RU2817562C1 - Piezoelectric dispenser - Google Patents

Abstract

FIELD: measurement.

SUBSTANCE: invention relates to liquid dosing devices intended for operation in printers. Piezoelectric dispenser, including a liquid supply chamber with a membrane, the nozzle cross-section is created by etching along the axes of the crystal, consisting of two glued plates, in one of which there are functional recesses for an inlet channel of liquid supply and a liquid supply chamber with a membrane, to which a piezoelectric element is attached. Wherein nozzle overhang channel features triangular shape while plates feature equal roughness of face part along the entire perimeter of nozzle outlet and wetting angle equal along nozzle perimeter.

EFFECT: increased grouping at drop exit from the nozzle.

1 cl, 4 dwg

Description

The invention relates to devices for liquid dispensing, intended for use in printers. Such devices are widely used and are integrated into various dosing systems, which require that these devices deliver droplets in volumes ranging from several picoliters to several nanoliters with high accuracy and sufficiently high frequency.

Piezoelectric dispensers are well-known and effective devices used in various fields of technology. These devices are highly efficient when used for dispensing in various printers. The scope of application of piezoelectric dispensers is extensive, but in each case the characteristics of such devices are significantly different, for example, the following dispensers are known:

A known piezoelectric dispenser with a longitudinal transducer and a replaceable capillary tube (International application PCT/US2012/022091), applicant Biodot INC. The longitudinal transducer typically contains a piezoelectric actuator connected to a tube. Actuating the piezoelectric actuator with a voltage pulse causes radial inward movement of the tube and generates an acoustic pressure or stress wave through the tube wall, resulting in axial motion and displacement of the tube wall.

Known patent US6232129 is a device with a piezoelectric drive for collecting and dosing liquid samples. Liquid samples are collected or drawn into the device by immersing the tip in the liquid. Next, the tip is placed in the printing area, and an electrical signal is applied to dispense the liquid. The device optionally includes a second piezoelectric element that acts as a sensor to determine whether the dispenser is full, clogged, or functioning properly.

The devices described above are difficult to manufacture, because their creation requires many specific elements, and the use of capillary tubes gives the advantage of replacing them, but at the same time has a significant drawback, which is manifested in the fact that for the new tube the flight path of the drop will be different from the flight path that was before. Also, these devices take up significantly more space than classic ones. Consequently, when using dispensers with replaceable tubes, it becomes difficult to use them in printer devices, for example, those aimed at mass production of oligonucliotide matrices. In this case, classic piezoelectric dosing devices (without a replaceable tube) have an advantage.

The closest analogue of the claimed invention is a piezoelectric dispenser of US patent No. 5094594, which consists of a pump unit with a corresponding chamber and a deformable chamber segment on which an electrically controlled piezoelectric element is located. The pumped liquid is supplied to the pump chamber through the inlet capillary (inlet channel). This pump is designed to generate microdroplets and consists of at least one pumping chamber (liquid supply chamber), or several chambers located in parallel.

One of the main disadvantages of the analogues of this invention is the creation of dispensers with a nozzle, the surface of which at the outlet has a different roughness along the length of the perimeter of the hole, namely: Dispensers are made of two plates of a composite material of silicon and glass, which are connected to each other by an anode connection. The end part of such plates made of different materials has different roughness, in addition to this, when creating a channel for a nozzle in the plate (plates), the edges of this channel have significant inhomogeneities (irregularities) due to the manufacturing process. As a result, at the nozzle exit, part of the liquid comes into contact with one plate, part with another, and irregularities at the nozzle exit significantly increase the perimeter of the hole. During operation of the dispenser, this leads to the deviation of the drop from the desired trajectory, i.e. products are being created in which, when dosing, the liquid can be deflected at different angles, therefore, the creation of serial samples with the same characteristics becomes problematic. Even the significantly problematic process of reducing the surface roughness at the output by means of chemical polishing can only partially compensate for this problem.

From the prior art it is believed that the shape of the nozzle is not significant in the case of using capillary tubes (used in analogues), however, for dispensers similar to the prototype, the shape of the nozzle plays a significant role due to the characteristics of the surface roughness at its outlet. In this case, the influence of roughness plays a significant role, because the contact angle depends on it. Depending on the contact angle, the drops can deviate significantly from the desired trajectories, which leads to a decrease in accuracy when the drops hit the desired location.

Unlike the analogue, the proposed invention is created not from silicon and glass wafers, but from two silicon ones by means of bonding, in one of which, like in the analogue, channels (regions) are formed by liquid etching, but along the crystallographic direction of the semiconductor. The use of identical wafers and etching along the crystallographic direction of the semiconductor increases repeatability when creating different samples and allows you to create dispensers with almost the same roughness of the end part along the entire perimeter around the nozzle exit. In this case, the nozzle is triangular in shape. Drops leaving such a nozzle have a smaller deviation from the desired trajectory than from a nozzle of another shape.

The technical result of the claimed invention is to increase the accuracy when drops fly out of the nozzle.

The technical result is achieved due to the triangular cross-section at the output and the use of identical silicon wafers. Increasing the accuracy makes it possible to increase the accuracy of droplets hitting a given point when using a piezoelectric dispenser in printers.

Figure 1 shows the dependence of the droplet volume on the contact angle for fixed liquid parameters, pulse duration and average liquid velocity (potential difference) through the cross section at the nozzle exit for fixed other system parameters - a, dependence of the droplet deflection angle on the difference in contact angles θ ₁ - θ ₂ (θ ₁ and θ ₂ – wetting angles in degrees, corresponding to different halves of the nozzle perimeter at the outlet) with the remaining parameters of the system fixed - b, dependence of the drop deflection angle on the distance to the plane parallel to one of the sides of the triangular nozzle and dividing the perimeter of its cross-section in half (the distance from this plane to the parallel face of the nozzle section is plotted in the positive direction, and the vertical lines correspond to the boundaries of the nozzle section) - c.

In fig. Figure 2a shows a drawing (top view) of the dispenser, and a three-dimensional diagram of the geometry of the functional elements of the internal part (Fig. 2b) in the proportion 1:2:5 (length:width:height), where 1 is the nozzle (with a triangular outlet), 2 is the outlet channel, 3 – inlet channel to the liquid supply chamber, 4 – liquid supply chamber, 5 – membrane, 6 – piezoelectric element.

In fig. Figure 3 shows a photograph of a dispenser layout – a and a triangular nozzle – b.

The use of piezodosers is effective for various types of printing, because These dispensers allow droplets to be ejected with high frequency, which is accompanied by high speeds. At such speeds, the wetting angle of the nozzle surface, caused by the roughness of the end part, plays a particularly important role. Using numerical modeling, we have shown that the volume of an emitted drop significantly depends on the contact angle (Fig. 1a), and how much the drop will deviate in flight depends on how much the contact angle is the same at different points along the perimeter of the nozzle (Fig. 1b) .

The inventive piezodischarger is made of two plates, the technological channel of the nozzle is made in one plate. In this case, at a fixed difference in contact angles for a triangular nozzle, the value of the drop deflection angle corresponds to the intersection of the right vertical line in Fig. 1c and the curve of the dependence of the angle of deflection of the drop on the distance to the plane parallel to one of the sides of the triangular nozzle and dividing the perimeter of its cross-section in half.

The contact angle significantly depends on the surface roughness. From fig. 1 it can be seen that creating a nozzle with a wetting angle that is the same along its entire perimeter is a priority task for the serial production of piezodispensers. This influence of the contact angle on the operation of the dosing system is due to the high droplet emission rates, which are characteristic of piezodispensers. Note that even strong changes in the geometry of the nozzle cross-section do not lead to such deviations as shown in Fig. 1b.

The droplet emission channel in the proposed invention is technologically created as follows: A mask based on a resist or dielectric or metal with a topological pattern repeating the shape of the dispenser channel is formed on the semiconductor wafer. Through the formed mask, a channel in the semiconductor is etched using a liquid etchant. Since the etching rate of the semiconductor substrate differs depending on the crystallographic direction, a triangular shape of the dispenser output nozzle is formed. In fig. Figure 2 shows a drawing of a dispenser with a triangular nozzle.

The implementation of this invention is as follows:

Piezoelectric dispenser, an example of the implementation of which is shown in the photograph of Fig. 3a has an internal geometry, an example of which is shown in FIG. 2b.

In fig. Figure 4 shows a cross-sectional diagram of the dispenser (the cutting plane runs along line 12 in Fig. 2a perpendicular to the figure), in which 1 is a nozzle (with a triangular outlet), 2 is an output channel, 3 is an inlet channel to the liquid supply chamber, 4 is a liquid supply chamber , 5 – membrane, 6 – piezoelement, 7 – plate on which the piezoelement is attached, 8 – plate with technological channels, 9 – gluing area of the piezoelement, covered with a thin electrically conductive layer, 10 – thin electrically conductive layer, 11 – thermoplastic polymer resin that fixes the piezoelement .

The dispenser operates by squeezing liquid through channel 2 and nozzle 1 (Fig. 4) under the mechanical (acoustic) effect of the piezoelectric element 6 (Fig. 4) on the membrane 5 (Fig. 4). Liquid enters through channel 3 (Fig. 4). The mechanical effect is carried out by means of the piezoelectric effect that occurs when creating a potential difference between the plates 9 and 10 (Fig. 4). As a result, when a pulse-type signal is applied to plates 9 and 10 (Fig. 4), a droplet flies out of nozzle 1 (Fig. 4). At the exit, nozzle 1 (Fig. 4) has the appearance shown in Fig. 3b.

Experimental testing was carried out on five dispensers with a square and 5 dispensers with a triangular nozzle. It has been proven that in the case of a square nozzle, the cross-sectional area of which at the outlet is equal to the cross-sectional area of the triangular nozzle at the outlet, when applying a potential difference from 30 to 300 V, the angle of deflection of the drop from a given direction is from 30 to 45 degrees, while for a triangular nozzle it does not exceed 10 degrees.

Claims (1)

Piezoelectric dispenser, including a liquid supply chamber with a membrane, the nozzle cross-section is created by etching along the axes of the crystal, consisting of two glued plates, in one of which functional recesses are created for the liquid supply inlet channel and a liquid supply chamber with a membrane, to which a piezoelectric element is attached, characterized by that the exit channel in the nozzle cross-section has a triangular shape and the plates are made with the same roughness of the end part along the entire perimeter around the nozzle exit and a wetting angle that is the same along the entire perimeter of the nozzle.