The invention relates to an electrospinning device for producing a fibrous structure. The invention also relates to method of electrospinning.
U.S. patent publication US2005/224999 discloses an electrospinning device for producing fibrous materials. The device has an extrusion element configured to electrospin a substance using an electric field extraction of the substance from a tip of the extrusion element, a collector, and a chamber enclosing the collector and extrusion element. An ion generator is present to generate ions for injection into a Rayleigh instability zone in the chamber during operation of the device.
US patent publication US2007/042069 discloses a fiber spinning apparatus for charging a polymer-containing liquid stream using a point-electrode positioned adjacent the intended path of the liquid stream during operation. E.g. an ion flow is generated by a corona discharge to impart electrical charge to the polymer-containing liquid stream.
US patent publication US2005/104258 discloses an electrospinning device allowing to direct a polymer from a source electrode into an electric field that drives the formation of electrospun fibers that are deposited onto a collecting surface (being a counter electrode or a collecting surface between the source electrode and a counter electrode). Multiple electrically charged areas underneath the counter electrode allow to produce a pattern of areas where fibers are collected.
Electrospinning is a method to produce continuous fibers with a diameter ranging from a few tens of nanometers to a few tens of micrometers. To electrospin fibers, a suitable liquefied material may be fed through a small, electrically conductive nozzle. The liquefied material may be electrically charged by applying a high voltage between the nozzle and a counter electrode. The generated electric field causes a cone-shape deformation of the droplet at the nozzle tip. Once the surface tension of this droplet is overcome by the electrical force, a jet is formed out of the droplet and a fiber forms that moves towards the counter electrode. During the flight towards the counter electrode the fiber is continuously stretched and elongated by the different forces acting on it, reducing its diameter and allowing it to solidify by evaporation of the solvent or cooling of the material such that a solid fiber is deposited on the collector which is placed before the counter electrode or the counter electrode is used as collector directly.
Electrospinning uses an electric field, generated by a high voltage potential between nozzle and collector, to produce a fiber from a droplet at the nozzle tip. In alternative configurations fibers are drawn e.g. from a liquid bath, liquid covered ball, liquid filled opening or liquid covered wire. After stretching, the fiber is deposited on the collector surface. However, even with conductive collector surfaces, residual electric charges might remain inside the deposited fiber. These residual charges have an adverse effect on the process since they act as a repulsive force on the subsequent section of the fiber arriving at the collector. These residual charges are not always easy to remove efficiently, even with conductive collectors. Eventually, fibers are not in direct contact with the collector anymore but with underlying, poorly conducting fibers.
Several methods are proposed to improve the removal/neutralization of residual charges at the deposited fibrous structure. However, these methods rely on either reducing charge on the fiber in mid-air, or bombarding the collector surface with ions to alter the charge on the fibrous structure, see e.g. patent publication WO2016/147951. In WO2016/147951 a nanofiber manufacturing apparatus is described equipped with a collecting unit, a discharging unit, a power source unit, and an electricity-removing unit. The collecting unit dispenses a deposit-receiving material from one end and collects same at the other end. The discharging unit discharges a feedstock liquid and deposits nanofibers on a collecting surface. The power source unit generates a potential difference between the discharging unit and the collecting surface. The electricity-removing unit removes the charge with which the deposited nanofibers are charged. Rotatable bodies cause the collecting surface to face the discharging unit and the electricity-removing unit alternately. The electricity-removing unit extends across the whole width of the collecting surface.
It is on object of the present invention to provide an improved electrospinning device.
A first aspect of the invention provides an electrospinning device comprising:
The present invention deploys the known technique of using ions to alter the charge on the deposited fibrous structure in a local manner. To obtain this, the one or more electrostatic emitters may be relatively small and positioned close to the surface of the collecting surface/fibrous structure, and have e.g. an effective area around the emitters with a radius of only 5-10 mm. This new technique offers precise control over the attractiveness/repulsiveness of certain areas of the collector/fibrous structure for subsequent fiber deposition. This enables a local built up of fibers, which enables patterning of the fibrous structure. So what was regarded previously as a problem (i.e. built up of charge in the fibrous structure during manufacturing) is now used by the inventors to its advantage.
Optionally, the device comprises a rotatable cylindrical body, the surface of which forms the collecting surface.
Optionally, the device comprises at least two rotatable bodies, and a looped conveyer belt arranged around the two rotatable bodies, wherein the surface of the belt forms the collecting surface.
Optionally, the collecting surface is arranged between the nozzle and the one or more electrostatic emitters. This allows to have the collecting surface, in combination with the rotatable bodies to face in turn (i.e. subsequently) the nozzle and the one or more electrostatic emitters. Furthermore, as in this embodiment, the electrostatic emitters are located at the opposite side from the collecting surface when viewed from the nozzle, the electrostatic emitters will have less influence on the area in the electrospinning device where the fibers are formed from the jet exiting the nozzles (the Rayleigh instability area).
Optionally, the electrostatic emitters are arranged in a row.
Optionally, the electrostatic emitters are arranged in an array.
Optionally, the electrostatic emitters are movable in a direction parallel to a rotation axis of the rotatable body or bodies.
Optionally, the electrostatic emitters comprise ion generators.
Optionally, the device comprises a control unit arranged to control the electrostatic emitters so as to create a pattern into the fibrous structure.
According to a further aspect there is provided a method of electrospinning comprising:
Optionally, the method further comprising the step of controlling the electrostatic emitters so as to form a pattern in the fibrous structure.
These and other aspects of the invention are apparent from and will be elucidated with reference to the embodiments described hereinafter. In the drawings,
In the embodiment shown in
In the embodiment shown in
The device 1 may also comprise a control unit 15 arranged to control the static emitters 10 so as to create a pattern into the fibrous structure 8, as will be explained below.
For example, when the tip portion of the nozzle 3 is positively charged, the fibrous structure 8 deposited on the collecting surface 4 has a positive charge. In such a case, since the positively charged fibers 8 repel each other, it is difficult to deposit the fibers consecutively. By locally distributing negative ions on the fiber structure 8, using the negative ion generator, the positive charges of the already deposited fibers can be locally neutralized. As a consequence, once the collecting surface faces the nozzle 3 again, at these locally neutralized locations, the fibers will be attracted, while at the still positively charged locations, the new fibers will be repelled. In this way a pattern can be created into the fiber structure. It is noted that instead of neutralizing certain locations of the fibrous structure, they can be charged negative, giving the same or sometimes even better results.
As mentioned above with reference to
In the embodiments shown in
Finally, the method comprises rotating the collecting surface by means of one or more rotatable bodies, see step 46, causing the collecting surface to face the nozzle and the one or more static emitters 10 alternately.
The method shown in
It should be noted that the above-mentioned embodiments illustrate rather than limit the invention, and that those skilled in the art will be able to design many alternative embodiments. In the claims, any reference signs placed between parentheses shall not be construed as limiting the claim. Use of the verb “comprise” and its conjugations does not exclude the presence of elements or steps other than those stated in a claim. The article “a” or “an” preceding an element does not exclude the presence of a plurality of such elements. In the device claims several means are enumerated. These means may be embodied by one and the same item of hardware or software. The mere fact that certain measures are recited in mutually different dependent claims does not indicate that a combination of these measures cannot be used to advantage.
Number | Date | Country | Kind |
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2019764 | Oct 2017 | NL | national |
Filing Document | Filing Date | Country | Kind |
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PCT/NL2018/050688 | 10/19/2018 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2019/078720 | 4/25/2019 | WO | A |
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