WO2021063447A1 - Tube valve for beverage machines - Google Patents

Abstract

The invention relates to a tube valve, in particular for beverage machines, comprising a squeeze element (2) which can be manually moved from an open position into a closed position in order to close a tube (100) by squeezing same and comprising a locking device (3) for locking the squeezing element (2) in the closed position, wherein the locking device (3) has a motor drive (4) for unlocking the squeeze element (2).

Description

Hose valve for drinks machines

The invention relates to a tube valve, in particular for beverage dispensers, with a squeezing element that can be manually moved from an open to a closed position for closing a tube by means of squeezing and a locking device for locking the squeezing element in the closed position. The invention also relates to a method for closing and opening a hose with a hose valve. Another object of the invention is a drinks machine with a hose valve.

Hose valves are used in various fields of technology and are used to control the flow of fluid through a hose this is closed and opened by means of the hose valve. The closing and opening of the hose takes place in known Schlauchven valves by means of a movable squeezing element, which squeezes the elastic tube in its closed position and releases it in its open position.

WO 2011/095299 discloses such a manually operable hose valve, in which a pinch element designed as a clamping bolt can be moved back and forth between an open and a closed position via a thread. The advantage of such hose valves is that when the hose is squeezed, the squeezing element remains in its closed position due to the self-locking of the thread and can only be moved again by renewed manual rotation. A disadvantage of these valves, however, is that the rotary actuation only allows the hose to be opened and closed slowly, which can be undesirable for certain applications.

In addition, hose valves are known in which the hose is squeezed by manual displacement of the squeezing element, which enables the hose to be opened and closed quickly. Since the squeezing element is displaced against the elasticity of the hose and against the pressure of the medium flowing in the hose, the squeezing element in the closed position tends to move automatically into the open position. For this reason, such hose valves with displaceable squeezing elements often have a locking device. The locking device locks the squeezing element in its closed position, so that the squeezing element is held in the closed position and the hose remains closed regardless of its inherent elasticity and regardless of the pressure of the medium applied. While hose valves with a manually movable Quetschele element have proven themselves for a variety of applications, there are also applications in which manual actuation of the hose valve by a user is not possible.

EP 2 099 341 B1 and WO 2005/031198 A1 disclose hose valves which enable the automatic opening and closing of hoses by means of electrical movement of the squeezing elements. The advantage of such hose valves is that, due to their automatic actuation, actuation by a user is not necessary. The disadvantage of such hose valves, however, is that relatively large squeezing forces must be applied via the drive, in particular for squeezing the tube, since the tube is squeezed against its inherent elasticity and against the pressure of the medium, which is why the squeeze is correspondingly energy-consuming.

The invention is therefore based on the aim of creating a hose valve which can be operated in a user-friendly manner with little expenditure of energy.

In the case of a hose valve of the type mentioned at the outset, this object is achieved in that the locking device has a motor drive for unlocking the squeezing element. The combination of a manually movable squeezing element with a motor drive for unlocking the squeezing element results in a semi-automatic hose valve. The valve can be closed by manual movement without additional energy. The valve can be opened in a user-friendly manner using the motorized drive. By means of the motorized drive of the hose valve, the squeezing element, which is locked in the closed position, can be nig electrical energy expenditure can be unlocked. The subsequent movement of the squeezing element from the closed position into the open position can take place without additional energy via the elasticity of the hose and the pressure of the adjacent medium. The process can be supported by an additional spring. The advantage of this semi-automatic hose valve is that opening the hose, which requires little energy, can take place automatically, i.e. without manual actuation by a user, and closing the hose manually, which is much more energy-intensive, and thus without additional energy, in particular electrical energy. For this reason, such hose valves are also suitable for battery operation, for example.

As an advantageous further development of the invention, it can be provided that the locking device has a locking element that can be moved between an unlocking and a locking position for locking the squeezing element in its closed position. By means of the locking element, the squeezing element can be locked in the closed position in a structurally simple manner. The locking element can be moved linearly, that is to say along an axis, or rotationally, that is to say in a circular movement. If the squeezing element is in the closed position, the locking element can be moved into its locking position, whereby the squeezing element is locked in a form-fitting manner. To unlock the squeezing element, the locking element can be moved into the unlocking position so that the squeezing element can be moved again.

In this context, it is particularly advantageous if the direction of movement of the locking element runs transversely to the direction of movement of the squeezing element. Due to the directions of movement running transversely to one another, the squeezing element can be locked in the closed position in a structurally simple manner by means of the locking element. The The direction of movement of the locking element is the direction in which the locking element can be moved back and forth between the unlocking and locking positions, in particular linearly. The direction of movement of the squeezing element is correspondingly the direction in which the squeezing element can be moved back and forth from the open to the closed position, in particular linear. In a particularly advantageous manner, the direction of movement of the locking element runs perpendicular to the direction of movement of the squeezing element. Alternatively, however, it is also conceivable for the directions of movement to run transversely to one another at a different angle, through a corresponding arrangement of the locking element and the squeezing element to one another.

It has also been found to be advantageous if the motor drive is designed as an electric motor drive. Electric motor drives are available inexpensively in many designs, so that standard solutions can be used and the drive can be selected according to the requirements for the hose valve. The electric motor drive, in particular an electric motor, can be operated by means of electrical energy and can convert this into a movement accordingly. For example, it is conceivable that the electromotive drive executes a rotary movement when it is supplied with power. Alternatively, however, it is also possible to provide an electromotive drive which, when energized, executes a linear movement. In a particularly advantageous manner, the locking device has an energy store, in particular a battery and / or a rechargeable battery, for supplying energy to the motor drive. The energy store can provide the energy required to operate the motor drive, so that there is no need to connect the hose valve to the power grid. In a particularly advantageous manner, the energy store can be exchangeable and / or rechargeable. To the sta- tus of the energy store, in particular the remaining energy present, the energy store can optionally have a display, in particular a display and / or a lamp, such as an LED.

It has also been found to be advantageous if the locking device for coupling the motor drive to the locking element has a gear via which a rotary movement originating from the drive can be converted into a linear movement of the locking element. The gearbox couples the motor drive with the locking element. The movement of the motor drive, in particular the rotary movement, can be converted into the movement of the locking element, in particular its linear movement, by means of the transmission. The result is that the locking element can be moved back and forth between the unlocking and locking positions by means of the motorized drive via the transmission.

In this context, it is particularly advantageous if the transmission has a drive-side transmission element and a locking-side Ge transmission element. The gear elements can be used in a constructive way to convert the rotary movement into the linear movement. It is conceivable to design the transmission as a gear transmission, curve transmission, screw transmission or traction mechanism. It is also possible to provide a step-up or step-down ratio for the transmission.

It has also proven to be particularly advantageous in this context if one of the gear elements is designed as a cam and one of the gear elements is designed as a driver that can be moved over the cam. The drive-side, in the manner of a course Gear element formed by a disk can be connected to the motorized drive so that the cam also rotates when the drive is rotated. The locking-side gear element, designed as a driver for this case, can be guided over a control curve of the cam disk when the cam disk is rotated so that the driver can perform the linear movement. Accordingly, the locking element connected to the driver can also perform the linear movement. It can also be advantageous if one of the transmission elements can be actuated manually. This makes it possible that the locking element can be moved manually not only via the motor drive, but also manually by means of one of the gear elements, whereby the functional reliability of the hose valve can be increased, for example when no electrical energy is available. Provision can be made for the locking element to be moved back and forth between the unlocking and locking positions by manual actuation of one of the gear elements, whereby the squeezing element can also be locked and unlocked manually. In addition to automatic opening and manual closing, for example in emergency situations, the hose valve can also be operated completely manually. In this context, it has proven to be particularly advantageous to design the drive-side gear element so that it can be operated manually. Alternatively, however, it is also conceivable for the locking-side gear element to be designed so that it can be operated manually.

In a particularly advantageous manner, the squeezing element can be moved from the open to the closed position against the force of a tensioning return spring. This can further increase the functional reliability of the hose valve, since the return spring can support the opening process of the hose. In the closed position, the squeezing element can by means of the Locking element be locked, the return spring is tensioned accordingly. If the squeezing element is subsequently unlocked, the tensioned return spring can move the squeezing element from the closed position into the open position, in particular move it linearly. The movement is independent of the inherent elasticity of the hose or the pressure of the medium, which can vary depending on the application.

The locking element can advantageously be moved from the locking position into the unlocking position against the force of a tensioning return spring. This return spring can be tensioned when the locking element moves from the locking to the unlocking position, for example by the motor drive. The unlocked squeezing element can be moved into the open position. If the squeezing element is then manually moved back into the closed position, the locking element can automatically lock the squeezing element in the manner of a snap connection due to the pretensioned second return spring. For this purpose, the return spring can also be designed as a compression or tension spring. Furthermore, it has been found to be advantageous if the hose valve has a housing for the arrangement of the locking device of the drive element and the pinch element. The housing can accommodate the locking device, the drive and the squeezing element in a structurally simple manner. It is conceivable to arrange the locking device and the drive in a line next to the squeezing element in order to achieve a particularly compact design. In addition, the housing can protect the locking device, the drive and the squeezing element from external influences, in particular from moisture or dust. In this context, it is particularly advantageous if the Verriege treatment device, in particular the locking element, the gear and the drive in a first housing part of the housing and the Quetschele element are arranged in a second housing part of the housing. The first housing part can accommodate the locking element, the gearbox and the drive. The first housing part can be designed in such a way that the transmission and the drive are arranged in a line or in a row. The second housing part can accommodate the squeezing element. It is possible that the first housing part guides the movement of the locking element and / or the second housing part guides the movement of the squeezing element. It is particularly advantageous if the housing parts can be connected to one another, for example by screwing, locking, gluing and / or magnetic connection. With regard to the design, it is also possible to design the housing parts in one piece. In order to facilitate assembly, the housing parts can also be designed symmetrically.

The housing further advantageously has a hose receptacle for receiving the hose. The hose receptacle can be designed as a through hole through which the hose can be inserted. It is possible for the hose receptacle to be arranged in the second housing part, so that the hose is arranged in such a way that the squeezing element can squeeze it accordingly.

In a particularly advantageous manner, the housing has a detachable cover for exchanging the hose. The cover can be connected to the housing in such a way that the hose is received by the housing and the cover. To replace the hose, the cover can be removed from the housing. In particular, it is possible for the cover to be connected to the second housing part. The second housing part can possibly have the hose receptacle, for example in the form of a groove, so that the hose can be inserted into the hose receptacle. The cover is then connected to the second housing part, see above that the hose is received by the housing and the cover. It has been found to be particularly advantageous in this context to configure the hose holder as a groove in such a way that hoses of different diameters can be received by the hose holder. It is also possible to arrange the hose holder in the cover. It can be advantageous here that the cover can remain on the hose while the rest of the housing, in particular the first and second housing parts, is detached from it, for example for maintenance purposes.

In addition, a drinks machine with a hose valve with one or more of the features described above is also proposed to achieve the above-mentioned object. The advantages explained above in connection with the hose valve result.

Furthermore, a method for opening and closing a hose is proposed in order to achieve the above-mentioned object, in which a hose valve with one or more of the features described above is used. The advantages explained in connection with the hose valve result.

With regard to the method, it has been found to be advantageous that the hose valve is closed manually to close the hose and automatically opened to open the hose.

Further details and advantages of hose valves according to the invention, drinks vending machines equipped with such hose valves and methods according to the invention are explained below with the aid of exemplary embodiments with the aid of the accompanying figures. They show: 1 shows a first embodiment of a hose valve according to the invention in the closed state,

Fig. 2 and 3 the hose valve in each case a sectional view along the axis A-A in Fig. 1 in the open and ge closed state,

4 and 5 the hose valve in each case a sectional view along the axis B-B in Fig. 1 in the open and closed state,

Fig. 6 to 10 the processes during the actuation of the hose valve each Weil in a sectional view along the axis A-A in Fig. 1,

11 to 15 a) an enlarged detail of the gear each along the axis CC in FIG. 1 during the actuation sequence according to FIGS. 6 to 10, b) an enlarged detail of the locking element each along the axis AA in FIG. 1 during the operating sequence according to FIGS. 6 to 10,

16 shows the hose valve according to FIG. 1 in an exploded view and development

17 shows a second exemplary embodiment of a hose valve according to the invention in an exploded view. 1 shows a first exemplary embodiment of a hose valve 1 according to the invention. Hose valves 1 of this type are used in various areas of technology and are also particularly suitable for use in beverage vending machines, such as cold brew coffee machines. In cold brew coffee machines, the coffee is cold brewed over a period of several hours before the coffee has to be conveyed by means of a hose 100 from a brewing chamber into a storage container. The hose valve 1 is used to control the flow of coffee through the hose 100.

The hose valve 1 is closed manually by hand before the start of a brewing process. Closing the hose 100 does not require any electrical energy. Rather, the energy required for squeezing is applied manually by a user. After the brewing process, which can last several hours and can also end at night, the hose valve 1 can then automatically open the hose 100 via a motor drive 4. No user intervention is necessary here, so that the hose valve 1 can open after a certain time, for example by a timer. The result is a semi-automatic hose valve 1 which can be closed manually and opened automatically.

Due to the structure of the hose valve 1, opening can be carried out in a particularly energy-saving manner, so that an energy store, for example a battery or an accumulator, only rarely has to be exchanged or recharged. The structure and the mode of operation of the hose valve 1 are explained in more detail below.

According to FIG. 1, the hose valve 1 has a squeezing element 2 designed as a pressure piece for squeezing the hose 100 and a locking device 3 for locking the squeezing element 2. The hose 100 is received by the hose valve 1 so that it can be opened and closed accordingly. So that the hose 100 can be squeezed, it consists of an elastic material, such as rubber, silicone or another elastic plastic, for example.

According to the illustration in Fig. 1, the hose valve 1 is in a closed state, i. H. the hose 100 is squeezed and closed accordingly. The squeezing element 2 is in the closed position and is locked by means of the locking device 3 so that it cannot be moved back by the inherent elasticity of the hose 100 or the pressure of the medium flowing through the hose 100.

Furthermore, the hose valve 1 according to FIG. 1 has a housing 9. The housing 9 is designed in two parts and has a first housing part 9.1 receiving the locking device 3 and a second housing part 9.2 receiving the squeezing element 2, which are connected by means of a housing connection 9.3. The housing connection 9.3 is designed as a clamp connection, other types of connection, such as a plug connection, an adhesive connection or a screw connection, are also possible.

In addition to the arrangement of the squeezing element 2 and the locking device 3, the housing 9 is used to protect against external influences. In particular in the field of food, such as, for example, brewing coffee, it is important that the hose valve 1 can be cleaned easily and is protected from external influences such as liquid and dust. The housing 9 can preferably consist of plastic, but it is also possible to choose a different material. The second housing part 9.2 also has a hose receptacle 10 for receiving the hose 100. The hose holder 10 is in the Execution example designed as a through hole, so that the hose 100 is passed through this, for example by being pushed axially through it. Alternatively, it would also be possible to design the hose receptacle 10 as a groove open on one side and to close it with a cover 9.4 after the hose 100 has been picked up, as will be discussed below in connection with FIG.

The second housing part 9.2 of the hose valve 1 is symmetrically out staltet. The symmetrical design enables, in particular, a simplified assembly, since the first housing part 9.1 can be arranged on the second housing part 9.2 on the right-hand side as well as on the left-hand side in the illustration. In this context, it is possible to adjust the arrangement of the first housing part 9.1 on the second housing part 9.2 according to the available space.

In FIGS. 2 and 3, the hose valve is in the open and closed state in a sectional view along the axis AA Darge, see FIG. 1. Fig. 2 shows the hose valve 1 in the open state. The hose 100 is completely open and a fluid can flow through it. In the open state of the hose valve 1, the pinch element 2 is in the open position and is unlocked. The locking device 3 has a locking element 5 which can be moved linearly up and down in the representation according to FIG. 2 and which is used to lock and unlock the squeezing element 2. The locking element 5 can be moved between the unlocking and locking positions by means of the motor drive 4, designed here as an electric motor. To supply the motor drive 4 with energy, it can be provided that it is connected directly to the power supply system. It is however, it is also conceivable, especially since cold brew coffee machines generally do not have to be connected to the power supply, to provide an additional energy store, not shown in the illustration, such as a battery or a rechargeable battery. The energy store can be designed to be exchangeable.

To move the locking element 5, the motorized drive 4 has a drive shaft 4.1, which executes a rotary movement when the drive 4 is actuated. In order to convert the rotary movement of the motorized drive 4 into a linear movement of the locking element 5, the locking device 3 also has a gear 6. The locking element 5 is guided through the first housing part 9.1.

As an alternative to a linearly moved locking element 5, it would also be possible to move the locking element 5 in a rotary manner. Such a solution would have the advantage that the rotational movement of the motor drive 4 could be transmitted directly to the locking element 5.

As shown in FIG. 2, the transmission 6 has a drive-side transmission element 6.1 and a locking-side transmission element 6.2 for converting the rotational movement of the motor drive 4 into the linear movement of the locking element 5. In the game Ausführungsbei the drive-side gear element 6.1 is designed as a cam and the locking-side gear element 6.2 as a driver. The drive-side gear element 6.1 is coupled to the drive shaft 4.1 and follows the rotational movement of the drive shaft 4.1 when the motor-driven drive 4 is actuated. The locking-side gear element 6.2 is arranged in one piece on the locking element 5. If the motorized drive 4 is actuated, the drive-side Ge gear element 6.1 rotates and takes the locking-side gear element 6.2 with, so that the locking element 5 moves up and down as shown. Here, the upper position of the locking element 5 according to FIG. 2 corresponds to the unlocking position in which the squeezing element is unlocked and the lower position of the locking element 5 according to FIG. 3 of the locking position in which the squeezing element 2 is locked. In connection with FIGS. 11 to 15, the function of the locking device 3 is explained again in detail below. Fig. 3 shows the hose valve 1 in the closed state. The squeezing element 2 was moved from the open position to the closed position. The movement was generated manually, that is by hand, by a user, so that no additional energy, for example electrical energy, had to be applied. In order to move the squeezing element 2 accordingly, a part of the squeezing element 2 protrudes from the second housing part 9.2, see FIG. 2, so that a user can move the squeezing element 2 by pushing it into the housing part 9.2. The second housing part 9.2 thus additionally serves as a guide for the squeezing element 2. As a result of the movement of the squeezing element 2, the hose 100 is squeezed by means of a squeezing edge 2.1 of the squeezing element 2 and closed accordingly. The pinch edge 2.1 of the pinch element 2 can be adapted to the properties of the hose 100 before geous. It is thus possible to vary the design of the pinch edge 2.1, for example in its width or height.

The movement of the squeezing element 2 from the open position into the closed position takes place against the spring force of a first return spring 7 designed as a compression spring. However, it is also conceivable to design the return spring 7 as a tension spring through simple structural changes. The return spring 7 is arranged in the second housing part 9.2 and is biased when the squeezing element 2 moves from the open position according to FIG. 2 into the closed position according to FIG. 3. As a result of this bias, when the squeezing element 2 is unlocked by the locking element 5, the squeezing element 2 is moved from the closed position into the open position by the spring force of the return spring 7. Alternatively, it is also possible to design the hose valve 1 without a return spring 7, for example if the elasticity of the hose 100 is sufficient to move the squeezing element 2.

In addition to the first return spring 7, the hose valve 1 also has a second return spring 8, which is arranged in the first housing part 9.1. The return spring 8 is used to move the Verriege treatment element 5 from the unlocking to the locking position. In this context, too, it is possible to design the return spring 8 as a compression spring or, alternatively, as a tension spring.

To lock the squeezing element 2, the locking element 5 has a locking pin 5.1. As soon as the squeezing element 2 is moved into the closed position, the locking pin 5.1 engages with a pin receptacle 2.2 of the squeezing element 2 designed as a bore, since the locking element 5 is moved from the unlocking position into the locking position due to the spring force of the second return spring 8. The squeezing element 2 is consequently locked and the hose 100 is closed, see FIG. 3.

During the movement of the locking element 5, it is guided by the first housing part 9.1. With regard to the return springs 7, 8, it is also possible to install them in a pretensioned state. While the exemplary embodiment of the hose valve 1 enables two possible states, namely the open and closed state, it is also conceivable to design the hose valve 1 in such a way that further states are made possible. For example, it would be conceivable to provide an intermediate position for the squeezing element 2 in which the squeezing element 2 can be locked and in which the hose 100 is only partially open. A plurality of intermediate positions would also be conceivable. By repeatedly unlocking the Quetschele element 2, this could then be moved from the closed position into the intermediate position and into the open position.

To explain the squeezing process, FIGS. 4 and 5 each show the hose valve 1 in a sectional view along the axis B-B, see FIG. 1.

4 shows the open state of the hose valve 1, in which the squeezing element 2 is in the open position and the hose 100 is open. It can be seen from the illustration that the squeeze element 2 has two laterally attached latching elements 11 to limit the open position, which are received by correspondingly designed housing recesses 12 of the second housing part 9.2. The housing recesses 12 are designed as elongated holes.

In the open position of the squeezing element according to FIG. 4, the latching elements 11 rest against boundaries 12.1 of the housing recesses 12, where a movement of the squeezing element 2 beyond the open position in the manner of a stop is prevented. To dismantle the hose valve, in particular the dismantling of the squeezing element 2, it is advantageous to make the locking elements 11 flexible so that the squeezing element 2 can be removed from the housing part 9.2 ent by pressing the locking elements 11 together. According to the illustration in FIG. 5, the hose valve 1 is in a closed state. The squeezing element 2 was accordingly moved into the closed position and the hose 100 squeezed so that it is also closed. When viewing the hose 100, it becomes clear that it is elastic and must have a certain inherent elasticity.

The operating sequence of the hose valve 1 will now be discussed with reference to FIGS. 6 to 10. The representations in FIGS. 6 to 10 show this

Hose valve 1 in a sectional view along the axis A-A, see FIGS. 1, 2 and 3.

6 shows the hose valve 1 in the open state. The squeezing element 2 is correspondingly in the open position, the hose 100 is open and the locking element 5 is in the unlocking position. The return spring 7 is pretensioned.

If the squeezing element 2 is now moved into the closed position in the direction R1, the hose valve 1 is closed and the hose 100 is correspondingly squeezed until the closed position shown in FIG. 7 is reached. The squeezing element 2 is pressed against the elastic tube 100 with the squeezing edge 2.1. Since the hose 100 is received in the second housing part 9.2, it is deformed due to the squeezing until the hose 100 is closed according to FIG. 7.

The movement of the squeezing element 2 from the open position into the closed position takes place against the spring force of a restoring spring 7. The restoring spring 7 is tensioned in the closed position of the squeezing element 2 according to FIG. As soon as the squeezing element 2 has been moved from the open position along the direction R1 into the closed position, the locking pin 5.1 of the locking element 5 can engage in the pin receptacle 2.2 of the squeezing element 2 and this can be locked accordingly. During the locking, the locking element 5 moves from the unlocking position according to FIG. 6 into the locking position according to FIGS. 7 and 8.

The movement of the locking element 5 is carried out by the pretensioned return spring 8. It is an automatic snap connection. There is thus no additional energy to be applied, for example electrical energy, in order to transfer the hose valve 1 from the open state to the closed state. The hose 100 can thus be squeezed manually without applying additional energy, in particular electrical energy.

In the closed state of the hose valve 1 according to FIGS. 7 and 8 ver, the hose valve 1 remains until the hose valve 1 is opened who should. The locking element 5 is then moved into its unlocking position by means of the motor drive 4, so that the squeezing element 2 can be moved back into the open position along a direction R2. This movement takes place in the illustrated embodiment, for example, due to the biased return spring 7, as soon as the locking pin 5.1 is no longer in engagement with the pin receptacle 2.2, see. 10. FIG. 9 shows an intermediate position, while the locking element 5 from the Locking is moved into the unlocking position.

Looking at the overall operating sequence of the hose valve 1, the result is that the energy-consuming squeezing of the hose 100 manually by moving the squeezing element 2 and the far less energy. The required unlocking of the squeezing element 2 is carried out by energizing the motor drive 4.

With reference to FIGS. 11 to 15, the mode of operation of the locking device 3 will be discussed again in more detail below. 11a to 15a each show the transmission 6 in an enlarged detail along the axis CC, see FIG. 1. FIGS. 11b to 15b each show the locking element 5 in an enlarged detail along the axis AA, see FIG Fig. 1.

In FIG. 11, the hose valve 1 is in the open position, see also FIG. 6. The squeezing element 2, which is only partially shown in this illustration, is in the open position and is unlocked. Consequently, the locking element 5 is in the unlocked position.

The locking element 5 is also prestressed by the return spring 8, so that as soon as the squeezing element 2 is moved from the open position to the closed position and the pin receptacle 2.2 is in line with the locking pin 5.1, the locking element 5 from the unlocking position into the locking position is transferred, see Fig.

12b. The spring force of the return spring 8 is sufficient for this, so that the motor drive 4 does not have to be actuated. In Fig. 12 the hose valve 1 is in the closed state, see Fig. 7. The locking element 5 is in the locking position and the squeezing element 2 is locked accordingly.

If the hose valve 1 is now to be transferred from the closed state to the open state, the drive-side transmission element 6.1 is moved from the position in FIG. 11a by means of the motor drive 4 moved in rotation until the drive-side gear element 6.1 is just before engagement of the locking-side gear element 6.2 according to FIG. 12a. If the drive-side gear element 6.1 is then moved further in a rotational manner, the locking-side gear element 6.2 moves along a control curve 6.1.1 of the drive-side gear element

6.1 linear.

In FIG. 13, the drive-side gear element 6.1 is already in engagement with the locking-side gear element 6.2. The drive-side gear element 6.1 also executes a rotary movement, whereby the locking-side gear element 6.2 is guided accordingly along the control curve 6.1.1. The result is that the rotational movement of the drive-side gear element 6.1 is converted into a linear movement of the locking-side gear element 6.2. Since the locking-side gear element 6.2 is arranged in one piece on the locking element 5, the linear movement of the locking-side gear element 6.2 is transmitted directly to the locking element 5. The locking element 5 is correspondingly transferred from the locking position to the unlocking position.

In Fig. 14, the unlocking has already progressed. The locking element 5 is in an elevated position in relation to the locking position in the illustration, so that the locking pin 5.1 has already been partially moved out of the pin receptacle 2.2 of the squeezing element 2. Since, according to FIG. 14b, the locking pin 5.1 is still partially received in the pin receptacle 2.2, the squeezing element 2 is still locked.

If the locking element 5 is finally moved into the unlocked position, the squeezing element 2 is unlocked and can accordingly be transferred from the closed position to the open position, as shown in FIG. 15b represents. In the exemplary embodiment, this takes place on the basis of the return spring 7, see FIG. 10. The hose 100 is correspondingly open.

16 shows the previously described exemplary embodiment of a hose valve 1 in an exploded view, on the basis of which the assembly of the hose valve 1 is to be explained.

The housing 9 of the hose valve 1 is made in two parts. It has the first housing part 9.1 and the second housing part 9.2. The first housing part 9.1 accommodates the motor drive 4, the gear 6 and the locking element 5 and arranges them in a line.

The second housing part 9.2 receives the squeezing element 2. Furthermore, the hose 100 is also arranged in the second housing part 9.2. For the arrangement, the hose 100 is passed through the hose receptacle 10 so that when the squeezing element 2 moves from the open position into the closed position, it can be squeezed accordingly.

The housing parts 9.1, 9.2 are each designed symmetrically to simplify assembly. So the first housing part 9.1 in the presen- tation is placed on top of the second housing part 9.2 and connected to it by means of the housing connection 9.3. Due to the symmetrical design of the second housing part 9.2, however, it would also be conceivable to place the first housing part 9.1 on the second housing part 9.2 from below in the illustration.

For assembly, the hose 100 is first passed through the second housing part 9.2 and then the squeezing element 2 with the return spring 7 already pushed on is pushed into the second housing part 9.2. As soon as the locking elements 11 snap into the housing recesses 12, the squeezing element 2 is secured in the open position. Thereupon the locking element 5 can be pushed into the first housing part 9.1 with the incorporated return spring 8 and with the locking-side gear element 6.2 and the motor drive 4 connected to the drive-side gear element 6.1. The first housing part 9.1 is then attached to the second housing part 9.2 by locking the housing parts 9.1, 9.2 together by means of the housing connection 9.3. 17 shows a further exemplary embodiment of the hose valve 1 according to the invention, the differences being primarily discussed below. However, all of the advantages described above also apply to this embodiment of the hose valve 1. The hose valve 1 has, contrary to the previous embodiment, for example a three-part housing 9, which is composed of a first housing part 9.1, a second housing part 9.2 and a detachable cover 9.4. The hose receptacle 10 of the second housing part 9.2 is designed as a groove so that the hose 100 can be received therein. A hose holder 10 designed as a groove has the advantage that hoses 100 of different diameters can be accommodated in it and the hose valve 1 can thus be used for hoses 100 of different dimensions. The lateral reception of the hose 100 by the hose receptacle 10 can be advantageous, in particular, when the hoses 100 are already connected, since the second housing part 9.2 can be simply plugged onto the hose 100 accordingly. Subsequently, the hose 100 is fixed in the hose receptacle 10 in that the second housing part 9.2 is connected to the cover 9.4. For the connection, the cover 9.4 has two cover fastening elements 9.4.1, which are connected to the second housing part 9.2 snap into place. The connection is designed to be detachable, whereby it would also be conceivable to design the connection to be permanent. Furthermore, it is possible, please include, to design the connection between the second housing part 9.2 and the cover 9.4 differently, for example as a screw connection or an adhesive connection.

The hose valve 1 according to FIG. 17 also has a drive-side gear element 6.1 in the form of a cam, which can be actuated manually. For manual actuation, the drive-side gear element 6.1 has a knurled outer edge which, when the hose valve 1 is assembled, can be manually actuated by a user through an actuation recess 9.1.1 in the first housing part 9.1. The result is that, in addition to being actuated by the motorized drive 4, the locking element 5 can also be moved manually between the unlocking and locking positions. The entire hose valve 1 can in this respect also be operated completely manually, which can be advantageous, for example, if the energy store should fail.

In contrast to the embodiment described above, the squeezing element 2 does not have any latching elements 11, so that in this embodiment the position is variable. This can be particularly advantageous if the hose valve 1 is to be suitable for different hoses 100 with different diameters. Reference number:

1 hose valve

2 pinch element

2.1 Pinch edge

2.2 Trunnion mount

3 locking device

4 motor drive

4.1 Drive shaft

5 locking element

5.1 Locking pin

6 gears

6.1 drive-side gear element

6.1.1 Control cam

6.2 gear element on the locking side

7 first return spring

8 second return spring

9 housing

9.1 first housing part

9.1.1 Actuating recess

9.2 second housing part

9.3 Housing connection

9.4 Lid

9.4.1 Lid fastening element

10 hose holder

11 locking element

12 housing recess

12.1 Limitation

100 hose R1 first direction (open position-closed position)

R2 second direction (closed position-open position)

Claims

Patent claims:

1 . Hose valve, in particular for drinks machines, with a squeezing element (2) that can be manually moved from an open to a closed position for closing a hose (100) by means of squeezing and a locking device (3) for locking the squeezing element (2) in the closed position, characterized that the locking device (3) has a motor drive (4) for unlocking the squeezing element (2).

2. Hose valve according to claim 1, characterized in that the locking device (3) has a locking element (5) movable between an unlocking and a locking position for locking the squeezing element (2) in its closed position.

3. Hose valve according to claim 2, characterized in that the direction of movement of the locking element (5) runs transversely to the direction of movement of the squeezing element (2).

4. Hose valve according to one of the preceding claims, characterized in that the locking device (3) has an energy storage device, in particular a battery and / or a rechargeable battery, for supplying energy to the motor drive (4).

5. Hose valve according to one of claims 2 to 4, characterized in that the locking device (3) for coupling the motorized drive (4) with the locking element (5) has a gear (6) via which one of the Drive (4) Mende rotary movement can be converted into a linear movement of the locking element (5).

6. Hose valve according to claim 5, characterized in that the gear (6) has a drive-side gear element (6.1) and a locking-side gear element (6.2).

7. Hose valve according to claim 6, characterized in that one of the gear elements (6.1) is designed as a cam and one of the gear elements (6.2) is designed as a driver that can be moved over the cam.

8. Hose valve according to one of the preceding claims, characterized in that the squeezing element (2) can be moved from the open to the closed position against the force of a tensioning return spring (7).

9. Hose valve according to one of the preceding claims, characterized in that the locking element (5) can be moved from the locking position to the unlocking position against the force of a tensioning return spring (8).

10. Hose valve according to one of the preceding claims, characterized by a housing (9) for the arrangement of the locking device (3), the drive (4) and the squeezing element (2).

11. Hose valve according to claim 10, characterized in that the locking device (3), in particular the locking element (5), the gear (6) and the drive (4), in a first housing part (9.1) of the housing (9) and the squeezing element (2) are arranged in a second housing part (9.2) of the housing (9).

12. Hose valve according to one of claims 10 or 11, characterized in that the housing (9) for receiving the hose (100) has a hose receptacle (10).

13. Hose valve according to one of claims 11 or 12, characterized in that the housing (9) has a detachable cover (9.4) for exchanging the hose (100).

14. Beverage machine, characterized by a hose valve (1) according to one of the preceding claims.

15. A method for opening and closing a hose (100), marked by a hose valve (1) according to any one of claims 1 to 13.