EP1941267A2 - Fitting for holding a probe - Google Patents

Abstract

The invention relates to a fitting for holding a probe, particularly a measuring probe or a sampling probe, with a housing, which has a space for holding the probe and a first chamber for holding a first fluid, which is connected to the space for holding the probe or comprises these, and which has a connecting section by means of which the housing can be connected or is connected to the container that serves to hold a medium whose property is to be measured by the probe or from which a sample is to be removed. At least one second chamber for holding a second fluid is provided inside the housing that is arranged between the first chamber and the connecting section of the housing.

Description

 Description Tap for holding a probe

The invention relates to a fitting for receiving a probe, in particular a probe or a sampling probe, with a housing having a space for receiving the probe and a first chamber for receiving a first fluid, with the space for receiving the probe or comprises, and which comprises a connecting portion, by means of which the housing is connectable or in communication with a container which serves to receive a medium whose property is to be measured with the probe or from which a sample is to be taken wherein the probe has a particular substantially cylindrical, elongated shaft which is displaceable in the axial direction with respect to the housing

The field of application of probes for sampling or for measuring certain properties of a medium is varied. For example, the production of sterile solutions in the sense of drugs and medical devices for peritoneal dialysis and hemodialysis applications or the production of perfusion solutions for flushing organs or rinsing solutions for blood adsorber u. a. The use of pH probes for monitoring the product or the manufacturing process. From the prior art, it is known an in-line pH measurement of products, for. B. to perform solutions in which so-called retractable housings with axially movable probe or receiving device for a pH sensor are used. These retractable housings, lock fittings or Meßwertgeber- devices have a rinsing chamber into which the probe or a sensor can be temporarily moved during calibration for calibration purposes and can be brought into contact with a calibration liquid therein. When the calibration process is completed, the probe or its sensor can be rinsed and / or sterilized and then moved back into the product to measure its pH.

In this case, a contamination of the solution whose pH is to be measured, counteracted with Kalibrierflüssigkeit or vice versa contamination of the calibration liquid through the solution by means of seals between the rinsing chamber and product.

From DE 100 54 272 Al, for example, a retractable housing is known, comprising a housing with a displaceably arranged therein probe with a sensor, if necessary withdrawn from the process or measuring medium out in the valve body and there in a against the media side sealed cleaning or calibration chamber is treated as required. The media side is compared to the washing chamber by means of a shut-off in the form of a ball valve separated. The separation of the rinsing chamber of a retractable fitting from the medium by means of seals inserted in annular grooves is known, for example, from WO 2004/024353, WO 2004/023127, DE 198 43 553 A1 and DE 197 23 681 A1. From DE 100 24 564 A1, a probe device is known whose rinsing chamber designed as a calibration chamber is sealed against the medium to be measured by means of a rotary slide device.

The use of such retractable assemblies in connection with sterile solutions is problematic because on the one hand the long sterilization cycles of pH probes in the product range (container) distort the measured values of the pH probe, whereby such measurements are less reliable. On the other hand, calibration fluids and other foreign substances must never be allowed to enter the product, as this would endanger patient safety. In the case of failure of seals, it would thus come to an unacceptable contamination of the product with calibration liquid (buffer solution), and this contamination would also go unnoticed. Conversely, a contamination of the calibration liquid by the product would be conceivable. Therefore, the use of such a measuring system, the valid GMP criteria (GMP = good manufacturing practice) would not be met. Therefore, the monitoring of the pH in the production of sterile solutions is still done with the help of manual sampling and subsequent, spatially separate analysis in the laboratory using common laboratory methods. In addition to the associated expense, another disadvantage of this approach is that already by the sampling a possible outgassing of CO ₂ may occur from the solution, which would in turn lead to a corresponding distortion of the measurement result.

Thus, it should be noted that an insufficient protection of the product space against the contamination by auxiliary media, which are used in retractable parts exists. Leakage is also not noticed, because the products are usually in large reactors with many measuring points, which can hardly be monitored visually, or because it is highly automated processes with little staff.

The present invention is therefore the object of developing a valve of the type mentioned in that the probability of contamination of the first fluid located in the first chamber by the medium to be measured or for the contamination of the medium to be measured by the said first fluid is reduced. This object is achieved by a fitting with the features of claim 1.

Thereafter, it is provided that in the housing at least a second chamber for receiving a second fluid is provided, which between the first chamber and the connecting portion of the housing is arranged. Unlike the known from the prior art fittings thus an additional chamber is provided in which a second fluid can be accommodated, wherein the second chamber between the first chamber and the medium to be measured or the connecting portion of the housing is arranged. Defective seals reduce the likelihood of contamination of the medium by the first fluid as well as contamination of the first fluid by the medium. In addition, the fitting according to the present invention allows a metrological monitoring of selected properties of the second fluid, which allows an immediate detection of a seal damage.

By fitting the invention, the problem of insufficient protection of the medium / the product or the first fluid against unnoticed leaks within a retractable housing can be overcome. This creates the prerequisite for the use of the desired inline pH measurements.

Possible modes of operation of the first and second chambers or process modes are, for example, rinsing, sterilizing, blowing out, emptying, suction, superimposing with blocking medium, etc. Normal pressure, overpressure and also vacuum operation of the first and / or the second fluid are conceivable. By way of example, product features or characteristics of the medium that can be considered critical are valuable, expensive, combustible, corrosive, toxic, biohazardous, radioactive, etc. With the fitting according to the invention, the discharge of such media from the container into the first chamber as well as the inlet be prevented by fluid from the first chamber into the medium effectively or timely detected.

It can also be recognized which seal is defective. In particular, a targeted gradation of pressure and temperature levels between the individual chambers and the container can be made. The appropriate adjustment of the pressure and temperature levels between the individual chambers and the container results from the respective product and operating conditions.

The fitting according to the invention also has the advantage that suitable sealing materials can be readily used. The interpretation of the seals in known from the prior art fittings z. As regards the material, chemical / thermal properties, compatibility, service life and the like takes place according to the product conditions or represents a compromise. The known from the prior art seals are on the one side of the medium to be measured and on the other side contacted by the first fluid, which is located in the first chamber (rinsing chamber, calibration chamber). Since these two fluids can have very different properties, the seal design is compromised. The according to the prior art used seals may not be optimal for contact with the medium to be measured and / or not optimal for contact with the first fluid.

The fitting according to the invention solves this problem by the fact that the mediens can seal the second chamber according to the conditions imposed by the medium to be measured conditions are designed while the seal in the first chamber are designed according to the conditions given by the first fluid can.

This results in the advantage that the maintenance intervals of the seals can be increased and the service life of the seals is increased. In addition, there are advantages in terms of the reliability of the calibration process due to the avoidance of contamination of the calibration medium.

It is particularly advantageous if the first chamber has an inlet and a drain, by means of which the first fluid can be introduced into and discharged from the first chamber. In a preferred embodiment of the invention it is provided that the first chamber is flowed through continuously. In principle, however, the embodiment also encompasses the fact that the first chamber is flowed through discontinuously or that there is a non-flowing fluid in the first chamber. The type of fluid is largely arbitrary. For example, a rinsing liquid or a calibration liquid, by means of which a probe or its sensor is cleaned or calibrated, may be considered.

Also, the second chamber may have an inlet and a drain, by means of which the second fluid can be introduced into the chamber and discharged from the second chamber. It also applies to the second fluid that this is preferably conducted continuously through the second chamber. Again, a discontinuous mode of operation is conceivable or even the case that the second fluid does not flow through the second chamber, but is in this.

In a further embodiment of the invention it is provided that the inlet and / or the outlet of the second chamber are arranged such that they open in a region in the second chamber, which faces the first chamber. If there is a leakage between the first chamber and the second chamber, in particular the said arrangement of the sequence causes the fluid entering from the first chamber to be detected at an early stage, so that appropriate measures can be taken in good time.

In a further embodiment, a first seal is provided, which seals the first chamber relative to the second chamber. Preferably, it is provided that this is a seal that surrounds the inserted probe sealing. The seal thus assumes a seal between the probe outside and the inside of the housing. If there is a leak in the area of this seal, through the the first fluid from the first chamber flows into the second chamber, this can be detected by means of suitable measuring devices.

In a further embodiment of the invention, a second seal is provided, which seals the second chamber from the environment, in particular with respect to the container interior. Also, this seal is preferably designed such that it surrounds an inserted probe sealing. The seal is also made here between the outside of the probe and the inside of the housing.

In a preferred embodiment of the invention it is provided that the space of

Housing in which the probe is received, is carried out such that the probe penetrates in the housing received in the state of the first chamber and / or the second chamber. It is conceivable, for example, that the housing has an axial extension which coincides with that of the probe and that in the axial direction spaced apart the first and the second chamber are arranged in the housing.

In a preferred embodiment of the invention, the housing is rotationally symmetrical and the first and the second chamber are arranged coaxially in the housing.

In a particularly preferred embodiment of the invention, a measuring device is provided, by means of which at least one property of the second fluid located in the second chamber or flowing out of this second fluid can be measured. Consider, for example, the measurement of the conductivity of the second fluid, which changes in this embodiment, when the second fluid is mixed with the first fluid or with the medium in a container due to leakage. In principle, various other properties of the second fluid are detectable, such as the temperature, the color, absorption properties against light, etc.

The measuring device can be arranged inside or outside the second chamber. It is conceivable, for example, that within the second chamber, a measuring device is arranged, which measures a certain property of the second fluid, which changes upon entry of the first fluid and / or from the medium to be measured in the second chamber. The invention also includes the case where the measuring device is arranged outside the second chamber. It is conceivable, for example, that the second chamber is flowed through by the second fluid and that a property of the effluent from the second chamber medium is detected by the Mes s device.

In a further embodiment of the invention, it is provided that the second chamber has an inlet and that a conveyor, in particular a pump is provided, which is in communication with the inlet of the second chamber and which is designed such that a continuous flow through the second chamber he follows. Furthermore, it can be provided that the first chamber has an inlet and that a delivery device, in particular a pump is provided which communicates with the inlet of the first chamber and which is designed such that a continuous flow through the first chamber.

It is conceivable that said pumps are on the inlet side with different storage containers in combination, which store the corresponding liquids (rinsing and calibration liquids). The rinsing and calibrating fluids may be sterile.

In a further embodiment of the invention it is provided that the valve further comprises a drive unit, by means of which the probe inserted into the housing can be moved between different positions. As already known from the prior art, the probe can be flushed by means of such a drive unit between an operating position in which a property of the medium is to be measured or sampled and in a further position in which the probe is purged is calibrated or the sample is dispensed from the probe.

The type of drive is largely arbitrary. It is conceivable, for example, that the drive unit has a piston which is reciprocably received in a cylinder, wherein the cylinder has connections for compressed air or another pressure medium.

Delay switches or initiators can be used to control the stroke.

The invention also relates to the fitting according to the invention, in the housing of a probe, in particular a sampling probe or a pH probe is added.

The probe can be arranged in the housing manually or by means of the drive unit in different positions movable. The different positions may include a first position in which at least a portion of the probe projects into a medium received in a container with which the fitting communicates and a second position containing at least a portion of the probe located in the first chamber. The said area of the probe may be a sensor of the probe or a sampling device of the probe.

Furthermore, it can be provided that in the first chamber, a rinsing or a calibration solution or a sterilizing fluid is received or that the first chamber is flowed through by a rinsing or calibration solution or a sterilizing fluid. Preferably, it is further provided that in the second chamber, a fluid, which is received in the first chamber and absorbed in relation to the medium received in the container, is received in the second chamber, or that such a fluid flows through the second chamber. A fluid is in this sense uncritical if it is biologically and / or chemically and / or physically neutral to the product and / or the liquid in the chamber. The second chamber can thus be traversed by the medium whose property is to be measured or sampled, and the first fluid by neutral fluid barrier medium or flushing medium, such as distilled water or such a medium can in the second chamber available.

The term "probe" in the sense of the present invention may be understood to mean single-part or multi-part components It is conceivable, for example, that the probe consists of a dip tube or another holder on which or in which a sensor or a sampling device is arranged It is conceivable that the dip tube or the probe has a recess in which a sensor is arranged, it is also conceivable that the probe is formed by the sensor.

For the purposes of the present invention, the term "container" is to be understood as meaning any unit in which a medium can be taken up or through which a medium flows, for example, reactors, storage or preparation containers, or conduits or containers Line sections.

In a further development of the invention, the fitting according to the invention may further comprise a third chamber, which connects to the first chamber at the side facing away from the second chamber. Specifically, the third chamber serves to clean and disinfect an axial portion of the probe shaft that is behind the first chamber during calibration and sterilization of the probe, and that there is no germ entrainment when this axial section of the probe shaft moves the probe enters the measuring position in the first chamber.

An embodiment of this is characterized in that the third chamber has an inlet and a drain, by means of which a fluid in the third chamber can be introduced and discharged from the third chamber.

Furthermore, a third seal may be provided, which seals the first chamber relative to the third chamber, wherein the seal bears against the shaft of the probe, and a fourth seal, which seals the third chamber on its side facing away from the first chamber, wherein the seal abuts the shaft of the probe.

As before, the third seal and / or the fourth seal may be constructed of two sealing elements, preferably two O-ring seals which are axially spaced, further comprising flushing ports through which the space between the sealing elements is flushed and / or can be sterilized.

In addition, a measuring device may be provided, by means of which at least one property of the one located in the third chamber or flowing out of this second fluid is measurable.

In a simpler embodiment, the third chamber serves only as a spacer between the cylinder of a pneumatic drive and the first chamber. This ensures that no axial portion of the probe shaft, which protrudes into the cylinder when the probe retracts, can penetrate into the first chamber when the probe is advanced.

Furthermore, one or more of the first to fourth seals, the valve may be designed as a pneumatically controllable or "inflatable" seal, the seal can either seal under pressure and in the relaxed state, ie without pressure, is open, or vice versa The advantage of such a seal is that the seal will be relaxed during sterilization of the probe shaft and spaced from the probe shaft so that no poorly or non-cleanable gaps remain during cleaning.

Further details and advantages of the invention will be explained in more detail with reference to an embodiment shown in the drawing.

FIG. 1 shows a retractable assembly according to the present invention.

FIG. 2 shows an embodiment of the detail "x" according to FIG. 1.

FIG. 3 shows a further embodiment of a retractable assembly according to the present invention.

The drawing of FIG. 1 is divided into sections A-F, wherein the section A indicates the reactor or product space in which the medium is present, whose property is to be measured or from which a sample can be taken. Section B comprises the so-called blocking medium space, section C the so-called rinsing, changing and calibration space, section D the so-called lantern, section E the drive and section F the shutter and the sensor connection.

The retractable housing has the housing 10, in which the probe 20 is disposed axially displaceable and reciprocable, as indicated by the double arrow. The probe 20 can be, for example, a probe for sampling or also a probe for measuring a specific value of the medium present in the region A. The probe 20 consists of a tube in which openings 21 are introduced, which release an access of the medium or a rinsing liquid to a sensor 22, which is located within the tube of the probe 20.

It is also conceivable that the probe may have cylindrical portions with gradually changed diameter, so that it would be possible to make specific seals accessible by an axial movement of the probe targeted for rinsing and / or sterilization.

With the probe 20 is the piston 110 in conjunction, in which by the Cylinder 120 fixed space axially back and forth and is movable in certain positions. It is also conceivable that the surfaces between the seals and the probe for cleaning and / or sterilization are made accessible by brief cycled reciprocation of the probe during flushing and / or sterilization. The cylinder has connections 122 for the supply and removal of compressed air in the cylinder chambers separated by the piston 110, so that a corresponding movement of the piston 110 and thus also of the probe 20 is possible.

The apparent from Fig. 1 so-called lantern (area D) is designed in terms of their length such that the piston 120 penetrating portions of the probe do not come into contact with the seal 70 'in the axial process of the probe.

As indicated in the end region F shown on the right, the probe 20 has a closure or a sensor connection.

By means of the drive, the probe 20 is displaceable between an operating position and a maintenance position.

In the position shown in the drawing, the probe 20 is in its operating position, in which the openings 21 dive into the medium, which in the area A, i. located in the container 50.

The medium is also due to the openings 21 to the sensor 22, so that the desired property, for example, the pH can be detected.

If the probe 20 is moved to its maintenance position, the compressed air port 122 shown on the left is pressurized with compressed air, whereupon the piston 110 and thus also the probe 20 is moved to the right. When the maintenance position is reached, the openings 21 and the probe 22 are in the position indicated by dashed lines.

As further shown in the figure, is located in the housing 10, a first chamber 30 through which the probe 20 passes. The chamber 30 has two axially spaced passages, in which seals 70, 70 'are provided, which have the task of sealing the first chamber with inserted probe 20 with respect to the adjacent chambers or areas of the housing 10. The first chamber 30 has an inlet 32 and a drain 34. The inlet 32 communicates with the pressure side of the pump 90, by means of which rinsing liquid, calibration liquid or any other liquid is passed through the chamber 30. On the suction side, the pump 90 communicates with various storage containers, which may be connected individually or cumulatively to the pump inlet to direct the desired medium through the first chamber 30.

In FIG. 1, the abbreviations CIP (cleaning in place) and SIP (sterilization in place) are used.

As is apparent from Figure 1, which is from the first chamber 30 via the Outflow 34 measured liquid in terms of their temperature, the pressure and their properties or there is a corresponding regulation of these parameters. Properties may be biological and / or chemical and / or physical properties.

As is further apparent from Figure 1, the openings 21 and the sensor 22 are in the maintenance position within the chamber 30. If the chamber flows through rinsing or Kalibrierflüssigkeiten, carried out according to a cleaning or calibration of the sensor 22nd

The fitting according to the invention has a connecting portion 40, by means of which the fitting or the housing 10 is in communication with the container 50 in which the medium is located, whose property is to be measured. The container has an opening in which a neck is welded, which has an external thread, which is in engagement with a union nut in the connecting portion 40 of the housing 10, so that the housing 10 firmly, but releasably in communication with the container 50. Through the opening of the container 50, the probe 20 is inserted with its sensor 22 having portion in the container 50, as can be seen from Figure 1.

Between this connecting portion 40 and the first chamber 30 is the second chamber 60, which is also penetrated by the probe 20, as can be seen from the figure. The chambers 30 and 60 are spaced apart in the axial direction of the housing 10 and the probe 20 and arranged coaxially. Also, the second chamber 60 has an inlet 62 and a drain 64, by means of which the second fluid is introduced into the second chamber 60 and withdrawn therefrom. The delivery of the second fluid or of the barrier fluid can take place continuously or discontinuously by means of the pump 80, which is connected on the pressure side to the inlet 62 and on the suction side to a container with barrier liquid. The second fluid is a liquid which is non-critical with respect to the medium in the container 50 and to the fluid in the first chamber 30, i. H. if it is biologically and / or chemically and / or physically neutral to the product and / or liquid in the chamber 30. Preferably, the second chamber 60 is supplied with WFI (water for injection) according to pharmacopoeia.

The second chamber 60, like the first chamber 30, has two axially spaced apertures in which the already mentioned seal 70 and the seal 72 are arranged, which seals the chamber 60 with respect to the interior of the probe when the probe 20 is inserted Container 50 and with respect to the first chamber 30 effect.

If there is a leakage in the region of the seal 70, this leads to the fact that the first fluid from the first chamber 30 passes into the second chamber 60 and is mixed with the second fluid located there. As a result, a property of the second fluid changes. This change in a characteristic of the second fluid is detected by means of a measuring device which is arranged outside the housing 10 and which communicates with the outlet 64 of the second chamber, ie the second fluid draining from the chamber 60 is checked for one or more characteristic properties ,

As can be seen further from FIG. 1, a device for measuring the temperature, pressure and properties of the second fluid is located in the region of the discharge line which is connected to the drain 64. Properties may be biological and / or chemical and / or physical properties.

The inventive design of the fitting prevents that in the

Area A present medium penetrates into the chamber 30 in the event of leakage and falsified the calibration process. It is also effectively prevented that calibration liquid from the chamber 30 enters the medium present in the region A, so that the present retractable assembly is particularly suitable for the production or monitoring of sterile solutions. Of course, other applications come into consideration.

A leak can be detected immediately due to the measurement of a property of the exiting from the second chamber 60 second fluid, so that immediately appropriate measures can be taken. It is conceivable that the measured parameters are used directly for process automation. An unnoticed, longer-lasting leakage that leads to the mentioned contamination can thus be excluded. Another advantage is that the seals 70, 70 'and 72 can be designed according to the properties of the adjacent media or fluids and that fewer compromises have to be made with regard to the selection of the sealing material.

This results in longer service lives and longer maintenance intervals with simultaneously improved functionality.

FIG. 2 shows an embodiment of the detail "x" according to FIG. 1 and thus relates to the sealing between the region A and the second chamber 60 or between the second chamber 60 and the first chamber 30.

The respective seals located between these regions or chambers can, in a preferred embodiment of the invention according to FIG. 2, be constructed from two spaced O-ring seals 73 each. The intermediate space between these sealing rings 73 can be rinsed and sterilized in this preferred embodiment of the invention analogous to the procedure in a known rinsing chamber via rinsing connections Nl and N2. The retractable assembly shown in Fig. 3 relates to a development of the invention, the process side or container side has substantially the same structure as the embodiment described above. In front of a first chamber 230, which is used in particular for calibrating and sterilizing the probe, a second chamber 260 is connected upstream to the process, in order to avoid media carryover to the process. The chambers have seals 270, 272 against each other and include ports for fluids 232, 234, 262, 264 to pressurize the chambers with the required media.

In addition, on the side facing away from the second chamber 260 of the first chamber 230, a third chamber 290 is provided to sterilize a rear Schaftabschitt, which is in the retracted position of the probe 220 between the pneumatic drive unit in the third chamber , For this purpose, the chamber comprises connections 292, 294 for a supply line and a discharge line for the required media.

In summary, it should be noted that the damage and leakage risk is minimized or calculable by the fitting according to the invention. Maintenance, operating costs and personnel costs are minimized. Due to automatable and thus reproducible operating conditions ultimately increase the life of the probes.

As stated above, the arrangement according to the invention is not limited to the field of sterile solutions, but can be used anywhere in the form of retractable fittings, where contamination of the product or an auxiliary medium prevented for different reasons or a seal damage must be detected or leakage of the product from area A into the environment must be prevented.

It is also an application as a sampling device conceivable.

Fields of application are, for example, pharmacy, chemistry, biotechnology, nuclear technology and other critical processes in processing and process engineering. The fitting of the invention allows in particular the use of extensive inline process analysis in the production process, eg. NIR (near-infrared) and / or MIR (mid-infrared).

Claims

 claims

Fitting for receiving a probe (20), in particular a measuring probe or a sampling probe, with a housing (10) having a space for receiving the probe (20) and a first chamber (30) for receiving a first fluid, which is in communication with or includes the space for receiving the probe (20) and which has a connecting portion (40) by means of which the housing (10) is connectable or in communication with a container (50) for receiving a medium whose property is to be measured with the probe (20) or from which a sample is to be taken, the probe having a particularly substantially cylindrical, elongated shaft which is displaceable relative to the housing in the axial direction, characterized in that in the housing (10) at least one second chamber (60) for receiving a second fluid is provided, between the first chamber (30) and the connecting portion (40) of the housing (10) angeord is net.

Fitting according to claim 1, characterized in that the first chamber (30) has an inlet (32) and a drain (34), by means of which the first fluid into the first chamber (30) introducible and from the first chamber ( 30) is dischargeable.

Fitting according to claim 1 or 2, characterized in that the second

Chamber (60) has an inlet (62) and a drain (64), by means of which the second fluid in the second chamber (60) can be introduced and discharged from the second chamber (60).

Fitting according to claim 3, characterized in that the inlet (62) and / or the outlet (64) of the second chamber (60) are arranged such that they open in a region in the second chamber (60), the facing the first chamber (30).

Fitting according to one of the preceding claims, characterized in that a first seal (70) is provided, which seals the first chamber (30) relative to the second chamber (60), wherein the seal rests against the shaft of the probe.

Fitting according to one of the preceding claims, characterized in that a second seal (72) is provided which seals the second chamber (60) from the environment, in particular with respect to the interior of the container (50), wherein the seal on the Shaft of the probe is applied.

Fitting according to claim 5 or 6, characterized in that the first

Seal (70) and / or the second seal (72) of two sealing elements, preferably of two O-ring seals (73) is constructed, the axially are spaced, and that flushing connections are provided, by means of which the gap between the sealing elements can be rinsed and / or sterilized.

Fitting according to one of the preceding claims, characterized in that the space for receiving the probe (20) is designed such that the probe (20) in the housing (10) recorded state the first chamber (30) and / or the second chamber (60) passes through.

Fitting according to one of the preceding claims, characterized in that a measuring device is provided, by means of which at least one property of the in the second chamber (60) located or flowing out of this second fluid is measurable.

Fitting according to claim 9, characterized in that the measuring device is arranged inside or outside the second chamber (60).

Fitting according to one of the preceding claims, characterized in that the second chamber (60) has an inlet (62) and that a conveying device, in particular a pump (80) is provided, with the inlet (62) of the second chamber (60) is connected and which is designed such that a continuous and / or discontinuous loading of the second chamber (60) takes place with fluid.

Fitting according to one of the preceding claims, characterized in that the first chamber (30) has an inlet (32) and that a conveying device, in particular a pump (90) is provided, with the inlet (32) of the first chamber (30) is connected and which is designed such that a continuous and / or discontinuous loading of the first chamber (30) takes place with fluid.

Fitting according to one of the preceding claims, characterized in that the valve further comprises a drive unit or is in communication with a drive unit, by means of which in the housing (10) inserted probe (20) is movable between different positions.

Fitting according to claim 13, characterized in that the drive unit comprises a piston (110) which is received in a cylinder (120) back and forth movable, wherein the cylinder (120) connections (122) for compressed air or a having other pressure medium.

Fitting according to one of the preceding claims, characterized in that in the housing (10) a probe (20), in particular a sampling probe or a pH probe is received.

Fitting according to claim 15, characterized in that the probe (20) in the

Housing manually or by means of the drive unit in different positions is movable.

Fitting according to claim 16, characterized in that the different

Positions include a first position in which at least a portion of the probe projects into a medium which is received in a container (50), with which the valve communicates, and a second position, in which at least a portion of the probe located in the first chamber (60).

Fitting according to claim 17, characterized in that the region of the probe is a sensor or a sampling device.

Fitting according to one of the preceding claims, characterized in that in the first chamber (30) a rinsing or a calibration solution is added or that the first chamber (30) is flowed through by a rinsing or calibration solution.

Fitting according to one of the preceding claims, characterized in that in the second chamber (60) relative to the in the first chamber (30) recorded and compared to the in the container (50) recorded medium uncritical fluid is added or that the second chamber (60) is flowed through by such a non-critical fluid.

Fitting according to one of the preceding claims, further comprising a third chamber, which connects to the first chamber at the side facing away from the second chamber.

Fitting according to claim 21, characterized in that the third chamber

(60) has an inlet (62) and a drain (64), by means of which a fluid in the third chamber (60) can be introduced and discharged from the third chamber (60).

Fitting according to one of claims 21 to 22, characterized in that a third seal (70) is provided which seals the first chamber (30) relative to the third chamber (60), wherein the seal rests against the shaft of the probe ,

Fitting according to one of the preceding claims, characterized in that a fourth seal (72) is provided which seals the third chamber (60) on its side facing away from the first chamber, wherein the seal rests against the shaft of the probe.

Fitting according to one of claims 21 to 24, wherein the third seal (70) and / or the fourth seal (72) of two sealing elements, preferably of two O-ring seals (73) is constructed, which are axially spaced In addition, flushing connections are provided by means of which the intermediate space between the sealing elements can be rinsed and / or sterilized.

Fitting according to one of the preceding claims, characterized in that a measuring device is provided, by means of which at least one egg property of the third chamber (60) located or flowing out of these second fluid is measurable. Fitting according to one of the preceding claims, characterized in that one or more of the first to fourth seals, the valve are designed as pneumatically controllable or "inflatable" seal, wherein the seal can seal either under pressure and in the relaxed state, ie without pressure , is open, or vice versa.