to be detachable from the nozzle 50, for example. In this manner, the user can easily take measures when, for example, the nozzle 50 is clogged with liquid and maintenance is required.

The nozzle 50 has a function of spraying the liquid supplied from the liquid supply device 10 by an electrospray ionization method. The nozzle 50 has an electrode member 60 and a droplet forming member 70, as shown in FIG. 2 and the like. The electrode member 60 is configured by a conductive member such as a metal member. The electrode member 60 can be made of, for example, aluminum, iron, gold, silver, titanium, stainless steel, or chromium, but is not limited to these. The electrode member 60 has the function of supplying the droplet forming member 70 with the high voltage supplied from the power supply device 20 . In this case, the electrode member 60 is electrically connected to the power supply device 20 via the power cable 21 or the like.

The electrode member 60 can be configured to have, for example, a support member 61, a connecting member 62, and a body portion 63, as shown in FIG. 2 and the like. The support member 61 is formed, for example, in a tubular shape, and is open at both ends in the axial direction. The support member 61 is connected to the droplet forming member 70 at its distal end and attached to the fixing member 40 at its proximal end. As shown in FIGS. 2 and 3, the connecting member 62 is formed in a substantially rod shape as a whole, with the base end side accommodated inside the support member 61 and the tip end side extending from the inside of the support member 61 to the tip side of the nozzle 50 . It protrudes and extends toward the In this case, the connecting member 62 is attached to the supporting member 61 by, for example, light press-fitting, and is configured to be movable with respect to the supporting member 61 along the axial direction of the nozzle 50 .

The connecting member 62 has a base portion 621 and a bar portion 622 . In this embodiment, the base portion 621 and the rod-like portion 622 are configured integrally. The base portion 621 is provided on the proximal end side of the connecting member 62 . The base portion 621 has a planar portion 621a and an arcuate portion 621b. The planar portion 621a and the arcuate portion 621b are formed on the peripheral surface of the base portion 621 as shown in FIG. The planar portion 621a is formed by processing a portion of the peripheral surface of the base portion 621 on the distal end side, that is, two locations facing each other in the radial direction into a planar shape. The arcuate portion 621b is a portion of the peripheral surface on which the planar portion 621a of the base portion 621 is formed, excluding the planar portion 621a, and is formed in an arc shape along the inner peripheral surface of the support member 61 .

The outer diameter of the portion of the base portion 621 where the arcuate portion 621b is formed is slightly larger than the inner diameter of the support member 61 . In this case, the connecting member 62 is held by the support member 61 by bringing the arcuate portion 621b and the inner peripheral surface of the support member 61 into contact. A space through which liquid can pass is formed between the planar portion 621 a and the inner peripheral surface of the support member 61 when the connection member 62 is held by the support member 61 . The liquid supplied from the liquid hose 13 into the support member 61 passes through the space and flows to the tip side of the nozzle 50 .

The rod-shaped portion 622 is provided on the distal end side of the connecting member 62 . As shown in FIG. 2 and the like, the bar-shaped portion 622 is formed in a cylindrical bar-like shape extending linearly along the axial direction of the nozzle 50, for example. The rod-shaped portion 622 has a proximal end disposed at the distal end of the base portion 621 and a distal end protruding from the inside of the support member 61 . The outer diameter of the rod-shaped portion 622 is smaller than the outer diameter of the base portion 621 and the inner diameter of the support member 61 . The bar-shaped portion 622 is formed, for example, with a spherical tip.

The body portion 63 is formed, for example, in a tubular shape, and is formed so that both ends in the axial direction are open. The body portion 63 is formed so as to extend axially toward the distal end side of the nozzle 50 . The body portion 63 is attached to the connecting member 62 , in this case the rod-like portion 622 , by light press-fitting, for example, and is configured to be movable with respect to the connecting member 62 along the axial direction of the nozzle 50 . That is, the connecting member 62 connects the support member 61 and the body portion 63 . A part of the body portion 63 is accommodated inside the support member 61 . The axial centers of the supporting member 61, the connecting member 62, and the main body portion 63 are aligned with each other.

The body portion 63 has a tubular portion 631 and a charging electrode portion 632 . The cylindrical portion 631 is provided on the base end side of the body portion 63 as shown in FIGS. The tubular portion 631 is configured, for example, in a cylindrical shape. The base end side of the cylindrical portion 631 is housed inside the supporting member 61 with the outer peripheral surface of the cylindrical portion 631 and the inner peripheral surface of the supporting member 61 separated from each other by a predetermined gap. The inner diameter of the cylindrical portion 631 is slightly smaller than the outer diameter of the rod-shaped portion 622 . The body portion 63 is held by the connecting member 62 by bringing the inner peripheral surface of the tubular portion 631 and the outer peripheral surface of the rod-shaped portion 622 into contact with each other. In this manner, the liquid that has passed through the support member 61 flows along the outer peripheral surface of the cylindrical portion 631 toward the tip of the nozzle 50 .

The charging electrode portion 632 is provided on the distal end side of the body portion 63 and continuously from the tubular portion 631 . As shown in FIGS. 2 to 5, the charging electrode portions 632 are formed in plurality, in this case four, at predetermined intervals, in this case equal intervals, in the circumferential direction of the main body portion 63 . The plurality of charging electrode portions 632 can be configured to have the same shape. Further, the plurality of charging electrode portions 632 extend along the axial direction of the main body portion 63, and as shown in FIG. It is formed so as to be slanted. The tip of the charging electrode portion 632 is positioned closer to the tip of the nozzle 50 than the rod-like portion 622 , that is, the tip of the connecting member 62 .

As shown in FIGS. 2 and 3, the tip of the charging electrode portion 632 is formed into a curved surface with chamfered corners in the width direction. The tip portion of the charging electrode portion 632 is not limited to a curved surface, and may be formed to be generally pointed so as to taper. In this specification, a corner means a point formed by two sides intersecting, and indicates a sharp portion that is not curved.

Further, as shown in FIG. 4, a gap 633 is formed between the charging electrode portions 632 adjacent to each other. That is, in this embodiment, four gaps 633 are formed. The gap 633 is formed at a position overlapping at least the tip of the bar-shaped portion 622, as shown in FIG.

The droplet forming member 70 is formed, for example, in a cylindrical shape, and is open at both ends in the axial direction. The droplet forming member 70 is configured to allow the liquid to pass along its tubular inner peripheral surface 701 and to flow out from the tip portion 71 of the droplet forming member 70 . That is, the tip portion 71 constitutes the outlet of the nozzle 50 .

The droplet forming member 70 is made of a conductive member such as a metal member. The droplet forming member 70 can be made of, for example, aluminum, iron, gold, silver, titanium, stainless steel, or chromium, but is not limited to these. The droplet forming member 70 has a function of applying a high voltage supplied from the power supply device 20 via the electrode member 60 to the liquid supplied from the liquid supply device 10 and flowing in the cylinder. In this case, the droplet forming member 70 is electrically connected to the power supply device 20 indirectly through the electrode member 60 . Therefore, the electrode member 60 and the droplet forming member 70 are configured to have the same potential by the voltage supplied from the power supply device 20 .

As shown in FIG. 2, the base end side of the droplet forming member 70 is attached to the support member 61 by, for example, light press-fitting, and is configured to be movable with respect to the support member 61 along the axial direction of the nozzle 50. ing. That is, the outer diameter of the support member 61 is slightly larger than the inner diameter of the droplet forming member 70 . The droplet forming member 70 is held by the supporting member 61 by bringing the outer peripheral surface of the supporting member 61 and the inner peripheral surface 701 of the droplet forming member 70 into contact with each other.

In this embodiment, as shown in FIG. 2 and the like, the liquid flow path 80 is formed between the inner peripheral surface 701 of the droplet forming member 70 and the outer peripheral surface 634 of the main body portion 63 . The liquid flow path 80 allows the liquid supplied from the liquid hose 13 through the inside of the support member 61 to form droplets through the space between the inner peripheral surface 701 of the droplet forming member 70 and the outer peripheral surface 634 of the main body 63 . It is a path leading to the tip portion 71 of the member 70 . That is, the liquid supplied from the liquid supply device 10 and passed through the support member 61 flows through the liquid channel 80 and is discharged from the tip portion 71 to the outside of the nozzle 50 .

A gap 633 is formed between adjacent charging electrode portions 632 on the distal end side of the body portion 63 as described above. A part of the liquid flowing through the liquid channel 80 flows out from the gap 633 . On the other hand, since the gap 633 is formed at a position overlapping the tip of the rod-shaped portion 622 located inside the charging electrode portion 632 , the liquid flowing out from the gap 633 is guided to the tip of the rod-shaped portion 622 . The ease of adherence of the liquid to the tip of the rod-shaped portion 622 , that is, wettability, prevents the liquid that has flowed out from the gap 633 from dripping from the vicinity of the center of the droplet forming member 70 .

The droplet forming member 70 has grooves 72 . As shown in FIGS. 4 to 6, the grooves 72 are notched from the distal end side toward the proximal end side of the droplet forming member 70 at predetermined intervals, in this case, equal intervals along the circumferential direction. formed by A plurality of grooves 72, four in this case, are formed. A tip portion 71 is formed between the adjacent groove portions 72 . That is, in this embodiment, four tip portions 71 are formed. The plurality of tip portions 71 and groove portions 72 can be configured to have the same shape.

As shown in FIG. 4 , the plurality of tip portions 71 are provided at positions overlapping the corresponding charging electrode portions 632 in the circumferential direction of the nozzle 50 . Also, the plurality of grooves 72 are provided at positions overlapping the corresponding gaps 633 in the circumferential direction of the nozzle 50 . In this case, the width dimension W1 of the tip portion 71 is configured to be larger than the width dimension W2 of the charging electrode portion 632 . The width dimension G1 of the groove portion 72 is smaller than the width dimension G2 of the gap 633 .

Moreover, as shown in FIGS. 5 and 6, the groove portion 72 and the tip portion 71 are connected, for example, in a continuous curve shape without corners. In this specification, the curved shape is not limited to one having a constant radius of curvature, and may have a varying radius of curvature. In this manner, a plurality of grooves 72 and tip portions 71 are alternately formed on the tip side of the droplet forming member 70 . The width dimension W1 of the tip portion 71 can be configured to be larger than the width dimension G1 of the groove portion 72 . In this case, the width dimension W1 of the tip portion 71 can be configured to be, for example, about 2 to 3 mm, and the width dimension G1 of the groove portion 72 can be configured to be about 0.3 to 1 mm. Also, the tip portion 71 and the groove portion 72 can be rephrased as the peak portion 71 and the valley portion 72 .

Further, as shown in FIG. 6, the tip of the tip portion 71 is formed in, for example, a continuous curved shape without corners. 7 and the like, the tip portion 71 is closer to the tip side of the nozzle 50 than the bar-shaped portion 622 in the axial direction of the nozzle 50, and is closer to the base of the nozzle 50 than the tip of the charging electrode portion 632. located on the edge. That is, the charging electrode portion 632 is provided so as to protrude from the tip side of the nozzle 50 .

In the configuration of the electrospray device 1 as described above, the liquid supplied from the liquid supply device 10 to the nozzle 50 passes through the liquid flow path 80 of the nozzle 50 and reaches the inner peripheral surface 701 of the tip portion 71 of the droplet forming member 70 . to reach Due to wettability with the inner surface of the tip portion 71 , the liquid leaks from the inner peripheral surface 701 of the tip portion 71 to the tip side of the end face of the tip portion 71 as a pool. This liquid pool is generated in such a manner as to wrap the charging electrode portion 632 of the main body portion 63 inside. Then, this liquid pool is supplied with excessive electric charge from the inner peripheral surface 701 of the tip portion 71, the end surface of the tip portion 71, and the charging electrode portion 632, and the strong electric field between the counter electrode 90 causes the surface of the liquid pool to Excess electrodes are concentrated in . Thereby, a conical Taylor cone 91 as shown in FIG. 7 is formed.

In this embodiment, four tip portions 71 are provided. Therefore, four Taylor cones 91 are formed independently corresponding to the tip portion 71 . That is, in the nozzle 50, the Taylor cone 91 is not formed singularly, but is divided into a plurality of, in this case, four. Furthermore, since the plurality of tip portions 71 are arranged evenly along the circumferential direction of each tip side of the droplet forming member 70 formed in a cylindrical shape and having the same shape, each Taylor cone generated 91 has a substantially uniform shape.

Then, when the excess charge concentrated on the surface of the liquid exceeds the surface tension of the liquid, minute charged droplets 92 are emitted from the tips of the plurality of Taylor cones 91 respectively. These fine charged droplets 92 are further subdivided into fine mist by so-called Coulomb explosion and promotion of liquid evaporation. This fine mist is attracted to the counter electrode 90 by its own electric charge, and adheres to the counter electrode 90 as shown in FIG.

According to the embodiment described above, the nozzle 50 is an electrospray nozzle that sprays liquid by the electrospray ionization method, and includes the droplet forming member 70 . The droplet forming member 70 is formed in a cylindrical shape and is configured to allow the liquid to pass along the inner peripheral surface of the cylindrical shape and to flow out the liquid from the cylindrical tip portion 71. , supplies excess charge to the liquid flowing out of the tubular tip 71 . Also, the droplet forming member 70 has a plurality of grooves 72 . A plurality of grooves 72 are formed by notching the distal end side of the droplet forming member 70 from the cylindrical distal end side toward the proximal end side. The tip portion 71 is formed between the groove portions 72 adjacent to each other.

Here, as the amount of liquid to be sprayed increases, the particle size of the Taylor cone becomes coarser. Therefore, it is difficult to generate a single Taylor cone for the nozzle and increase the amount of spray with a fine particle size. Therefore, in this embodiment, a plurality of tip portions 71 are provided on the tip side of the droplet forming member 70 . Therefore, by supplying liquid to a plurality of tip portions 71 , Taylor cones 91 can be generated at each tip portion 71 . By generating the divided tailor cones 91 in this manner, the amount of sprayed by each tailor cone 91 can be suppressed, and the particles sprayed by each tailor cone 91 can be atomized. As a result, the nozzle 50 as a whole can spray a large amount of liquid with fine particle diameters, compared to the case where a single Taylor cone is generated for the nozzle and the liquid is sprayed.

Further, the tip of the tip portion 71 is formed in a continuous curved shape without corners. Here, for example, if there is a straight portion at the tip of the tip portion 71, the Taylor cone 91 may be irregularly generated at the straight portion, and stable spraying may be disturbed. Therefore, by forming the tip of tip portion 71 into a continuous curved shape without corners, Taylor cone 91 can be reliably generated in the vicinity of the topmost portion of tip portion 71 . Thereby, the liquid can be sprayed satisfactorily over a desired spray range.

Furthermore, the tip portion 71 and the groove portion 72 are connected in a continuous curved shape without corners. In the electrospray method, the application of a high voltage causes the electric field to concentrate on the acute-angled portion, making it easier for corona discharge to occur. Therefore, if there is a corner at the connection portion between the tip portion 71 and the groove portion 72, corona discharge may occur from the corner, and stable generation of the Taylor cone at the tip portion 71 may be hindered. have a nature. Therefore, by forming the connection portion between the tip portion 71 and the groove portion 72 into a curved shape, a Taylor cone can be reliably generated in the vicinity of the topmost portion of the tip portion 71 . Thereby, the liquid can be sprayed satisfactorily over a desired spray range.

Nozzle 50 further comprises an electrode member 60 . The electrode member 60 charges the liquid flowing through the liquid flow path 80 with a power source supplied from the outside. The electrode member 60 has a support member 61 and a body portion 63 . The supporting member 61 is formed in a cylindrical shape and can support the droplet forming member 70 in a state where a portion of the supporting member 61 is accommodated inside the droplet forming member 70 . The body portion 63 is formed in a cylindrical shape, is disposed on the tip side of the support member 61 , and forms a liquid flow path 80 through which the liquid can pass between the body portion 63 and the droplet forming member 70 .

According to this, the liquid channel 80 is formed between the electrode member 60 and the droplet forming member 70, and power is supplied to the liquid flowing through the liquid channel 80, that is, voltage is applied to the liquid. Excess electric charge can be smoothly supplied to the liquid supplied to the tip portion 71 of the droplet forming member 70 . This makes it possible to easily generate a stable Taylor cone continuously.

Moreover, the electrode member 60 further has a connecting member 62 . The connecting member 62 connects the support member 61 and the body portion 63 . The body portion 63 has a plurality of charging electrode portions 632 . The plurality of charging electrode portions 632 are formed on the distal end side of the body portion 63 and extend along the axial direction of the body portion 63 at predetermined intervals in the circumferential direction of the body portion 63 . A gap 633 through which the liquid that has passed through the liquid channel 80 can pass is formed between the charging electrode sections 632 adjacent to each other. Then, the connecting member 62 comes into contact with the liquid that has flowed through the gap 633 .

According to this, the liquid that has flowed through the liquid flow path 80 and passed through the gap 633 is brought into contact with the connecting member 62 , so that the liquid drips as droplets from the inside of the droplet forming member 70 . can be suppressed. Thereby, the liquid can be smoothly guided to the tip portion 71 of the droplet forming member 70 . Therefore, good atomization can be achieved.

The droplet forming member 70 and the support member 61, and the body portion 63 and the connecting member 62 are attached by light press fitting. According to this, the droplet formation member 70 and the support member 61, and the body portion 63 and the connection member 62 are attached by light press-fitting, so that each member can be moved along the axial direction of the nozzle 50. can be done. This makes it possible to easily finely adjust the positional relationship of each member. Therefore, the position of each member can be changed to a position where a stable Taylor cone is likely to be generated according to various conditions such as the amount of liquid supplied and the applied voltage. Therefore, good atomization can be achieved.

The embodiments described above are presented as examples, and are not limited to the embodiments described above and described in the drawings, and can be appropriately modified within the scope of the invention.

DESCRIPTION OF SYMBOLS 1... Electrospray apparatus, 10... Liquid supply apparatus, 20... Power supply apparatus, 50... Electrospray nozzle, 60... Electrode member, 61... Support member, 62... Connection member, 63... Body part, 632... Charge electrode part , 633... Gap 70... Droplet forming member 71... Tip part 72... Groove part 80... Liquid channel

Claims (7)

An electrospray nozzle for spraying a liquid by an electrospray ionization method,
It is formed in a cylindrical shape and configured to allow liquid to pass along the inner peripheral surface of the cylindrical shape and to flow out from the distal end of the cylindrical shape. a droplet forming member for supplying an excess charge to the spilled liquid;
The droplet forming member has a plurality of grooves formed by notching the cylindrical tip side toward the base end side from the tip side of the droplet forming member,
The tip is formed between the grooves adjacent to each other,
Electrospray nozzle. The tip of the tip portion is formed in a continuous curved shape without corners,
The electrospray nozzle according to claim 1. The tip portion and the groove portion are connected in a continuous curved shape without corners,
The electrospray nozzle according to claim 1 or 2. a support member formed in a tubular shape and capable of supporting the droplet formation member in a state in which a part of the droplet formation member is accommodated inside the droplet formation member; a body forming a liquid channel through which liquid can pass between itself and the droplet forming member, and charging the liquid flowing through the liquid channel by the power source supplied from the outside. further comprising an electrode member;
Electrospray nozzle according to any one of claims 1 to 3. The electrode member further has a connecting member that connects the supporting member and the main body,
The main body has a plurality of charging electrodes formed on the tip side of the main body and extending along the axial direction of the main body at predetermined intervals in the circumferential direction of the main body. A gap through which the liquid that has passed through the liquid channel can pass is formed between the charged electrode portions adjacent to the
the connecting member contacts the liquid that has flowed through the gap;
The electrospray nozzle according to claim 4. The droplet formation member, the support member, and the body portion and the connection member are each attached by light press-fitting,
The electrospray nozzle according to claim 5. an electrospray nozzle according to any one of claims 1 to 6;
a liquid supply device that supplies liquid to the nozzle;
a power supply device that supplies power to the nozzle;
An electrospray device comprising:

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