DE102017008220B4 - Device for deactivating a multi-way valve - Google Patents

Abstract

Deactivatable multi-way valve system (300) with a multi-way valve device (100), wherein the multi-way valve device (100) comprises a housing (102) with a functional element (106) arranged along a main axis (104) of the housing (102) and designed to be removable Arrangement of the functional element (106) in the housing (102), at least one first fluid flow channel is defined through the housing (102), the deactivatable multi-way valve system (300) also having a deactivation device (200) which, instead of the functional element (106), is located along the Main axis (104) is designed to be insertable into the housing (102) of the multi-way valve device (100), the deactivation device (200) being designed to completely close the first fluid flow channel in a state inserted into the housing (102), characterized in that the Deactivation device (200) can be connected to the functional element (106) out is formed in order to remove the functional element (106) from the housing (102) of the multi-way valve device (100).

Description

The invention relates to a deactivatable multi-way valve system with a multi-way valve device, the multi-way valve device having a housing with a functional element arranged along a main axis of the housing and designed to be removable. The arrangement of the functional element in the housing defines at least one first fluid flow channel through the housing.

One from the pamphlet DE 10 2013 001 134 A1 Known multi-way valve comprises a multi-way valve which has at least one control unit inserted into a valve housing, which is composed of an axially movable control member and a control sleeve surrounding the control member. To control a fluid flow, the control unit has two axially spaced, first and second pairs of valve seats, each of which contains a first valve seat arranged on the control sleeve and a second valve seat arranged on the control member. In the first pair of valve seats, the first valve seat is formed by a rigid sealing section and the second valve seat is formed by a deformable sealing lip. In the second pair of valve seats, the first valve seat is formed by a deformable sealing lip and the second valve seat is formed by a rigid sealing section.

The pamphlet WO 2016/128104 Al discloses a pressure relief valve with a suction function, which has a valve housing with at least two connection points, in particular in the form of a working connection and a tank connection and with a spring-loaded pressure relief valve piston that is longitudinally displaceable in the valve housing and with a spring-loaded check valve piston for the implementation of the suction function, with the check valve as a hollow piston executed and guided in the valve housing longitudinally.

Furthermore, the publications DE 10 2013 209 524 A1 and DE 103 36 334 B3 known from the prior art.

Such multi-way valves are also known in a different design as so-called vacuum modules. The essential commonality of both multi-way valve designs, however, is the fact that in the course of the service life cycle of such multi-way valves, the need may arise to deactivate the multi-way valves. This can be justified, for example, with increased efficiency or energy-saving measures. A deactivation of such multi-way valves is implemented, for example, by changing their position within the housing of the multi-way valves so that they can be displaced. Functional elements can be formed, for example, by vacuum cartridges or, alternatively, by cartridges with integrated control pistons. By changing the position of the functional elements, a fluid flow through the valve is changed or prevented. In the simplest case, these functional elements are removed and replaced by a piston that closes at least one or more fluid flow paths.

The object on which the invention is based is to provide a multi-way valve system which realizes a deactivation of a multi-way valve in a particularly simple and efficient manner. The invention solves the problem of reducing the assembly effort and saving energy while the multi-way valve is in use.

According to the invention, this object is achieved by the subject matter of claim 1.

The invention is therefore based on the idea of specifying a multi-way valve system with a deactivation device, the deactivation device being designed to be connectable to the functional element in order to remove the functional element from the housing of the multi-way valve device.

The advantage of the deactivatable multi-way valve system according to the invention is that the deactivation device serves both as a tool for removing the functional element and as a closure of the fluid flow channels in the housing of the multi-way valve system, in that the deactivation device first removes the functional element within the multi-way valve system and then takes its place in the housing . As a result, it is not necessary to provide a separate tool for removing the functional element and for introducing the deactivation device, since the deactivation device itself serves as a tool for removing the functional element.

According to a preferred embodiment, the deactivation device is designed at least in sections as a blind plug in order to replace the functional element. In this way, for example, the technical advantage is achieved that the dummy plug can initially serve as a grip element of the tool for removing the functional element. When the deactivation device is inserted into the housing, the blind plug, which previously serves as a grip element for manually operating the tool, completely closes one or more fluid flow channels within the multi-way valve.

In order to improve the deactivation, or to improve the closing of all fluid flow channels by introducing the deactivation device, the deactivation device has at least one sealing element. Alternatively or additionally, it is possible to arrange several sealing elements on the deactivation device. It would also be conceivable to arrange the sealing elements on the deactivating device in such a way that when the deactivating device is introduced into the housing of the multi-way valve, all fluid flow channels optimally adjoin a sealing element and can thus be sealed particularly effectively.

In order to unintentionally remove a deactivation device from the housing of the multi-way valve and to ensure a particularly secure arrangement of a deactivation device, the deactivation device has a threaded section in order to screw the deactivation device into the housing of the deactivatable multi-way valve system.

In order to implement the removal of the functional element in a particularly simple manner, the deactivation device has a first interface. The first interface can be designed in any shape that enables either a form fit or a force fit with the functional element.

According to a preferred embodiment, the functional element has a second interface which is designed to establish a non-positive and / or positive connection with the first interface of the deactivation device. For example, the second interface is designed in such a way that it corresponds to the first interface. This can be done, for example, with the operating principle of a screwdriver, an Allen key or any other known tool principle.

According to a particularly preferred embodiment, the first interface has at least one axially extending projection in a longitudinal direction of the deactivation device. In this way, for example, the technical advantage can be realized that the deactivation device can be used in a similar way to a screwdriver. The at least one axially extending projection has a particularly simple mode of operation, is expedient and inexpensive to manufacture.

In order to optimize the interaction of the functional element and the deactivation device, the second interface of the functional element has an engagement opening for the first interface. Thus, both the first interface on the deactivation device and the second interface of the functional element can be optimally matched to one another, whereby a particularly efficient introduction of force is possible when the deactivation device is operated manually. Both the first interface on the deactivation device and the second interface on the functional element are each arranged on the end face.

According to a further preferred embodiment, the deactivation device has a third interface. This achieves the technical advantage, for example, that the deactivation device can be manually fixed in the housing of the multi-way valve or removed from it by means of a further tool. It would be conceivable here, for example, to design the third interface as a simple slot-like interface, cross-slot interface, star-shaped interface or as an Allen interface. Thus, both the first interface and the third interface can be arranged at the front on one side of the deactivation device. As a result, the first interface of the deactivation device can be used to remove the functional element. In contrast, the third interface can be used to fix or screw the deactivation device into the housing of the multi-way valve after the functional element has been removed.

In order to design the deactivation device in a particularly simple and compact manner, the first interface is formed on a section of the deactivation device opposite the section of the deactivation device designed as a blind plug. As a result, the section of the deactivation device which is designed as a blind plug can be used as a grip element of the deactivation device that can be used as a tool for removing the functional element. If the functional element has now been removed from the housing of the multi-way valve through the first interface of the deactivation device, the deactivation device can be turned over and inserted into the housing of the multi-way valve with the opposite end or with the section designed as a blind plug.

In order to be able to adapt the deactivatable multi-way valve system more individually to the intended use or to application-specific circumstances, the deactivatable multi-way valve system defines at least one second fluid flow channel through the housing through the arrangement of the functional element in the housing. Furthermore, the deactivation device is designed to close only the first fluid flow channel in a state inserted into the housing of the multi-way valve device. This will For example, the technical advantage achieved that only the first fluid flow channel is closed, while the second fluid flow channel, which is arranged within the multi-way valve system, remains open. It is thus possible to close only one fluid flow channel or several fluid flow channels and at the same time not to close or keep open individual fluid flow channels or several fluid flow channels. As a result, the area of use of such a deactivatable multi-way valve system is significantly enlarged and can be flexibly adapted to the intended use.

According to a further preferred embodiment, the deactivatable multi-way valve system is designed as a vacuum module. Here, the functional element is designed as a removable object within the housing of the vacuum module, which generates a vacuum with the aid of a Venturi nozzle, for example, and thus forms a fluid flow channel in the housing that can operate a vacuum interface. The functional element of the deactivatable reusable system is designed as a vacuum cartridge.

The invention is explained in more detail below with the aid of several exemplary embodiments and with reference to the attached illustrations.

• 1 eine Mehrwegeventilvorrichtung in Form eines Vakuummoduls,
• 2 eine Mehrwegeventilvorrichtung in Form eines Vakuummoduls, wobei eine Deaktivierungsvorrichtung im Eingriff mit dem Funktionselement angeordnet ist,
• 3 eine Mehrwegeventilvorrichtung in Form eines Vakuummoduls, wobei eine Deaktivierungsvorrichtung in das Gehäuse der Mehrwegeventilvorrichtung eingebracht ist,
• 4 eine perspektivische Darstellung eines Funktionselements, und
• 5 eine perspektivische Darstellung einer Deaktivierungsvorrichtung.

Show it:

• 1 a multi-way valve device in the form of a vacuum module,
• 2 a multi-way valve device in the form of a vacuum module, wherein a deactivation device is arranged in engagement with the functional element,
• 3rd a multi-way valve device in the form of a vacuum module, wherein a deactivation device is introduced into the housing of the multi-way valve device,
• 4th a perspective view of a functional element, and
• 5 a perspective view of a deactivation device.

The 1 shows a multi-way valve device 100 in the form of a vacuum module. The multi-way valve device 100 includes a main control unit 112 , a pilot control unit 114 and a silencer 110 , which on the housing 102 the multi-way valve device 100 are arranged. In addition, the housing 102 the multi-way valve device 100 a vacuum connection 108 as well as a main axis 104 on. Inside the case 102 is along the main axis 104 a functional element 106 designed to be removable, with the arrangement of the functional element 106 in the case 102 a fluid flow channel through the housing 102 is defined through it. This fluid flow channel is with the vacuum connection 108 connected. By creating a vacuum inside the housing 102 what, for example, with the help of a Venturi nozzle inside the functional element 106 can be realized, enormous sound peaks arise, which are caused by the silencer 110 at the front output of the functional element 106 can be weakened or greatly reduced. The functional element 106 is designed as a vacuum cartridge.

The 2 shows a deactivatable multi-way valve system 300 with a multi-way valve device 100 , where the functional element 106 in the case 102 the multi-way valve device 100 along a major axis 104 is arranged. Furthermore, the deactivatable multi-way valve system 300 the main control unit 112 , the pilot control unit 114 and the vacuum connection 108 on which on the housing 102 the multi-way valve device 100 are arranged. The deactivatable multi-way valve system 300 additionally has a deactivation device 200 on which the front side of the functional element 106 is arranged. This is the deactivation device 200 used as a tool to the functional element 106 , in the form of a vacuum cartridge, out of the housing 102 the multi-way valve device 100 , in the form of a vacuum module. One from the functional module 106 and the case 102 the multi-way valve device 100 remote side of the deactivation device 200 is designed as a handle element, whereby the manual actuation of the deactivation device 200 in relation to the functional element 106 is possible.

The 3rd shows a multi-way valve device 100 , where the functional element 106 by the deactivation device 200 was replaced. The part of the deactivation device, which is partially designed as a blind plug, was thereby removed 200 , which for the purpose of removing the functional element 106 as a handle element of the deactivation device 200 was used in the housing 102 introduced, creating the fluid flow channel that connects to the vacuum port 108 is formed fluidly connected, is completely closed. Here, the deactivation device comprises 200 two sealing elements 202 in order to improve the sealing or closing of the fluid flow channel. The deactivation device 200 includes a threaded portion 204 , which a screwing and thus a reliable fixation of the deactivation device 200 in the case 102 the multi-way valve device 100 ensures. In addition, the deactivation device is located at a front end 200 a first interface 206 in the form of two axially protruding projections 208 to intervene in a second interface 207 (not shown) of the functional element 106 (Not shown). The first interface 206 is thus for connecting the deactivation device 200 and the functional element 106. A third interface 209 is used to fix or remove the deactivation device 200 in the case 102 the multi-way valve device 100 usable. For the application or for the use of the deactivation device 200 there is thus the great advantage that the first interface 206 the section of the deactivation device designed as a blind plug 200 is formed opposite. Thus, the blind plug can be used as a handle or handle element of the deactivation device 200 serve as a tool with the first interface 206 to remove the functional element 106 with the second interface 207 can be used. If the functional element 106 out of the case 102 the multi-way valve device 100 removed, the deactivation device 200 upside down and with the dummy plug instead of the functional element 106 in the housing 102 brought in. With another tool, such as a screwdriver or an Allen key, the deactivation device 200 via the third interface 209 final in the housing 102 be fixed.

The 4th shows a perspective view of a functional element 106 , which is designed as a vacuum cartridge. The vacuum cartridge encompasses the second interface in a frontal arrangement 207 , which is designed to do so with the first interface 206 (not shown) the deactivation device 200 (not shown) cooperate. Here the second interface includes 207 a total of two access openings 210 which for engaging the protrusions 208 (not shown) of the first interface 206 are trained. The first interface 206 the deactivation device 200 and the second interface 207 of the functional element 106 In this case, by no means have to go through the engagement openings shown by way of example 210 and the axially extending protrusions 208 will be realized. In particular, any non-positive and / or form-fitting connection is suitable which enables the engagement and interaction between the deactivation device 200 and functional element 106 enables.

The 5 shows a perspective view of a deactivation device 200 . The deactivation device 200 includes the sealing elements 202 which are at opposite ends of the deactivation device 200 are arranged. Through the two sealing elements 202 and the deactivating device shaft disposed therebetween 200 the dummy plug is formed, which is inserted into the housing 102 the multi-way valve device 100 introduced state completely closes the fluid flow channel of the vacuum module and thereby deactivates the vacuum module. The deactivation device 200 additionally includes a threaded section 204 , which for safe and reliable fixing of the deactivation device 200 in the case 102 serves. At one end of the deactivation device 200 is the first interface 206 which is suitable for this with the second interface 207 (not shown) of the functional element 106 (not shown) to cooperate around the functional element 106 out of the case 102 to remove. The first interface 206 is by two axially extending projections 208 formed, which with the engagement openings 210 (not shown) of the second interface 207 correspond or in the engagement openings 210 are designed to be insertable. It is also possible to have additional projections, notches or other means of engagement on the front end of the deactivation device 200 to arrange. In addition, the deactivation device is located in a central position on the same end face 200 a third interface 209 . The third interface 209 is used to reliably fix or remove the deactivation device 200 , provided the functional element 106 removed and the deactivation device in the housing 102 the multi-way valve device 100 is introduced.

List of reference symbols

100

Multi-way valve device

102

casing

104

Main axis

106

Functional element

108

Vacuum connection

110

silencer

112

Main control unit

114

Pilot control unit

200

Deactivation device

202

Sealing element

204

Threaded section

206

First interface

207

Second interface

208

head Start

209

Third interface

210

Access opening

300

Multi-way valve system

Claims (14)

Deactivatable multi-way valve system (300) with a multi-way valve device (100), wherein the multi-way valve device (100) comprises a housing (102) with a functional element (106) arranged along a main axis (104) of the housing (102) and designed to be removable Arrangement of the functional element (106) in the housing (102), at least one first fluid flow channel is defined through the housing (102), the deactivatable multi-way valve system (300) also having a deactivation device (200) which, instead of the functional element (106), is located along the Main axis (104) is designed to be insertable into the housing (102) of the multi-way valve device (100), the deactivation device (200) being designed to completely close the first fluid flow channel in a state inserted into the housing (102), characterized in that the Deactivation device (200) can be connected to the functional element (106) is formed in order to remove the functional element (106) from the housing (102) of the multi-way valve device (100). Deactivatable multi-way valve system (300) according to Claim 1 , characterized in that the deactivation device (200) is designed at least in sections as a blind plug to replace the functional element (106). Deactivatable multi-way valve system (300) according to one of the preceding claims, characterized in that the deactivation device (200) has at least one sealing element (202). Deactivatable multi-way valve system (300) according to one of the preceding claims, characterized in that the deactivating device (200) has a threaded section (204) in order to screw the deactivating device (200) in the housing (102) of the deactivatable multi-way valve system (300). Deactivatable multi-way valve system (300) according to one of the preceding claims, characterized in that the deactivation device (200) has a first interface (206). Deactivatable multi-way valve system (300) according to Claim 5 , characterized in that the functional element (106) has a second interface (207) which is designed to establish a non-positive and / or positive connection with the first interface (206) of the deactivation device (200). Deactivatable multi-way valve system (300) according to Claim 5 or 6th , characterized in that the first interface (206) has at least one axially extending projection (208) in a longitudinal direction of the deactivation device (200). Deactivatable multi-way valve system (300) according to Claim 6 , characterized in that the second interface (207) of the functional element (106) has an engagement opening (210) for the first interface (206). Deactivatable multi-way valve system (300) according to one of the preceding claims, characterized in that the deactivation device (200) has a third interface (209). Deactivatable multi-way valve system (300) according to Claim 5 , characterized in that the first interface (206) is formed on a section of the deactivation device (200) opposite the section of the deactivation device (200) designed as a blind plug. Deactivatable multi-way valve system (300) according to one of the preceding claims, characterized in that the deactivatable multi-way valve system (300) defines at least one second fluid flow channel through the housing (102) through the arrangement of the functional element (106) in the housing (102). Deactivatable multi-way valve system (300) according to Claim 11 , characterized in that the deactivation device (200) is designed to close only the first fluid flow channel in a state introduced into the housing (102) of the multi-way valve device (100). Deactivatable multi-way valve system (300) according to one of the preceding claims, characterized in that the deactivatable multi-way valve system (300) is designed as a vacuum module. Deactivatable multi-way valve system (300) according to Claim 13 , characterized in that the functional element {106) of the deactivatable multi-way valve system (300) designed as a vacuum module is designed as a vacuum cartridge.

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