DE2224331C3 - - Google Patents

Description

The invention relates to a device for applying precisely metered amounts of liquid to a Application area according to the preamble of claim 1.

A device of the type mentioned is already known in which the application a precisely dosed amount of liquid is carried out by a compressed air pulse that acts on a ball that floats in the needle on the liquid in it. The known arrangement is relatively expensive, since it has a special compressed air source in addition to the actuation movement of the needle requires.

Furthermore, an application device is known in which the application is carried out only by using a liquid supply communicating with the needle, by means of which a very low liquid pressure of a few centimeters of water is provided, which moves a uniform application of a coating material in the form of longitudinal strips on a liquid outlet opening opposite Medium yields
In the known device, a preliminary suction process is required at the beginning of the order in order to direct the liquid outlet into the path, so that the known device is intended essentially only for a continuous coating, but for a punctiform coating

ίο without additional, automatically operated suction devices would not be suitable.

The present invention is based on the object of providing a coating device of the initially described mentioned type in such a way that they can be used without the use of their own compressed air sources or at Suction devices to be actuated for each coating process for a point coating suitable is

This object is achieved according to the invention as stated in the characterizing part of claim 1.

Further refinements of the invention are characterized in the subclaims.

The invention will then be described with reference to an embodiment shown in the drawings.

F i g. Fig. 1 is a plan view of an example of application of the device according to the invention and a setting Disposable thermometer, which by the simultaneous application of precisely dosed amounts of a liquid Substance has to be prepared in 45 separate places;

F i g. Figure 2 is an elevation of the device with only two needles shown and
F i g. 3a to 3g show a sequence of operations when applying the amount of liquid to the application surface.

The liquid used in the device according to the invention can consist of only a single component or consist of several components; it can also be a solid substance at room temperature that is used for Application must be liquefied by heating and again after deposition on the application surface stiffens.

F i g. Fig. 1 shows a continuous strip or plate 10 which is spaced apart with a Device 12, e.g. B. a disposable thermometer (shown by the dash-dotted outline because the Device 12 is eventually separated from the strip 10), is provided thereon in a number of locations precisely dosed amounts are to be applied.

These places can be, for. B. form a pattern of wells 14 with which the strip is provided, but can the liquid can be deposited on any flat, convex, concave or other surface.

The amount of liquid to be applied at each point can be the same everywhere, but also from one point vary to the next; It is only essential that the amount released at each point is exactly the amount intended Amount corresponds. The strip 10 can have markings 16 which are produced by a photocell 20 (FIG. 2) can be detected.

The device for applying the amounts of liquid has according to Fi g. 2 a holding plate 22 for the hollow needles 24, which are arranged vertically in the holding plate 22, and their lower ends lie in a first position at a distance Ei from the strip 10. The holding plate 22 is on one Slide block 30 attached and for vertical displacement

supported with respect to an upright stand 70. The sliding block 30 is connected at 75 to a hydraulically operated piston 33 which lowers the holding plate for applying the liquid and then pulls it back again. only S two needles 24 are shown; however, there is a special needle for each application point. The holding plate 22 is slidably arranged in a rigidly fixed block 71, which is connected to a further sliding block 72, which in turn is connected to the stand 70 and forms the mechanical connection point between the piston 33 and the sliding area 30. The sliding block 30 also contains a bracket 76 in which an adjusting screw 77 is attached which engages in the holding plate 22 in order to set the latter and with it the lower tip of the needle 24 in its first position, ie change the height E \ to be able to.

Each needle 24 has its own liquid supply 34. Therefore, each needle has a special ampoule 32, in which a liquid supply 34 is accommodated, as well as a supplementary reservoir 36, a valve 38 which controls the flow between the supplementary container 36 and the ampoule 32, and Liquid level sensing elements in the form of a pair of thermistors 40, 42, which are accommodated in the ampoule 32. The supplementary container 36 and the ampoules 32 can be arranged in rows in a manner known per se, the ampoules being in such positions that the liquid level in them is at a distance E ₂ above the strip 10; this distance causes the liquid level of the supply in the ampoule to be approximately the same level as or slightly lower than the lower end of the associated needle when the latter is in its first or upper position. Each needle also includes a capillary line 44 connecting the fluid supply 34 to the top of the needle, each capillary line 44 having a U-shaped bend 46 located above the strip 10 but below the lower end of the associated needle. Each ampoule 32 is provided with a pair of tubular arms; one arm 82 is used for the inlet of air from the atmosphere through the ventilation port 83 to the top of the liquid supply, while the other arm 84 forms a line for the entry of liquid from the supplementary container 36 through the filling line 85. The supplementary container 36 of each unit is also open to the outside atmosphere in that it is provided for this purpose with a cap 88 through which air can enter the supplementary container.

The relative sizes of the ampoule 32 and the needles 24 are shown not to scale in Figure 2, since the distance E \, as described below, about at the output of a particular binary mixture of heat-sensitive substances is 41.3 mm, while in this Trap used ampoules are filled with the liquid supply to a height of 51 mm or more above their bottom.

Each dispenser also includes a magnetically operated diaphragm valve 38 in FIG Filling line 85, which is operated so that the liquid in the ampoule 32, if necessary, from the supplementary container 36 is filled.

When the tubular needles 24 of each dispenser are in their first or upper position, there is practically no difference between the level of the supply level (EJ) and that of the lower end of the needle (E,) and therefore the liquid at the lower end of the The needle does not apply hydrostatic pressure that could cause fluid to flow out of the needle. Furthermore, the size of the capillary line 44 of each dispensing device and its associated needle with respect to the viscosity of the liquid is such that the liquid in the needle and the capillary line is retained by capillary forces and not from the needle and the capillary line into the ampoule 32 can flow back and, as a result, the needle and tube 44 are always fallen with liquid.

In order to apply the liquid to the strip 10, the piston 33 is operated so that it lowers the holding plate 22 at a certain speed in the direction of the strip 10, with the result that a hydrostatic pressure (Ei -E \) is created and an impulse is applied to the liquid at the lower end of the needle so that the liquid begins to flow out of the needle 24, the flow of the liquid being in the form of a drop of liquid caused by capillary action due to the size of the needle and the viscosity of the liquid the lower end of the needle. The downward movement of the retaining plate is interrupted when each needle 24 is in its second or lower position, which is shown in FIG. 2 is shown in dot-dash lines and in which the lower end of each needle is immediately above the strip 10 but does not touch the strip. However, the drop of liquid at the lower end of the needle contacts the strip 10 and the adhesive force of the latter pulls the drop away from the needle. The needles 24 are only held in the second position for a moment, as the holding plate 22 is immediately retracted into the first position and the capillary action in the needle tip prevents the further outflow of liquid, while the dispensed liquid drop corresponds exactly to the desired amount.

The exact dosage is a function of the speed at which the needles 24 are moved downwards and the distance between the first and second positions. If one works with a predetermined speed and a predetermined stroke, the outflow of liquid from the needles as a result of increasing hydrostatic pressure and increasing momentum as the needles move downwards can be controlled in such a way that a dispensed liquid drop of precisely defined size is obtained. In a special application, namely when a binary mixture of o-chloronitrobenzene and o-bromonitrobenzene is dispensed, 0.3 mg of this liquid is deposited with a stroke of 41.3 mm. The traveling speed during the downward movement is essentially V ₈ seconds, the holding time within which the drop of liquid is in contact with the strip is essentially 1/4 second, and the time for the upward movement is Ve seconds. If, with these parameters, the needle has a clear width of 0.5842 mm and the capillary line has a clear width of 0.8636 mm, a liquid drop with a diameter of about 0.76 mm and a weight of 0.3 mg is obtained. The binary mixture used has a viscosity of 3 to 5 cP. If such a binary mixture, which forms a solid solution at room temperature, is to be deposited on a surface, it must be in liquid form, and

therefore, the supply in the ampoules 32 is on one Temperature maintained in the range of 46 to 66 ° C.

When the above-mentioned binary solutions are dispensed, polytetrafluoroethylene is used as the material for the capillary line 44 preferred because it is compatible with the binary solutions and does not react with them.

F i g. 3a to 3g show the chronological sequence in the formation and delivery of a liquid drop 120 the strip 10. In FIG. 3a, the needle 24 is in its first position and the liquid flows through it Capillary action is retained, and at the bottom of the needle there is a meniscus 121. When the When the needle is lowered towards the strip 10, the liquid begins to flow out, forming a Liquid drop, as shown in FIG. 3b and 3c is shown, and this drop increases in size Moves the needle downward and assumes a generally spherical shape. If the If the liquid drop 120 touches the strip 10 at 123, the capillary holding the drop is interrupted and the drop is withdrawn from needle 24 as shown in FIG. 3d is shown. When the needle is raised essentially the reverse sequence of operations takes place as in FIG. 3e to 3g is explained, with the difference that the liquid which is tending after the transition of the drop 120 to flow out of the needle on the strip 10, a slightly smaller spherical mass on the upstroke forms and decreases in size and, when the needle is returned to its first position, fully in the needle has been withdrawn and forms the meniscus 127.

The level of the liquid supply 34 in each ampoule 32 is preferably in a certain Range between a maximum and a minimum value kept so the hydrostatic pressure essentially constant at the lower end of the needle

ίο remains as substantial changes in value £ 2 the The amount of liquid dispensed. For this purpose, each ampoule 32 is provided with a continuously operating liquid level monitoring device in the form of a pair of thermistors 40,42 fitted. The thermistors are mounted in each ampoule 32 at different heights. Usually A thermistor 42 is always immersed in the liquid and serves as a reference sensor. The other thermistor 40 and the Thermistors 42 are connected by coaxial lines 63 to a comparison device 60, which in turn is connected by lines 65 to the magnet of the valve 38. The comparison device 60 includes a highly sensitive electrical bridge that is balanced by signals from the two thermistors is held and in the event of an imbalance, a solenoid valve 38 is actuated to restore the original Restore fluid levels.

For this purpose 2 sheets of drawings

Claims (4)

Patent claims: 1. Device for applying precisely dosed amounts of liquid to an application surface, with at least one tubular, vertically arranged needle and a device for jerky vertical displacement of the needle from an initial position to a position in which the needle tip is at such a distance above the application surface that one on the needle hanging drop touches the application surface, and with a device to increase the pressure the liquid in the needle tip as the needle is lowered, with the tubular needle in relation to it on the viscosity of the liquid in size is such that the liquid in the needle is retained when the needle is in its first position, indicated by a liquid reservoir (34) at such a distance above the application surface (10) that the level of the Liquid reservoir level with or slightly lower than the lower end of the needle (24) is located when this assumes its starting position and the device (33) for displacement the needle (24) brings it back to its starting position immediately after it has reached its lowest position. 2. Apparatus according to claim 1, characterized by one having a holding plate (22) for the needle associated means (71, 76, 77) for selectively adjusting the height of the lower end of the needle above the application surface (10) when the needle is in its initial position. 3. Apparatus according to claim 1, characterized by an arrangement (40, 42, 60) for monitoring of the liquid level in the reservoir (34) and an arrangement (36, 85, 38, 84, 82, 83) for automatic Refilling of liquid as soon as the liquid level in the reservoir (34) falls below a certain level Height decreases. 4. Apparatus according to claim 3, characterized in that the arrangement for receiving the Liquid supply (34) consists of an ampoule (32).