DE20112192U1 - Device for providing liquids - Google Patents

Description

Device for providing liquids

The invention relates to a device for providing chemical and/or biological liquids containing particles. The liquids are provided for microsystems. Microsystems are, for example, systems such as chip structures, micropumps and the like, which have channels with small dimensions.

A micropump is used to pump tiny amounts of liquids. For example, micropumps are used in automatic dispensing devices to fill titer plates with chemical and/or biological liquids. The micropumps dispense liquid drops with a volume of a few μl, in particular a few nl. Such micropumps have a chamber onto which pressure is exerted using a piezo element. This releases a small drop through a capillary outlet channel of the micropump. Both the feed channel

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Both the inlet channel and the outlet channel to the chamber of the micropump have very small diameters of less than 200 μm, in particular less than 100 /cm. The micropump is connected to a liquid reservoir. The connection is generally made via a thin silicone tube or the like. Silicone tubes with an inner diameter of 1 mm or less are usually used.

Due to the small dimensions of the microsystem, such as the micropump, blockages easily occur when providing chemical and/or biological liquids that contain particles. The particles can be, for example, cells, molecules or the like that are to be supplied to the microsystem or are conveyed by the microsystem, such as a micropump. Protein agglomerates or vesicles or other contaminants can form in liquids containing such particles.

These contaminants have a significantly larger diameter than the particles that are to be fed into the microsystem. This can lead to blockages in the microsystem. Due to blockages, for example, it is no longer possible to pump the liquid using the micropump. In particular, in tests where a large number of samples are examined within a short period of time, this can result in the entire test having to be repeated if the micropump becomes blocked during the test and the tests are delayed. In such tests, it is often not possible to clean the pump and then continue the test. This is particularly the case when it is

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sensitive liquids that react, for example, with oxygen or other fluids or gases surrounding the sample.

The object of the invention is to provide a device for providing particle-containing chemical and/or biological liquids for microsystems, which reduces the risk of blockages in the microsystems.

The object is achieved according to the invention by the features of claim 1.

The device for providing particle-containing chemical and/or biological liquids for microsystems has a liquid reservoir and a tubular fluid element, such as a hose. The tubular fluid element is connected to an outlet nozzle of the liquid reservoir and serves to connect the liquid reservoir to the microsystem, for example a micropump. According to the invention, a tubular connecting element is provided which serves to connect the fluid element to the liquid reservoir. The fluid element is thus connected to the liquid reservoir via the tubular connecting element. According to the invention, the tubular connecting element projects into the liquid reservoir. An inlet opening of the connecting element is thus arranged within the liquid reservoir, i.e. within the liquid. The liquid is therefore not removed from the liquid reservoir via the outlet nozzle at the bottom of the liquid reservoir.

Contaminants can therefore settle on the bottom of the liquid reservoir without being able to enter the microsystem connected to the device according to the invention. The risk of the microsystem becoming clogged by contaminants, such as particle agglomerates forming in the biological and/or chemical liquid, is thus significantly reduced.

Preferably, the inlet opening of the tubular connecting element is arranged at a vertical distance from the bottom of the liquid reservoir. The liquid reservoir thus has a dead volume in the bottom area in which contaminants, such as particle agglomerates formed in the chemical and/or biological liquid, can be deposited.

To attach the tubular connecting element to a conventional outlet nozzle of a liquid reservoir, a sealing sleeve is preferably provided which can be attached to the outlet nozzle. The sealing sleeve is preferably put over the outlet nozzle and has a central opening in which the tubular connecting element is held. This allows the tubular connecting element to be easily pulled off the outlet nozzle together with the sealing sleeve. After removing the tubular connecting element from the liquid reservoir, it can be easily cleaned because the liquid reservoir now has a relatively large outlet opening in the outlet nozzle through which the contaminants can be flushed out.

The tubular connecting element is preferably a capillary with an inner diameter of less than 2 mm, in particular less than 1 mm and particularly preferably less than 0.8 mm. The outer diameter of the capillary preferably corresponds essentially to the inner diameter of the fluid element, such as a silicone hose. The tubular connecting element can thus be connected to the fluid element in a simple manner by plugging it in. A separate fastening of the fluid element to the connecting element is not necessary since there is sufficient friction between the two elements with appropriately selected diameters. The capillary is preferably made of PEEK material (polyetherketone).

The device according to the invention is particularly suitable for chemical and/or biological liquids containing particles that tend to form agglomerates and then sediment.

The invention is explained below using a preferred embodiment with reference to the accompanying drawing.

The drawing shows a schematic, partially sectioned side view of a preferred embodiment of the device according to the invention. / ^:

A liquid reservoir 10 is filled with a chemical and/or biological liquid 12 containing particles. To remove the liquid 12 from the liquid reservoir 10, the liquid reservoir 10 indicates

a base 14 and an outlet nozzle 16. A tubular connecting element 18 in the form of a capillary is introduced from the outside through the outlet nozzle 16. The capillary 18 has a significantly smaller outer diameter than the inner diameter of the outlet nozzle 16.

A sealing sleeve 20 is provided to hold the tubular connecting element 18 and to seal it off from the liquid reservoir 10. The sealing sleeve 20, which is preferably made of elastic plastic, is slipped over the outlet nozzle 16, which has a round cross-section. The rotationally symmetrical, U-shaped cross-section sealing sleeve 20 has a through-opening 22 for receiving the tubular connecting element 18. The diameter of the through-opening 22 is slightly smaller than the outer diameter of the connecting element 18, so that the connecting element 18 is held in a sealing manner in the through-opening 22. An additional holder for the connecting element 18 is not required. Simply attaching the sealing sleeve 20, which carries the connecting element 18, is sufficient for fastening.

Likewise, a fluid element 24, such as a silicone hose, is simply plugged onto the end of the connecting element 18 that protrudes downwards from the sleeve 20 in the figure. For this purpose, the outer diameter of the connecting element 18 is selected such that it is slightly larger than the inner diameter of the fluid element 24. By plugging on a fluid element designed as a silicone hose or the like, a firm and tight connection is thus achieved.

The connecting element 18 is thus arranged partially within the liquid reservoir 10, so that an inlet opening 26 of the connecting element 18 is arranged within the liquid 12. The inlet opening 26 is at a vertical distance from a base 14 of the liquid reservoir 10. It is thus possible for contaminants 28 to collect in the area of the base 14 around the tubular connecting element 18 without entering the connecting element 18 through the inlet opening 26. This prevents contaminants 28 from the liquid reservoir 10 from being fed to a microsystem, such as a micropump, via the hose 24. In addition, the inlet opening can be provided with a membrane. This is permeable to particles but impermeable to contaminants. This increases the security that no contaminants can enter the microsystem.

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Claims (5)

1. Device for providing particle-containing chemical and/or biological liquids for microsystems, in particular micropumps, with
a liquid reservoir ( 10 ) and
a tubular fluid element ( 24 ) connected to an outlet port ( 16 ) of the liquid reservoir ( 10 ) for connecting the liquid reservoir ( 10 ) to the microsystem,
characterized ,
that the fluid element ( 24 ) is connected to the liquid reservoir ( 10 ) via a tubular connecting element ( 18 ) and that the connecting element ( 18 ) projects into the liquid reservoir ( 10 ). 2. Device according to claim 1, characterized in that an inlet opening ( 26 ) of the connecting element ( 18 ) is arranged at a vertical distance from a bottom ( 14 ) of the liquid reservoir ( 10 ). 3. Device according to claim 1 or 2, characterized in that the connecting element ( 18 ) is fastened to the outlet nozzle ( 16 ) with a sealing sleeve ( 20 ). 4. Device according to one of claims 1-3, characterized in that the connecting element ( 18 ) is inserted into the fluid element ( 24 ). 5. Device according to one of claims 1-4, characterized in that the connecting element ( 18 ) has an inner diameter of less than 2 mm, in particular less than 1 mm and particularly preferably less than 0.8 mm.