EP2140236A1 - Container unit for storing and protecting laboratory substances - Google Patents

Abstract

The invention relates to a container unit for storing and protecting laboratory substances, comprising a protective housing and at least one metering unit. The metering unit(s) has or have a reservoir and a metering head. To establish the operational readiness of the metering unit(s), the protective housing can be removed from said metering unit. The protective housing has a lower part with at least one suitably shaped cavity for holding the metering unit(s) in a stable position and a cap-type upper part. The upper part can be connected to the lower part in order to form a gas-tight interior. The metering unit(s) is or are placed in the interior of the sealed protective housing for transport and storage purposes.

Description

 CONTAINER UNIT FOR STORAGE AND PROTECTION OF LABORATORY SUBSTANCES

The present invention relates to a container unit for the storage and protection of powdered and pasty substances in amounts which are typical for laboratory applications.

In regionally or globally operating companies, where new substances are developed and intermediates as well as samples from production processes are analyzed, a large amount of time is spent over the entire work process for the necessary logistics processes to distribute these substances in different places in the laboratory or in different laboratories distributed worldwide

Dispensing dispensing containers in receptacles. Especially with dangerous substances, such as toxic or carcinogenic substances, the necessary safety precautions are very time consuming and expensive. The cost of a large dosing system with automatic substance replenishment can not be justified in this type of application, because such systems are very expensive.

To make the workflow more efficient, therefore, there is a need for low-cost dispensers, so that several of these devices can be placed in different locations. Such dosing devices are particularly advantageous if they are designed as retrofittable units, which can be used in high-precision analytical balances. In FR 2 846 632 A1, a

Dosing unit discloses which can be inserted into an actuator and removed from it. The dosing unit essentially consists of a storage container, which is connected to a dosing head. The dosing head has an outlet opening, which can be opened and closed by means of a slide valve. For the purpose of storing the dosing unit with substance contained therein, the entire dosing head, or its openings with an attachable protective cap against the environment can be completed. The disclosed dosing unit is suitable for use in so-called compound libraries, which are often huge substance storage systems with defined and controlled climatic conditions. However, if the metering units are to be shipped worldwide, special attention must be paid to the protection of the metering unit and the substance contained therein, for example with measures against the ingress of moisture or contamination and to avoid personal accidents, which could be caused for example by toxic substances ,

In an effort to protect the integrity of the substance and avoid the risk of personal injury, the present invention therefore seeks to provide a laboratory substance container unit.

- which is safe and easy to handle, - which protects the substance contained in it from external influences, such as moisture and impurities,

the personal injuries which could be caused, for example, by substance escaping from the dosing unit and which prevents the unauthorized removal of laboratory substances, and - where appropriate, means for collecting information concerning the substance

Texture and the state of the substance contained in the dosing.

The stated aim is fulfilled by a laboratory substance container unit for the storage and protection of laboratory substances according to the independent device claim.

A laboratory substance container unit for storing and protecting laboratory substances comprises a protective housing and at least one dosing unit. The at least one dosing unit has a storage container and a dosing head. To create the operational readiness of the at least one metering unit, the protective housing can be removed from the metering unit. The protective housing has a lower part with at least one suitably shaped recess for positionally stable accommodation of the at least one metering unit, as well as a hood-shaped upper part. The upper part is connectable to the lower part to form a dense interior. The at least one metering unit is arranged for transport and storage purposes in the interior of the closed protective housing.

Densely means in connection with the present invention, that the closed protective housing at least the escape of laboratory substance into the environment, or the entry of dirt from the environment in the

Interior of the protective housing prevented. Preferably, however, the protective housing is gas-tight, so that, for example, the penetration of moisture into the interior can be prevented and thereby also environmental influences can be kept away from the laboratory substance.

Preferably, upper part is connected by means of a threaded connection of low pitch, by means of a bayonet lock with locking element or by means of sealable clamping closures with the lower part. The protective housing has primarily the function that it forms a shield between the environment and the laboratory substance in the dosing unit, so that in particular leakage passages are blocked in the dosing. This lock is necessary because it is almost impossible to make the dosing permanently sealed. The possible leakage passages, which lead into the storage container via the dosing head, comprise in particular the outlet opening and possibly bores in the dosing head for coupling an outflow control device and the connection between the dosing head and the storage container. The protective housing also has the function of a barrier wall surrounding the dosing head, so that substance particles, which could adhere to the outside of the dosing head in the region of the outflow opening after dosing, remain in the interior of the protective housing under secure closure and pose no danger to persons and the environment ,

If the lower part has a flat underside, this flat underside forms a stable base for the laboratory substance container unit.

If the at least one recess is adapted in its shape to the dosing head and the lower part has a flat underside, the lower part alone forms a position-stable receptacle for at least one dosing unit. - A -

In the interior of the protective housing thus more than one metering unit can be accommodated. In order to avoid the mixing (cross-contamination) of different laboratory substances, the interior of the protective housing is preferably designed such that only one dosing unit can be enclosed. Optionally, the interior can also be subdivided so that only one dosing unit can be enclosed in each partial interior.

In order to keep the dosing unit permanently closed in the recess when the protective housing is closed, the hood can have a securing part, by means of which the dosing unit can be secured. The securing section prevents the dosing unit from moving in the protective housing and from improper handling of the laboratory substance container unit destroying the dosing unit inside the protective housing. As soon as the upper part is separated from the lower part, the at least one dosing unit can easily be lifted out of the recess. Of course, other securing means, for example, with the base connected brackets, hooks and eyes for fixing the dosing unit can be used in the recess.

In order to achieve a simple and safe handling and to develop the required protective effect for the laboratory substance contained therein, preferably at least one chamber is formed in the protective housing, which is filled with a treatment agent. The at least one chamber has a directed against the interior passage opening.

Advantageously, the passage opening with a chamber closure gas-tight closable. The present in the chamber treatment agent can thereby be filled during the production process of the protective housing in the chamber and sealed gas-tight with the chamber closure.

Although in everyday use completely gas-tight sealable laboratory containers are known in which, for example, bags are included with moisture treatment agents directly with the substance. In comparison with this usual way of storage, the arrangement according to the invention has enormous advantages in comparison. The treatment agent is always spatially separated from the laboratory substance, there are no problems with the treatment agent in the removal of laboratory substance and in the handling of the laboratory substance container unit. Furthermore, the treatment agent is already present and in an impeccable, for example, unsaturated state, when the chamber closure of the protective housing is opened immediately before the connection of the upper part with the lower part and thus the effect of the treatment agent is activated.

An already opened chamber closure of a protective housing clearly indicates that the protective housing was already in use, that the treatment agent may be saturated or used up and therefore ineffective and that the inside of the protective housing may be contaminated. It may therefore be advantageous if the chamber closure can not be closed again. Optionally, a tear-off tab formed on the protective housing or a tear-off adhesive seal can be used as a chamber closure.

Of course, the chamber closure but can also have all sorts of functional principles and be, for example, a hinged lid or a rotary closure, which can be opened by turning or pivoting and closed again.

Depending on the laboratory substance to be stored, different treatment agents can be used. Known possible treatment agents are, for example, binders such as silicate gel, molecular sieve, activated carbon and activated clay (potash-provided concrete). However, the treatment agent does not necessarily have to be a binder. There are also treatment agents in the chamber can be filled, which bind or displace, for example, the oxygen in the air. Of course, in the case of displacing treatment agents, an outlet must be present between the interior space and the environment, for example a pressure relief valve. The treatment agent is preferably present in solid form, of course, but it may also be filled in liquid or gaseous form in the chamber, wherein the chamber closure, or the passage opening, the

Aggregate state of the treatment agent must be designed accordingly. For Special solutions even reaction components could be filled into the chambers, which should consciously cause a change in the laboratory substance in the reservoir during the storage period. Such special solutions could be used, for example, in aging tests by filling in place of the treatment agent, for example, water or even an oxygen carrier such as potassium nitrate.

The passage opening can of course be designed very different. Preferably, it is designed so that no treatment agent can penetrate through the passage opening into the interior, but this is gas permeable. When using coarse-grained silicate gel, for example, a sieve insert is sufficient, while with fine powders, preferably a gas-permeable membrane or a tissue is arranged in the passage opening.

If the same protective housing is to be used several times, this may include more than one chamber, each chamber having its own chamber closure. In one possible embodiment, each of these chambers can be filled with another treatment agent, so that the treatment agent suitable for the laboratory substance can be activated by opening the corresponding chamber closure. Each chamber closure can of course be provided with appropriate instructions. Of course, multiple treatment agents can be activated simultaneously by removing multiple chamber closures.

Especially with large substance storage systems, it is invaluable if the stored substances can be individually monitored. In order to make it possible to check the condition of the treatment agent or of the laboratory substance, at least one indicator and / or one sensor can be arranged in the at least one chamber and / or in the interior and / or, if present, in the lid chamber. The sensor may be a humidity sensor, a pressure sensor, a gas sensor or an optical sensor.

Advantageously, the at least one sensor is arranged wirelessly or via connecting lines with one in the laboratory substance container unit and / or connected to an externally arranged monitoring unit. The external monitoring unit may be connected to the substance storage management system. As soon as irregularities occur in a laboratory substance container unit, for example, the robot connected to the substance storage management system could automatically pick up the corresponding laboratory substance container unit and place it in a dispensing or disposal station.

If the chamber is provided with a viewing window and an indicator, the condition of the treatment agent or the indoor conditions prevailing in the laboratory substance container unit can also be detected optically. Such an indicator may be a treating agent such as silicate gel itself, which undergoes a color change from blue to red once it has a certain moisture saturation. The monitoring unit described above can then monitor the condition of the treatment agent by means of an optical sensor, wherein the optical sensor does not even have to be arranged in the interior of the laboratory substance container unit, but can detect the color change through the viewing window. The optical sensor can then be permanently installed in the parking space of a laboratory substance container unit.

Of course, the reservoir and / or at least one housing part of the dosing head and / or the protective housing can be made of transparent material. This can easily be checked how much substance is still in the

Laboratory substance container unit is present. Furthermore, it can also be checked whether the dosing head is still sealed or whether laboratory substance is already in the interior of the protective housing or in the recess and thus there is a risk of contamination when removing the protective housing.

In order to protect the laboratory substance filled in the laboratory substance container unit from damaging radiation from the environment, the transparent material may have filter properties for specific light wavelengths or be coated with a material having these filter properties. A known measure is, for example, the use of brown glass, which has such filter properties. If the coated material having filter properties is arranged in the interior, this may also have indicator properties. For example, if too high a relative humidity is present in the interior, the coating material may, for example, become discolored or even opaque due to moisture. The coating material itself can also absorb some of the moisture and thereby serve as a treatment agent.

In addition to the chambers, the protective housing can have at least one gas connection and / or one vacuum connection, which contains a check valve and can be connected to a gas supply or a vacuum pump. The connection of the protective housing with the gas supply or the vacuum pump can be maintained permanently during a storage period or exist only briefly for filling or evacuation. By the gas supply or vacuum pump either a gas or vacuum atmosphere can be generated in the interior of the protective housing, which also spreads through the dosing through and into the reservoir and in the

Dosing unit located air replaced. As a result, for example, the duration of action of the treatment agent filled in the at least one chamber can be influenced. A negative pressure present in the protective housing and in the dosing unit, or a partial vacuum, can act as an additional safety measure, since in the event of a leak, air penetrates into the laboratory substance container unit, but thereby no substance can escape from the laboratory substance container unit into the environment. A hermetic seal is required to maintain the gaseous or partial vacuum inside the container unit. The container unit and the reservoir must of course be carried out sufficiently stable pressure.

In addition to or instead of the gas connection, the protective housing may further comprise at least one externally operable gas cartridge for flooding the interior with a gas. An external actuation means that the dosing unit is first provided with the protective housing and the valve of the gas cartridge can be operated, for example, by means of a pressure or rotary knob accessible from the environment. Depending on the design, the valve of the gas cartridge can be irreversibly opened or closed again. If the valve the gas cartridge can be closed again, with repeated removal of the protective housing in each case after assembly of the laboratory substance container unit whose interior can be re-flooded. Advantageously, an opening should be provided with a check valve, so that the displaced by the gas of the gas cartridge air can escape from the interior into the environment. Such an opening may also be the connection point between the protective housing and the dosing unit when the housing expands under the effect of pressure in the interior so that a short-term leak forms via the connection point and an excessively high pressure in the interior can be reduced by this leak.

By adapting the at least one recess may optionally accumulate on the outside of the dosing adhering dosing in the recess and be trapped in the recess, as long as the dosing head inserted in the recess. The recess may preferably also have an insert which binds the laboratory substance particles to itself. Such inserts could be, for example, a felt insert or a microfibre fabric insert which electrostatically attracts the laboratory substance particles. Of course, other deposits such as a wet sponge, a suction device, rotating cleaning brushes and the like can be used.

In a further embodiment, a marking means can furthermore be arranged on the storage container and / or on the dosing head and / or on the protective housing. This identification means is preferably an RFID tag, a bar code or matrix code tag or a printed or handwritten adhesive label.

Another security element may be the sealing of the laboratory substance container unit with a tamper-proof protective label or a so-called "tamper-proof seal", which protective label for removal of the dosing unit from the protective housing in a visible manner breakable.

Of course, the handling of the laboratory substance container unit described above can be automated by means of a laboratory robot. The laboratory robot could use the methods described below. In a method for filling, transporting and storing a laboratory substance container unit

The storage container of the dosing unit is filled with a laboratory substance and the dosing head is connected to the storage container,

• The dosing unit is inserted into the recess of the base, the

Chamber closure of a passage opening removed or opened and the dosing unit enclosed by connecting the lower part to the upper part in the protective housing,

• the laboratory substance container unit is suitably marked, if necessary sealed and stored or shipped to its destination.

In a method for dispensing substance from a filled laboratory substance container unit

• by separating the upper part from the lower part, remove the protective housing from the dosing unit,

The dosing unit is connected to an actuating device and placed in position over a receptacle,

• the dosing process started,

After the predefined amount of substance has been metered out into one or more receptacles, the metering unit being removed from the actuating device,

• The dosing unit inserted into the recess of the lower part, the chamber closure at least one passage opening removed or opened and the dosing unit enclosed by connecting the lower part to the upper part in the protective housing and • The laboratory substance container unit is again stored or disposed of.

As described above, a monitoring unit for monitoring one or more laboratory substance container units may be present. A method for monitoring a filled and stored laboratory substance container unit may comprise the following method steps:

• there is a measuring signal connection between the sensor permanently or intermittently or by means of a user input initialized with the monitoring unit,

• the monitoring unit continuously and periodically or once receives and records measurement signals emitted by the sensor,

At least one measurement signal received by the monitoring unit or a measured value obtained from the measurement signal is compared with at least one threshold value stored in the monitoring unit,

• when a threshold value is exceeded, a warning signal is sent to the

Monitoring unit associated output unit or transmitted to the indicator.

From the foregoing description it is apparent that the indicator is not necessarily only a substance which indicates a change, for example by means of a color change. An indicator may also be an electronic component which has a monitoring unit and an output unit and optionally a sensor. The threshold value represents a value whose exceeding may have negative effects on the laboratory substance located in the laboratory substance container unit. Thus, for example, for a particular powdered laboratory substance, a relative humidity in the interior of 0% to 15% still have no influence on their flowability, as soon as the value of 15% is exceeded, the individual powder particles begin to stick together. The threshold in this example would thus be 15%. Furthermore, it would also be possible to define a limit value, for example a maximum permissible temperature, above which the total destruction of the laboratory substance must be assumed. A repeated exceeding of a threshold value, in the second example a lower temperature than the limit at which the decomposition process of the laboratory substance begins, could be summed up in connection with the exceeding of the threshold value and thereby make possible a lifetime calculation of the laboratory substance.

Details of the laboratory substance container unit according to the invention can be seen from the description of the exemplary embodiments depicted in the drawings. It shows:

Figure 1 is a three-dimensional view of a laboratory substance container unit according to a first embodiment, wherein the metering unit is inserted in a recess of the lower part of the protective housing and the bell-shaped upper part is lifted from the lower part.

2 shows a laboratory substance container unit according to a second embodiment in section and in the assembled state with a metering unit arranged in the interior;

Fig. 3 is a three-dimensional view of a laboratory substance container unit according to a third embodiment, wherein chambers are formed in the lower part and in the upper part and a monitoring unit, a sensor and a

Gas connection are available;

4 shows the container unit according to the first and third embodiments in the assembled, ready for storage or transport state.

The laboratory substance container unit 100 in Figure 1 represents a first embodiment of the invention. A dosing unit 110 has a slender cylindrical reservoir 1 1 1 and a dosing head 1 12, which are connected to each other by means of a screw connection. The dosing head 1 12 can each have known operating principle, such as a cone valve, a feed screw, a sieve insert, a slide and the like. The specific embodiment of the dosing head 1 12 is thus arbitrary and therefore not relevant to the invention.

The laboratory substance container unit 100 further has a two-part protective housing

120 on. The protective housing 120 includes a lower part 122 and an upper part 121. The connection point between upper part 121 and lower part 122 has a multi-start thread 124. By means of this connection point, the upper part

121 are firmly connected to the lower part 122. In the lower part 122, a recess 123 adapted to the outer contour of the dosing head 12 is provided, so that the dosing unit 110 can be inserted into the lower part 122 in the normal position. The upper part 121 of the protective housing 120, which is placed over the dosing unit 110 set in the lower part 122, is configured essentially as a bell-shaped hood or inverted cup. Instead of the thread 124, of course, other suitable connecting means, such as snaps or clamping claws and the like can be used. Preferably, the joint further comprises sealing means, which are described in more detail in Figure 2.

In this first embodiment, both the upper part 121 and the test tube-like storage container 11 are preferably made of transparent material, so that the laboratory substance can easily be checked visually.

FIG. 2 shows a partial section of a laboratory substance container unit 200 according to a second embodiment, wherein a dosing unit 110 is arranged in the interior 225 of the assembled protective housing 220.

In contrast to the upper part of FIG. 1, the upper part 221 in FIG. 2 has a stepped contour, as a result of which a securing part 229 is present. This securing part 229 engages in such a way on the dosing head 1 12 of the dosing unit 1 10 that this is caught in the recess 223 of the lower part 222. This construction allows a backup of the dosing unit 1 10 in the interior 225, regardless of the Length of the reservoir 1 11, which thus does not have to be adapted to the length of the upper part 221.

So that the two-part protective housing 220 can be closed in a gas-tight manner, the lower part 222 has a frustoconical sealing shoulder 227. The upper part 221 has an annular sealing lip 226, the inner diameter of which is adjusted so far the sealing shoulder 227 that when joining the upper part 221 with the lower part 222, the sealing lip 227 expanded and / or the sealing shoulder 227 is compressed. This implies that at least the sealing lip 226 and / or the sealing shoulder 227 should be made of elastic material.

Furthermore, the lower part 222 has a chamber 228, which can receive a bag with a treatment agent 290. To secure the bag may be arranged at the mouth of the chamber 228, not shown fastening means. The bag could also be glued into the chamber 228 or its dimensions be dimensioned so that it gets stuck in the chamber 228 due to sufficient frictional forces.

FIG. 3 shows a three-dimensional view of a laboratory substance container unit 300 in a third embodiment. In the lower part 322 and in the upper part 321 of a protective housing 320, shown by broken lines, chambers 331, 332 are formed. The chambers 331, 332 each have one, directed to the interior passage opening 333, 334. The chambers 331, 332 can be filled with a treatment agent. The passage openings 333, 334 may be closable with a chamber closure 339. The chamber closure 339 shown in FIG. 3 is an adhesive label which has been removed from the passage opening 333. Of course, other, for example, resealable chamber closures 339 can be used.

In order to make the state of the treatment agent verifiable, an indicator may be present in the chamber 331, 332 or in the interior of the protective housing 320. To visually check the indicator or the treatment agent may be made of transparent material, protective housing 320 or at least have a viewing window 335.

The indicator does not necessarily have to be a visually perceptible agent such as silicate gel or a litmus litmus paper. The indicator can also be a sensor 336, which can be connected to a monitoring unit 337 by means of a galvanic connection 338 and / or by means of a radio connection 338. From the measurement signal of the sensor 336, the monitoring unit 337 can detect the condition of the treatment agent or the climatic conditions of the interior of the protective housing 320 and determine therefrom the state of the filled laboratory substance, the filled treatment agent and possibly also the state of the dosing unit 310 without the protective housing 320 must be opened. If appropriate, the measurement signals and measurement results of the sensor 336 can also be used to determine a expiration date of the laboratory substance, which depends on the storage conditions (remaining life calculation of the laboratory substance).

In order to make the laboratory substance in the laboratory substance container unit 300 durable for as long as possible, the protective housing 320 can furthermore have a gas connection 340. By means of this gas connection 340, for example, a protective gas can be introduced into the interior. The gas connection 340 can also be used to generate a negative pressure in the interior. Due to the pressure difference to the ambient pressure, the protective housing 320 can not open unintentionally or only with great difficulty and thus offers additional protection.

The laboratory substance container unit 400 shown in FIG. 4 essentially corresponds to the container units from FIG. 1 and FIG. 3, but is shown in the closed state. In the interior of the protective housing 420, a dosing unit 410 shown by means of broken lines is arranged. A protective label 490 or a so-called "tamperproof seal" is glued over the connecting joint between the lower part 422 and the upper part 421 of the protective housing 420. FIG. 4 also shows the position of the outlet opening 415 of the dosing unit 410. In addition, it is clearly evident that the recess 423 on the lower part 422 encloses precisely this outlet opening 415 and serves as a collecting tray for laboratory substance particles, which in the Edge region of the outlet opening 415 could adhere. Optionally, the recess 423 may have an insert 429 which binds the laboratory substance particles per se. Such an insert 429 could, for example, be a felt insert or a microfibre fabric insert which electrostatically attracts the laboratory substance particles.

Although the invention has been described by way of illustrating specific embodiments, it will be apparent that numerous other embodiments can be provided with the knowledge of the present invention, for example by combining the features of the individual embodiments and / or individual functional units of the

Embodiments are exchanged. For example, the monitoring unit shown in FIG. 3 and the sensor connected thereto or possibly several sensors for detecting various parameters can also be used in all other laboratory substance container units. Furthermore, further embodiments of the dosing head regarding different closure means and discharge opening are conceivable, as well as various positive connection possibilities and solutions between the upper part and the lower part of the protective housing.

LIST OF REFERENCE NUMBERS

400, 300, 200, 100 laboratory substance container unit

410.310, 110 dosing unit

111 storage tank

112 Dosing head 420, 320, 220, 120 Protective housing

421.321.221.121 upper part

422.322.222.122 lower part 423, 223, 123 recess

124 thread

225 interior

226 sealing lip

227 sealing shoulder 332,331,228 chamber

229 backup lot

290 treatment agents

334, 333 passage opening

335 viewing window

336 sensor

337 monitoring unit

338 galvanic connection or radio connection

339 chamber closure

340 Gas connection 415 Outlet opening 429 insert

490 protective label

Claims

claims

A laboratory substance container unit (100, 200, 300, 400) for storing and protecting laboratory substances, comprising a protective housing (120, 220, 320, 420) and at least one metering unit (110, 310, 410), which metering unit ( 1 10, 310, 410) has a reservoir (1 11) and a dosing (1 12) and which protective housing (120, 220, 320, 420) for establishing the operational readiness of at least one dosing unit (1 10, 310, 410) of this is removable, characterized in that the protective housing (120, 220, 320, 420) has a lower part (122, 222, 322, 422) with at least one suitably shaped recess (123, 223, 423) for positionally stable recording of the at least one metering unit (110, 310, 410) and an upper part (121, 221, 321, 421), wherein the upper part (121, 221, 321, 421) to form a sealed interior (225) with the lower part (122, 222, 322 , 422) is connectable and the at least one metering unit (110, 310, 410) for transport and Lagerun in the interior (225) of the closed protective housing

(120, 220, 320, 420) is arranged.

2. Laboratory substance container unit (100, 200, 300, 400) according to claim 1, characterized in that the recess (123, 223, 423) is adapted to the dosing head (1 12).

3. Laboratory substance container unit (100, 200, 300, 400) according to claim 1 or 2, characterized in that the upper part (121, 221, 321, 421) has a securing part (229), by means of which the dosing unit (110, 310 , 410) in the closed housing (120, 220, 320, 420) in the recess (123, 223, 423) is securable.

4. Laboratory substance container unit (100, 200, 300, 400) according to one of claims 1 to 3, characterized in that the protective housing (120, 220, 320, 420) has a flat underside which provides a stable base for the laboratory substance Container unit (100, 200, 300, 400) forms.

5. Laboratory substance container unit (100, 200, 300, 400) according to one of claims 1 to 4, characterized in that in the lower part (122, 222, 322, 422) and / or in the upper part (121, 221, 321, 421 ) at least one chamber (228, 331, 332) is formed such that the at least one chamber (228, 331, 332) can be filled with a treatment agent (290), wherein the chamber (228, 331, 332) bears against the interior ( 225) directed through opening (333, 334).

6. laboratory substance container unit (100, 200, 300, 400) according to claim 5, characterized in that the passage opening (333, 334) with a chamber closure (339) is gas-tight closable.

7. laboratory substance container unit (100, 200, 300, 400) according to one of claims 1 to 6, characterized in that in the at least one chamber (228, 331, 332) and / or in the interior (225) an indicator and / or at least one sensor (336) is arranged.

8. Laboratory substance container unit (100, 200, 300, 400) according to claim 7, characterized in that the at least one sensor (336) via a galvanic

Connection (338) or via a radio link (338) with a in the laboratory substance container unit (100, 200, 300, 400) arranged and / or connected to an externally arranged monitoring unit (337).

9. laboratory substance container unit (100, 200, 300, 400) according to one of claims 1 to 8, characterized in that the at least one chamber (228, 331,

332) is provided with a viewing window (335).

10. Laboratory substance container unit (100, 200, 300, 400) according to one of claims 1 to 9, characterized in that the storage container (1 1 1) and / or at least one housing part of the dosing head (1 12) and / or the upper part (121, 221, 321, 421) and / or the lower part (122, 222, 322, 422) of transparent

Material are made.

1 1. Laboratory substance container unit (100, 200, 300, 400) according to claim 10, characterized in that the transparent material filter properties for has certain light wavelengths or coated with a material having these filter properties.

12. laboratory substance container unit (100, 200, 300, 400) according to claim 1 1, characterized in that coated, filter properties having material in the interior (225) is arranged and indicator properties and / or

Having treatment agent properties.

13. Laboratory substance container unit (100, 200, 300, 400) according to one of claims 1 to 12, characterized in that the protective housing (120, 220, 320, 420) at least one gas connection (340) and / or a vacuum connection (340 ), which includes a check valve and is connectable to a gas supply or a vacuum pump through which gas supply or vacuum pump in the interior (225) of the protective housing (120, 220, 320, 420) either a gas or a negative pressure atmosphere can be generated.

14 laboratory substance container unit (100, 200, 300, 400) according to one of claims 1 to 13, characterized in that the protective housing (120, 220, 320, 420) at least one externally actuable gas cartridge for flooding the interior (225). having.

15. Laboratory substance container unit (100, 200, 300, 400) according to one of claims 1 to 14, characterized in that a marking means on the reservoir (11 1) and / or on the dosing head (112) and / or on the protective housing

(120, 220, 320, 420), said identification means preferably being an RFID tag, a bar code or matrix code tag, or printed or handwritten glue.

16. Laboratory substance container unit (100, 200, 300, 400) according to one of claims 1 to 15, characterized in that the laboratory substance container unit (100, 200, 300, 400)

200, 300, 400) is sealed with a tamper evident protective label (490), which protective label (490) for removing the dosing unit (1 10, 310, 410) from the protective housing (120, 220, 320, 420) in a visible manner breakable ,

17 laboratory substance container unit (100, 200, 300, 400) according to one of claims 1 to 16, characterized in that the recess (123, 223, 423) has a liner (429) for binding of laboratory substance particles.

18. A method for filling, transporting and storing a laboratory substance container unit (100, 200, 300, 400) according to one of claims 1 to 17, characterized in that

a. the storage container (1 1 1) of the dosing unit (1 10, 310, 410) is filled with a laboratory substance and the dosing head (1 12) with the reservoir (1 1 1) is connected, b. the dosing unit (1 10, 310, 410) in the recess (123, 223, 423) of the

Lower part (122, 222, 322, 422) is inserted, the chamber closure (339) of a passage opening (333, 334) is removed or opened and the dosing unit (1 10, 310, 410) by connecting the lower part (122, 222, 322 , 422) is enclosed with the upper part (121, 221, 321, 421) in the protective housing (120, 220, 320, 420), c. the laboratory substance container unit (100, 200, 300, 400) is suitably labeled, optionally sealed and stored or shipped to its destination.

19. A method for dispensing laboratory substance (150) from a filled laboratory substance container unit (100, 200, 300, 400) according to one of claims 1 to 17, characterized in that a. in that the protective housing (120, 220, 320, 420) is removed from the metering unit (110, 310, 410) by separating the upper part (121, 221, 321, 421) from the lower part (122, 222, 322, 422), b. the dosing unit (1 10, 310, 410) is connected to an actuating device and positioned over a receptacle, c. the dosing process is started, d. after dosing out the predetermined amount of substance (s) in one or more receptacles, the dosing unit (1 10, 310, 410) is removed from the actuator, e. the dosing unit (1 10, 310, 410) in the recess (123, 223, 423) of the lower part (122, 222, 322, 422) is inserted, the chamber closure

(339) a passage opening (333, 334) is removed or opened and the dosing unit (1 10, 310, 410) by connecting the lower part (122, 222, 322, 422) with the upper part (121, 221, 321, 421) enclosed in the protective housing (120, 220, 320, 420) and f. the laboratory substance container unit (100, 200, 300, 400) is stored again or disposed of.

20. A method for monitoring a filled and stored laboratory substance container unit (100, 200, 300, 400) according to claim 7, characterized in that a. between the sensor (336) continuously or periodically or by means of a

User input initializes a measurement signal connection with the monitoring unit (337), b. received and recorded by the monitoring unit (337) continuously or periodically or once by the sensor (336), c. at least one measurement signal received by the monitoring unit (337) or a measured value obtained from the measurement signal is compared with at least one threshold value and / or limit value stored in the monitoring unit (337), d. when exceeding a threshold value and / or a limit value

Warning signal is transmitted to an output unit belonging to the monitoring unit (337) or to the indicator.