WO2021204444A1 - Connecting clamp for the mechanical connection of two bioprocess system components - Google Patents

Abstract

Connecting clamp for the mechanical connection of two bioprocess system components (2, 3) axially along a geometrical connecting axis (4), wherein the connecting clamp (1) has a locking body (5) which, in the definitively assembled state, runs radially around the geometrical connecting axis (4) and at least one of the bioprocess system components (2, 3). It is proposed that the connecting clamp (1) should have at least one clamping block (6), which interacts with the locking body (5) and is intended for the clamping connection of the bioprocess system components (2, 3), that the clamping block (6) should be movable, by means of a locking movement, out of an initial state, in which the clamping block (6) releases the bioprocess system components (2, 3), into a stable locking state, in which the clamping block (6) connects the bioprocess system components (2, 3) axially with clamping action, as a result of which the connecting clamp (1) and the bioprocess system components (2, 3) assume the definitively assembled state, and that the locking movement should comprise a movement of the locking body (5) in the axial direction relative to the bioprocess system components (2, 3), this movement causing the clamping block (6) to move out of the initial state into the locking state along with a movement component in the radial direction of the geometrical connecting axis (4).

Description

Connection clamp for the mechanical connection of two bioprocess engineering system components

The invention relates to a connecting clamp for the mechanical connection of two bioprocess engineering system components according to the preamble of claim 1 and a method for connecting two bioprocessing system components by means of such a connecting clamp according to claim 16. This can be an actuator, for example for a one-way valve, and the one-way valve, but also fluid-carrying pipelines and the like. Other bioprocess engineering system components such as filters may also have to be added to the connection. In principle, the bioprocess engineering system components can therefore be any bioprocess engineering system components that are to be connected to one another. In particular, it can be a question of bioprocess engineering system components that are connected using the triclamp technique.

Previous solutions for connecting bioprocess engineering system components, such as the clamping screws known from DIN 28 403, are expensive to manufacture and complex to operate. The invention is based on the problem of designing and developing the known connecting terminals in such a way that the connecting terminal is cheaper to manufacture and / or is easier to operate.

The above problem is solved in a connecting terminal according to the preamble of claim 1 by the features of the characterizing part of claim 1.

It is essential that the connecting terminal has a locking body and a terminal block that interacts with the locking body and that the terminal block can be brought into a stable locking state by means of a locking movement. A locking body is here a structural part that can be manually acted upon with a locking movement, by means of which two bio-process engineering system components are fixed to one another in a form-fitting manner. It was recognized that if the locking movement includes a movement of the locking body in the axial direction relative to the bioprocess engineering system components, a movement of the terminal block with a radial movement component can be caused. In this way, a clamping connection of the bioprocess engineering system components can be established with simple means, which can be established with little expenditure of force, but can only be released again with difficulty by forces acting between the bioprocess engineering system components. Loosening is preferably associated with a higher expenditure of force compared to establishing the connection, so that unintentional loosening can be avoided. In particular, loosening is only possible by means of a tool.

It is assumed that the connecting clamp is designed for the mechanical connection of two bioprocess engineering system components axially along a geometrical connecting axis, the connecting clamp having a locking body which, in the final assembled state of the connecting clamp and the bioprocessing system components, is radially around the geometrical connecting axis and at least one of the bioprocess engineering system components.

In detail, it is proposed that the connecting clamp has at least one clamping block that interacts with the locking body for the clamping connection of the bioprocessing system components, that the clamping block can be brought into a stable locking state by means of a locking movement from an initial state in which the clamping block releases the bioprocessing system components that the terminal block connects the bioprocessing system components axially by clamping, whereby the connecting terminal and the bioprocessing system components assume the final assembled state and that the locking movement comprises a movement of the locking body in the axial direction relative to the bioprocessing system components, which moves the terminal block from the initial state to the locking state caused with a movement component in the radial direction of the geometric connection axis In the embodiment according to claim 2, the connecting clamp has several clamping blocks, whereby stable clamping can be achieved with simple means.

In the embodiment according to claim 3, the connecting terminal has a pretensioning device, by means of which the operability of the connecting terminal can be simplified. According to claim 4, the prestressing device can comprise a prestressing element.

Claim 5 specifies preferred embodiments of the locking body. Claim 6 specifies preferred configurations of a clamping body which, in one configuration, is part of the connecting terminal. A clamping body is a further component here that contributes to the function of the connecting clamp and, in particular, is in direct, clamping contact with the bioprocessing system components. Claims 7 and 8 specify preferred configurations of the arrangement of the individual components of the connecting terminal with respect to one another.

According to claim 9, the components of the connecting clamp can be assembled around a first of the bioprocess engineering system components. This makes it possible, for example, to deliver the connecting clamp as a pre-assembly component together with the bioprocess engineering system component.

Claim 10 describes preferred embodiments of the locking movement and the locking state. These are designed to establish a stable connection between the bioprocess engineering system components by means of a locking movement that is as simple as possible.

According to claim 11, the movement of the terminal block caused by the locking body can take place at least partially against the bias of the terminal block. In particular in combination with the further preferred optional configurations according to claim 11, an easily manageable construction of the connecting terminal can thus be made possible. In the preferred embodiment according to claim 12, the locking body secures the locking state, whereby in particular an undesired opening of the connecting terminal can be prevented. Claim 13 specifies embodiments of how the terminal block can be connected to the locking body.

Claims 14 and 15 indicate preferred configurations which make it possible to connect the connecting terminal to the bioprocess engineering system components as simply as possible.

According to a further teaching, which is of independent importance, a method for connecting two bioprocess engineering system components by means of a connecting clamp according to the proposal is claimed. Reference may be made to all statements relating to the proposed connecting terminal.

In the following, the invention is explained in more detail with the aid of a drawing which merely shows exemplary embodiments. In the drawing shows

1 shows a first embodiment of the proposed connecting clamp in a) assembled state and b) not assembled, FIG. 2 shows the process of connecting two bioprocess engineering system components by means of the connecting clamp of the first exemplary embodiment,

3 shows a second embodiment of the proposed connecting terminal in a) assembled state and b) not assembled state,

4 shows the process of connecting the connecting clamp of the second exemplary embodiment to a first bioprocess engineering system component, and FIG FIG. 5 shows the process of connecting the connecting clamp connected to the first bioprocessing system component according to FIG. 4 to a second bioprocessing system component.

The figures show two embodiments of the proposed connecting terminal 1. 1 and 2 show the first embodiment and FIGS. 3 to 5 show the second embodiment. 1b) and 3b) show the respective embodiment of the connecting terminal 1 in a non-assembled state. Unless explicitly stated otherwise, however, the following statements always relate to the connecting terminal 1 as such, that is to say in the assembled state.

The connecting clamp 1 is used for the mechanical connection of two bioprocessing system components 2, 3 axially along a geometric connection axis 4. The bioprocessing system components 2, 3 are here and preferably a valve 2, in particular a one-way valve, and a motor 3 for controlling the Valve 2. The two bioprocess engineering system components 2, 3 are here and preferably not in fluid communication with one another. However, the bioprocess engineering system components 2, 3 can also be in fluid communication with one another just as advantageously. Here, and preferably, it is a connection based on the triclamp technique.

The connecting clamp 1 has a locking body 5 which, in the final assembled state of the connecting clamp 1 and the bioprocessing system components 2, 3, runs radially around the geometrical connecting axis 4 and at least one of the bioprocessing system components 2, 3. The terms “radial” and “axial” always relate to the geometric connecting axis 4.

The connecting clamp 1 has at least one clamping block 6 interacting with the locking body 5 for the clamping connection of the bioprocess engineering system components 2, 3. The clamping connection can meet different requirements. If the bioprocessing system components 2, 3 are a valve 2 and a motor 3, here is and preferably provided that the connecting terminal 1 can hold the actuating forces of the motor 3. This is here and preferably at least 10 Newtons. If the connection is a fluid-technical connection, the clamping connection is designed in such a way that it also meets the requirements there, in particular for a tightness of the connection.

According to the proposal, the terminal block 6 can be brought from an initial state, in which the terminal block 6 releases the bioprocess engineering system components 2, 3, into a stable locking state, in which the terminal block 6 connects the bioprocess engineering system components 2, 3 in an axially clamping manner by means of a locking movement, whereby the connecting terminal 1 and the bioprocess engineering system components 2, 3 assume the final assembled state. The locking movement is shown in FIGS. 2 and 5 for the two embodiments. The locking state is so stable that it does not come loose on its own. This minimizes the risk of unintentional loosening of the connection. In particular, loosening is only possible by means of a tool. The final assembled state relates to the intended use of the connecting clamp 1 for the mechanical connection of the two bioprocess engineering system components 2, 3.

The locking movement comprises a movement of the locking body 5 in the axial direction relative to the bioprocess engineering system components 2, 3, which causes a movement of the terminal block 6 from the initial state into the locking state. This movement of the terminal block 6 has a movement component in the radial direction of the geometric connecting axis 4. In particular, the locking movement is only a movement in the axial direction of the locking body 5. The movement of the clamping block 6 is in particular a pivoting movement or a linear movement.

For the first embodiment, the locking movement is shown enlarged in detail in FIG. The connecting terminal 1 can have further components to be explained, which, however, can be left out for the explanation of the locking movement. As shown in FIG. 2, the two bioprocess engineering system components 2, 3 are here and preferably first brought into the state that they later assume should. The locking movement of the locking body 5 is then carried out in the axial direction. This locking body 5 comes into engagement with the clamping block 6, in particular previously spaced apart, whereby the latter is pivoted in the radial direction. As will be explained, the locking body 5 here and preferably reaches a position in which it then locks the clamping block 6 against undesired pivoting back. The clamping block 6 then directly or indirectly clamps the two bioprocess engineering system components 2, 3 against one another. It is conceivable that a filter or the like is also located between these two bioprocess engineering system components 2, 3, as a result of which they are not in direct contact. However, there can also be direct contact between the two bioprocess engineering system components 2, 3.

The locking movement of the second embodiment shown in Fig. 5 has a similar function. There, however, the terminal block 6 is mounted directly on the locking body 5, which also corresponds to a preferred embodiment. As a result, too, the axial movement of the locking body 5 is transmitted to the clamping block 6, which is pivoted radially and holds the bioprocess engineering system components 2, 3 in a clamping manner. Here, too, the locking body 5 can lock the terminal block 6 against undesired pivoting back. This will also be explained in more detail.

The connecting terminal 1 can have a plurality of terminal blocks 6, preferably at least or precisely four terminal blocks 6, more preferably at least or precisely six terminal blocks 6. The terminal blocks 6 can be distributed radially around the geometrical connecting axis 4 in the final assembled state and preferably also in the assembled state. All statements relating to a terminal block 6 can apply accordingly to the other terminal blocks 6. Here and preferably, the terminal blocks 6 are each configured identically.

The connecting terminal 1 can have at least one pretensioning device 7 for pretensioning the respective terminal block 6 in the direction of the initial state. Here and preferably, the radial movement of the clamping block 6 caused by the axial movement of the locking body 5 takes place against the prestressing of the clamping block 6. The prestressing device 7 is here and preferably designed in such a way that the connection of the bioprocess engineering system components 2, 3 is simplified. In the final assembled state, it no longer has to have any functions and can then be destroyed.

The pretensioning device 7 here and preferably comprises a pretensioning element 8. This is set up in particular to pretension all of the clamping blocks 6. As shown in the figures, the prestressing element 8 can be ring-shaped and / or consist of a rubber material. It can be a clamping ring, preferably a preformed clamping ring, which in particular has a corner for each clamping block 6, via which the clamping ring is connected to the clamping block 6. A preformed clamping ring is a clamping ring that does not have a round shape, but is in particular already adapted to the number of clamping blocks 6, that is, for example, has a square or hexagonal shape. The prestressing element 8 is here and preferably only connected to the respective clamping blocks 6 and otherwise to no other component.

As already mentioned, the prestressing element 8 is preferably only relevant before the final assembly of the connecting terminal 1. It can even be provided that the pretensioning element 8 is set up to be destroyed by the locking movement. It can also be provided that the pretensioning device 7 comprises one or more film hinges. Via these, the terminal blocks 6 can be connected to the locking body 5, to one another and / or to a terminal body 9 that is yet to be explained. In principle, it is conceivable that the prestressing device 7 has exactly one prestressing element 8 or several prestressing elements 8, in particular one per clamping block 6.

The locking body 5 can be ring-shaped or sleeve-shaped and here and preferably additionally or alternatively form a receptacle for the bioprocess engineering system components 2, 3. In the exemplary embodiments, the receptacle is formed by the cavity in the center of the locking body 5. Here and preferably, the locking body 5 also surrounds one or both of the bioprocess engineering system components 2, 3 radially in the final assembled state. Here and preferably, the locking body 5 can be moved axially with respect to the bioprocess engineering system components 2, 3 and / or some or all of the other components of the connecting terminal 1. This axial movability is preferably limited, in particular via a stop. Here and preferably, the axial mobility is essentially limited to the locking movement.

The connecting clamp 1 can have a clamp body 9, in particular an annular or sleeve-shaped clamp body. This clamping body 9 is shown in FIGS. 1 and 2, which are assigned to the first exemplary embodiment. Here and preferably, the respective clamping block 6 is connected to the clamping body 9, in particular pivotably and / or directly. As can be seen clearly in FIG. 1, the clamping body 9 can have several separate circumferential segments 10. Here and preferably, the clamping body 9 has two separate circumferential segments 10. The circumferential segments 10 of the clamping body 9 are held relative to one another here and preferably by means of the locking body 5, here via the clamping blocks 6. The circumferential segments 10 can each carry at least one clamping block 6, in particular at least two clamping blocks 6 each. Here, and preferably, the clamping body 9 in the finally assembled state is in contact with an inner side, in particular only one of the bioprocess engineering system components 2, 3.

Here and preferably, the terminal block 6 is arranged radially outside of the terminal body 9. In particular, all of the terminal blocks 6 are arranged radially outside of the terminal body 9. The locking body 5 is arranged here and preferably radially outside the clamping body 9 and / or the clamping block 6, in particular all the clamping blocks 6.

As shown in FIG. 1, the locking body 5 can be in direct contact with the respective terminal block 6 and / or the clamping body 9, in particular all circumferential segments 10 of the clamping body 9. The locking body 5 is preferably not connected to the clamping body 9 in a materially or form-fitting manner. It can be provided that the locking body 5 is in play-prone contact with the terminal block 6, in particular all the terminal blocks 6, and / or the clamping body 9 or that there is no play and the locking body 5 with the terminal block 6, in particular all the terminal blocks 6, and / or the clamping body 9 is continuously in frictional contact, whereby the axial mobility of the locking body 5, however, remains unaffected. The clamping body 9 has here and preferably a receptacle 11 for the respective clamping block 6. The respective terminal block 6 is preferably mounted pivotably in the receptacle 11. For this purpose, the terminal block 6 can have bearing pins 12 which are pivotably received in a bearing opening of the clamping body 9. Here and preferably the bearing opening is part of the receptacle 11.

It is already clear here that the proposed connecting terminal 1 can be assembled by means of simple mechanical components. Here and preferably, the locking body 5, the clamping body 9 and / or the clamping blocks 6 consist of a plastic material and are preferably injection molded parts. The entire connecting clamp 1 can be a disposable or reusable component, which can in particular be delivered together with a disposable bioprocess engineering system component 2, 3.

Appropriately, it can be provided that the components of the connecting clamp 1 can be assembled around a first of the bioprocessing system components 2 and that the second bioprocessing system component 3 can be axially inserted into the receptacle formed by the assembled connecting clamp 1. This is shown in the transition from FIG. 1 to FIG. 2. After the introduction of the second bioprocessing system component 3, the locking movement can then be carried out. This can be done here, for example, by placing the valve 2 with the connecting terminal 1 on a motor 3 standing for mounting on a surface and pulling the locking body 5 downwards. Thus, in a simple embodiment, only a single handle can be necessary to connect the two bioprocess engineering system components 2, 3. This is of course not to be understood in a restrictive manner, the connecting terminal 1 could also be attached to the motor 3 for assembly or the valve could be placed on a surface.

Here and preferably, the connecting clamp 1, here the first embodiment, cannot be separated from the bioprocess engineering system component 2 in the assembled state in a non-destructive manner. This closes does not mean that the connecting terminal 1 can be dismantled by dismantling it into its individual components.

The locking movement can be a movement of the locking body 5 relative to the clamping body 9 and / or the clamping block 6, in particular all the clamping blocks 6. The locking movement preferably causes the respective clamping block 6 to pivot relative to the clamping body 9, by means of which the clamping body 9 connects the bioprocess engineering system components 2, 3 with one another in a clamping manner.

In principle, the respective terminal block 6 can hold the bioprocess engineering system components 2, 3 both in direct contact with them. Additionally or alternatively, the respective clamping block 6 can clamp the bioprocess engineering system components 2, 3 in the locked state against the clamping body 9, as shown in FIG. 2. Here and preferably, the locking body 5 comes into engagement with the respective terminal block 6 during the locking movement. The movement of the terminal block 6 caused by the locking body 5 can take place at least partially against the bias of the terminal block 6.

Furthermore, as implemented in both embodiments, the prestressing of the clamping block 6 can counteract the locking movement only on a first section of the locking movement. At the beginning of a second section of the locking movement, a dead center of the interaction between the terminal block 6 and the locking body 5 can be reached, so that on the second section of the locking movement the prestress of the terminal block 6 no longer counteracts the locking movement. As shown in FIG. 2, the dead center is reached shortly before reaching the position in the last enlarged section. The second section is very short. While in the previous enlarged sections the clamping block 6 could move the locking body 5 upwards again due to the bias, this is no longer the case in the last enlarged section.

Accordingly, the prestressing of the respective terminal block 6 is preferably supported by the locking body 5. Around the respective terminal block 6 To open again, the locking body 5 would first have to be moved upwards again. This translation between the pivoting movement, which is introduced into the structure of the locking body 5, but is not able to move it, makes it possible to absorb relatively large forces via the clamping connection. In the second embodiment, the dead center is realized differently, since there the friction between the terminal block 6 and the bioprocess engineering system components 2, 3 in cooperation with the locking body 5 is of great importance. Without the bioprocessing system components 2, 3, the terminal block 6 would be reset there by the prestress to its initial state.

The locking state of the respective terminal block 6 is secured here and preferably by the locking body 5 in such a way that an axial movement of the locking body 5 has to take place in order to enable the clamping connection of the bioprocess engineering system components 2, 3 to be released from the final assembled state.

In particular with a view to FIGS. 3 to 5 and the second embodiment, it can be provided that the respective terminal block 6 is connected to the locking body 5, in particular pivotably, preferably via a clip connection. The respective terminal block 6 can be arranged radially inside the locking body 5. Additionally or alternatively, the respective terminal block 6 can have a receptacle 13 into which a counter-receptacle element 14 of the locking body 5 engages in a force-locking manner. Here, and preferably, the clamping block 6 can be pivoted about the counter-receiving element 14. However, this clip connection can also be replaced using the film hinge mentioned. In addition, it should be noted in principle that the clamping blocks 6 and the locking body 5 can also be a single component without being separable from one another. The same applies to all other components of connecting terminal 1.

Looking at FIGS. 3 to 5 together, it can now be seen that the respective terminal block 6 can be prestressed in a first position before assembly. The assembly refers to the assembly with the bioprocess engineering system components 2, 3, which is carried out here and preferably before the locking movement. Before assembly is the connecting clamp 1 has therefore not yet been brought together with the bioprocess engineering system components 2, 3. This first position can be seen in Fig. 3a). From the first position, the respective terminal block 6 can be brought into a second position against its pretension before assembly. This second position is shown in FIG. 4, the first bioprocess engineering system component 2 having already been introduced into the receptacle formed by the connecting clamp 1.

The second position can preferably be reached by pressing the connecting terminal 1 as such axially against a surface. For this purpose, in FIG. 4 the connecting clamp 1 is pressed downwards against the indicated surface 15, as a result of which the bioprocess engineering system component 2 can be introduced from above. The bioprocess engineering system components 2, 3 can be introduced into the connecting clamp 1 here and preferably separately, in particular from different sides. This is implemented here and preferably in such a way that a bioprocess engineering system component 2 to be introduced first into the connecting terminal 1 cannot be introduced when the terminal block 6 is in the first position and that the bioprocessing system component 2 to be introduced first into the connecting terminal 1 when the terminal block 6 is in the second position is insertable. For this purpose, reference is also made to the illustration in FIG. 4.

If the connecting terminal 1 is then removed from the surface 15, the state in FIG. 5 on the left is reached. The second bioprocess engineering system component 3 to be introduced into the connecting terminal 1 can then preferably be introduced when the terminal block 6 is in the first position. Here, and preferably, the terminal block 6 was thus temporarily transferred into the second position against its pretension and then in particular again assumed the first position. The terminal block 6 can then be brought into the locking state by means of the locking movement when the bioprocess engineering system components 2, 3 have been introduced. For this purpose, the locking body 5 is here, and preferably again, moved downwards with just one movement.

Here and preferably lies the first position with respect to a pivot axis of the clamping block 6, which is here and preferably from the counter-receiving element ment 14 is defined on one side of the pivot axis and the second position on the other side.

According to a further teaching, which is of independent importance, a method for connecting two bioprocess engineering system components 2, 3 by means of a connection terminal 1 according to the proposal is proposed. The connecting clamp 1 is connected to two bioprocess engineering system components 2, 3 according to the method, the connecting clamp 1 being brought into the locking state by means of the locking movement and thus the connecting clamp 1 and the bioprocessing system components 2, 3 being brought into the final assembled state. Reference may be made to all statements relating to the proposed connecting terminal 1.

Claims

Claims

1. Connection clamp for the mechanical connection of two bioprocess technology system components (2, 3) axially along a geometric connection axis (4), the connection clamp (1) having a locking body (5), which in the final assembled state of the connection clamp (1) and the bioprocess technology system components (2, 3) runs radially around the geometric connecting axis (4) and at least one of the bioprocessing system components (2, 3), characterized in that the connecting clamp (1) has at least one clamping block ( 6) for the clamping connection of the bioprocess engineering system components (2, 3) has that the clamping block (6) can be brought into a stable locking state by means of a locking movement from an initial state in which the clamping block (6) releases the bioprocessing system components (2, 3) is, in which the terminal block (6) the bioprocess engineering system components (2, 3) connects axially clamping, whereby the connecting clamp (1) and the bioprocess engineering system components (2, 3) assume the final assembled state and that the locking movement includes a movement of the locking body (5) in the axial direction relative to the bioprocess engineering system components (2, 3) which causes a movement of the terminal block (6) from the initial state into the locking state with a movement component in the radial direction of the geometric connecting axis (4).

2. Connection terminal according to claim 1, characterized in that the connection terminal (1) has several terminal blocks (6), preferably at least or exactly four terminal blocks (6), further preferably at least or exactly six terminal blocks (6), which in the final assembled state radially are distributed around the geometric connection axis (4).

3. Connecting terminal according to claim 1 or 2, characterized in that the connecting terminal (1) has at least one prestressing device (7) for prestressing the respective terminal block (6) in the direction of the initial state preferably that the radial movement of the respective terminal block (6) caused by the axial movement of the locking body (5) takes place against the bias of the respective terminal block (6).

4. Connecting terminal according to claim 3, characterized in that the prestressing device (7) comprises a prestressing element (8) which is particularly designed to prestress all the clamping blocks (6), preferably that the prestressing element (8) is ring-shaped and / or consists of one Consists of rubber material and / or is a clamping ring, preferably a preformed clamping ring, which has a corner in particular for each clamping block (6), and / or that the pretensioning element (8) is set up to be destroyed by the locking movement, and / or that the pretensioning device (7) comprises one or more film hinges.

5. Connecting clamp according to one of the preceding claims, characterized in that the locking body (5) is ring-shaped or sleeve-shaped, and / or that the locking body (5) forms a receptacle for the bioprocess engineering system components (2, 3) and preferably at least one, preferably radially surrounds both of the bioprocess engineering system components (2, 3) in the final assembled state.

6. Connecting terminal according to one of the preceding claims, characterized in that the connecting terminal (1) has a, in particular annular or sleeve-shaped, clamping body (9) that the respective terminal block (6) with the clamping body (9), in particular pivotable and / or directly, is connected, preferably that the clamping body (9) has several separate circumferential segments (10), more preferably that the circumferential segments (10) of the clamping body (9) are held relative to one another by means of the locking body (5) and / or the circumferential segments (10) each carry at least one terminal block (6), in particular at least two terminal blocks (6) each.

7. Connecting terminal according to claim 6, characterized in that the respective terminal block (6) is arranged radially outside the clamping body (9), and / or that the locking body (5) radially outside of the clamping body (9) and / or the terminal block ( 6) is arranged, and / or that the The locking body (5) is in direct contact with the terminal block (6) and / or the clamping body (9), in particular all peripheral segments (10) of the clamping body (9), preferably that the locking body (5) with the clamping body (9) is not cohesively and not positively connected.

8. Connecting terminal according to claim 6 or 7, characterized in that the clamping body (9) has a receptacle (11) for the respective terminal block (6), preferably that the terminal block (6) is pivotable in the receptacle

(11) is mounted, more preferably that the terminal block (6) bearing mandrels

(12) which are pivotally received in a bearing opening of the clamping body (9).

9. Connecting clamp according to one of claims 5 to 8, characterized in that the components of the connecting clamp (1) can be assembled around a first of the bioprocessing system components (2) and that the second bioprocessing system component (3) is inserted into the connecting clamp ( 1) formed receptacle can be inserted axially.

10. Connecting terminal according to one of the preceding claims, characterized in that the locking movement is a movement of the locking body (5) relative to the clamping body (9) and / or the terminal block (6), which is preferably a pivoting of the respective terminal block (6) relative caused to the clamping body (9), through which the clamping body (9) connects the bioprocessing system components (2, 3) with each other in a clamping manner, and / or that the respective clamping block (6) the bioprocessing system components (2, 3) in the locked state against the The clamping body (9) jams and / or that the locking body (5) comes into engagement with the respective clamping block (6) during the locking movement.

11. Connecting terminal according to one of claims 3 to 10, characterized in that the movement of the terminal block (6) caused by the locking body (5) takes place at least partially against the prestress of the terminal block (6), preferably that the prestress of the terminal block (6) ) the locking movement on a first section of the locking movement counteracts and that at the beginning of a second section of the locking movement a dead center of the interaction between the terminal block (6) and the locking body (5) is reached, so that the bias of the terminal block (6) no longer counteracts the locking movement on the second section of the locking movement.

12. Connecting terminal according to one of the preceding claims, characterized in that the locking state of the respective terminal block (6) is secured by the locking body (5) in such a way that an axial movement of the locking body (5) must take place in order to break the clamping connection To enable bioprocess engineering system components (2, 3) from the final assembled state.

13. Connecting terminal according to one of the preceding claims, characterized in that the respective terminal block (6) is connected to the locking body (5), in particular pivotably, preferably via a clip connection, preferably that the respective terminal block (6) is radially inside of the locking body (5) is arranged, and / or that the respective terminal block (6) has a receptacle (13) into which a counter-receptacle element (14) of the locking body (5) engages in a force-locking manner, preferably that the terminal block (6 ) is pivotable about the counter-receiving element (14).

14. Connecting clamp according to one of the preceding claims, characterized in that the respective terminal block (6) is biased into a first position prior to assembly, that the terminal block (6) prior to assembly from the first position against its bias into a second position can be brought, preferably in that the connecting clamp (1) as such is pressed axially against a surface (15) so that the bioprocess engineering system components (2, 3) can be introduced into the connecting clamp (1) separately, in particular from different sides, in such a way that that a bioprocess engineering system component (2) to be introduced first into the connecting clamp (1) cannot be introduced when the terminal block (6) is in the first position; Terminal block (6) can be inserted that is the second to be inserted into the connecting terminal (1) rende bioprocess engineering system component (3) at in The terminal block (6) located in the first position can be inserted and that the terminal block (6) can be brought into the locking state by means of the locking movement when the bioprocess engineering system components (2, 3) are inserted.

15. Connecting clamp according to claim 14, characterized in that the first position with respect to a pivot axis of the clamping block (6) lies on one side of the pivot axis and the second position on the other side, and / or that the pivot axis is through the counter-receiving element (14) is defined.

16. A method for connecting two bioprocess engineering system components (2, 3) by means of a connecting terminal (1) according to one of the preceding claims, wherein the connecting terminal (1) is connected to two bioprocessing system components (2, 3), the connecting terminal ( 1) is brought into the locked state by means of the locking movement and the connecting terminal (1) and the bioprocess engineering system components (2, 3) are brought into the final assembled state.