DE102017102455A1 - Pressure indicator for a fluid - Google Patents

Abstract

The invention relates to a pressure indicator (100) for a fluid, in particular for air, comprising a housing (102) at least one inflow port (104) for flowing a fluid into the housing (102) and at least partially disposed in the housing (102) A pressure member (106), said pressure member (106) interposing a first condition in which the pressure member (106) defines a cavity (122) in the housing (102) and a second condition in which the pressure member (106) defines the cavity (122) at least partially fills, is formed convertible.

Description

The present invention relates to a pressure indicator for a fluid, in particular for air.

Air pressure gauges are known in various applications, such as in the field of vehicle tires or air pumps. Particularly in the field of pneumatic drive technology, extensive equipment of industrial plants is under constant air pressure. For safety reasons, it is desired by operators of such pneumatic systems to use visual displays for the purpose of rapid diagnostics, but also as a warning of pressurized lines. For this purpose, sometimes complicated and expensive measuring devices are used.

It is the object underlying the invention to provide an improved concept of a pressure indicator, which is suitable as a simple but reliable solution for visual display, rapid diagnosis and also as a warning device against pressurized pneumatic lines.

This object is achieved by objects according to the independent claims. Advantageous embodiments are the subject of the dependent claims, the description and the drawings.

According to a first aspect, the object is achieved by a pressure indicator for a fluid, in particular for air, with a housing, at least one inflow port, for flowing a fluid into the housing, and a pressure element arranged at least partially in the housing, wherein the pressure element between a first state, in which the pressure element defines a cavity in the housing, and a second state, in which the pressure element at least partially fills the cavity, is designed to be transferable.

For the purposes of the present application, a pressure indicator is understood to be a type of hose coupling device which can be connected in a simple manner via an inflow connection to a hose or a line or another fluid-carrying device. An inventive pressure indicator brings, for example, the technical advantage that it can be produced very easily and at very low cost. In this case, it is possible, in a very simple manner, to realize a visual indication of an actually prevailing air pressure state of a line or a hose. The pressure indicator is also easy to replace and thus makes an important contribution to increasing safety in the field of pneumatic systems.

According to a preferred embodiment, the pressure element is elastically deformable. In particular, it lends itself here to form the pressure element as an elastomer, whereby in each case the elastic deformability is given. The pressure element is in this case arranged in the housing such that an elastic deformation between the first state and the second state is effected exclusively by the action of air. Preferably, the dimensioning of the pressure element within the housing is selected such that an elastic deformation of the pressure element and thus the actuation of the pressure indicator takes place from a preferred pressure threshold. This air pressure threshold could be 0.5 bar or more, such as two bar, four bar, six bar, eight bar, ten bar, twelve bar, fourteen bar or sixteen bar. In order to improve the inherent elasticity of the pressure element or of the elastomer, a bending plate element can be arranged within the elastomer in order to effect a better overall elasticity of the pressure element. The elasticity of the pressure element is in particular designed such that a falling below the preferred pressure threshold has a return transfer of the pressure element to the first state result.

In order to improve the visual display and the use as a warning device of the pressure indicator, the housing comprises at least one viewing aperture to enable a visual determination of whether the pressure element is arranged in the first state or in the second state. It is also conceivable to provide a plurality of viewing openings on the housing of the pressure indicator. These may be arranged, for example, on different sides of the housing, whereby a visual statement of several pages is possible.

According to a preferred embodiment, the pressure element releases the viewing port in the first state and closes it in the second state. As a result, for example, the technical advantage is achieved that the visual visual inspection in response to a desired pressure threshold, which transfers the elastically deformable pressure element from the first state to the second state, in a very simple manner and a clear state indication is visually verifiable.

According to a further embodiment, the viewing opening has a transparent cover. This makes it possible to protect the pressure indicator or the pressure element arranged in the housing of the pressure indicator against external influences, such as moisture or contaminants. Furthermore, the cover stands by their transparent execution of the visual statement, in which state the pressure element and in the immediate consequence, the line to which the pressure indicator is connected is located.

In order to improve the clarity and thus the quality of the visual determination of the state of the pressure indicator, the cover is shown like a lens. As a result, it is possible, for example, to increase the visual statement under an enlarged viewing angle of a user on the pressure indicator. Likewise, it is possible by the lens-like design of the cover to get more light through the viewing aperture on the printing element. Likewise, this ultimately provides for an improvement in the visual visibility of the state of the printing element.

To ensure the operation of the pressure indicator, the pressure element is arranged in or on a flow channel of the fluid. Thus, the fluid, in particular the air, act directly on the pressure element, whereby the desired determination of the current pressure state can be realized.

In order to protect the arrangement of the pressure element within the housing as easily as possible against external influences, such as moisture or dirt, the pressure element has at least one collar in order to arrange the pressure element on the housing. Such a collar is preferably suitable for gluing the pressure element directly to the housing. Alternatively or additionally, the collar offers a suitable possibility for clamping, gluing or welding the pressure element to the housing. Basically, however, it is assumed that a self-sealing operation of the pressure element. Its peripheral side walls are always pressed against the inner wall of the housing of the pressure indicator as a result of the fluid pressure, or the air pressure, so that thereby a reliable seal can be realized.

According to a particularly preferred embodiment, the pressure element is arranged in the flow channel such that it can flow around fluid flowing through the flow channel. This realizes a uniform effect of acting within the pressure indicator air pressure on the pressure element. Thus, a highly reliable interaction between applied air pressure and elastic deformation of the pressure element can be assumed.

In order to additionally improve the flow around the pressure element and the mode of action of the pressure element, the pressure element has an elliptical cross section. The elliptical shape of the pressure element has a favorable flow-related effect for the unhindered flow through the housing of the pressure indicator.

In order to realize the transfer of the pressure element from the first state in which the pressure element defines the cavity in the housing to the second state in which the pressure element at least partially fills the cavity, in the case of a pressure element having an elliptical cross section, the cavity is inside formed of the pressure element. If now the inner volume of the housing of the pressure indicator is under pressure, the pressure element is first completely flowed around in the region of its elliptical cross section and squeezed together when a desired critical pressure load is reached. Due to the elliptical design of the printing element a squeezing even at relatively low pressure loads is possible. Furthermore, in the event of deforming the pressure element or, in the case of a crushing of the pressure element at a preferred critical pressure load, the elliptical configuration permits a complete and uniform closure of the pressure element in the region of the cavity. The complete closure of the cavity due to the compressive load acting within the housing, in turn, ensures a clear visual determination of the condition from the outside of the pressure indicator. This embodiment also ensures that the pressure element is protected even at very high loads against damage caused by pressure overload. In other words, the pressure element can not be damaged even at the highest pressures, since the elastic deformation of the cavity within the elliptical cross-section limits. When the pressure element is arranged in the second state, this closes the cavity formed within the pressure element and thus the visual opening for the external visual detection of a pressure state of the pressure indicator. In this case, the surfaces of the arranged inside the pressure element cavity are pressed directly on each other.

In order to prevent sticking or sticking of the opposing and contacting surfaces of the cavity, it may be provided with suitable non-sticking means. These release agents can be realized by simple non-stick coatings or corresponding surface structuring using the lotus effect. The technical effect of the application of a corresponding non-stick agent is to be found here in ensuring the elastic return of the pressure element in the first state, whereby the cavity is released again within the pressure element.

According to yet another preferred embodiment, the pressure element is in the Housing arranged that the pressure element for a fluid is flowed through. As a result, for example, the technical advantage is achieved that the elastic deformation of the pressure element upon reaching a critical pressure threshold, inside the housing is not oriented inwardly, but acts outward in the direction of the inner wall of the housing of the pressure indicator. This enables a simplified and reliable way of arranging the pressure element within the housing of the pressure indicator.

In order to produce the printing element as simply as possible and to ensure the arrangement of the printing element against the background of the visual state determination by the at least one viewing opening on the housing of the pressure indicator, the pressure element has a rectangular cross-section. Thus, the collar can be arranged at the beginning or at the end of the flow-through pressure element, resulting in the case of a rectangular configuration of the cross section particularly easy to produce mounting surfaces of the pressure element within the housing of the pressure indicator.

Due to the fact that the pressure element is designed to flow through a fluid, the deformation of the pressure element upon reaching a certain pressure threshold in a radial direction, starting from the flow channel of the pressure indicator, must take place. In order not to wear the outer wall of the pressure indicator during the deformation in the radial direction by friction or other effects of the inner wall of the housing of the pressure indicator, an inner wall of the housing in the region of the pressure element has a concave contour. Thus, the pressure element can be easily pressed against the inner wall of the housing in the event of elastic deformation, without assuming a wear or other reduction of the life of the pressure element.

According to yet another preferred embodiment, the pressure element is designed to deform in the transition from the first state to the second state in a radial direction starting from the flow channel. As a result, the technical advantage is achieved, for example, that the cavity outside the pressure element between the pressure element and the housing of the pressure indicator is arranged. Consequently, the pressure element fills the cavity in the second state, in which the pressure element is transferred when a certain threshold pressure is exceeded, at least partially. By appropriate arrangement of a viewing aperture, the visual determination of the condition can be made.

In order to improve the determination of the state of the pressure element within the pressure indicator, the pressure indicator comprises a signal generator, which is designed to give a signal by the elastic deformation of the pressure element. Such a signal may, for example, improve the visual detection by triggering a light signal, or supplement the visual detection with an additional acoustic signal.

In order to realize the visual detection of the pressure indicator in a particularly simple, reliable and cost-effective manner, the signal generator is designed to be insertable into the cavity of the pressure element. This can be used in a simple manner, the already occurring elastic deformation of the pressure element to optimize the visual determination of the state of the user from the outside of the pressure indicator.

In order to additionally improve the arrangement of the pressure element within the housing of the pressure indicator, the pressure indicator comprises a fixing element in order to seal the pressure element relative to the housing. The fixing element can preferably act directly as a securing ring on the collar of the sealing element, and clamp it directly to the housing of the pressure indicator. Alternatively or additionally, such a fixing element is suitable for gluing, screwing, welding or otherwise sealing the sealing element in the housing of the pressure indicator with respect to the housing.

To facilitate manufacture of the pressure indicator during assembly, the pressure indicator includes an alignment section to align the pressure element with the housing. Here, in particular when inserting and arranging the sealing element into the housing of the pressure indicator, a simplification and, in immediate consequence, an improvement in the precision of the arrangement of the sealing element in relation to the housing can be realized. This is particularly important for the alignment and deformation of the pressure element in a transfer from the first state to the second state in relation to the concave contour of the inner wall of the housing of particular importance. In addition, the associated visual determination of the condition of the pressure member through the viewing port provides increased precision to the orientation of the pressure member relative to the housing of the pressure indicator.

The invention is explained in more detail below on the basis of exemplary embodiments with reference to the accompanying schematic drawings.

• 1 eine perspektivische Explosionsdarstellung eines Druckindikators;
• 2a eine Längsschnittdarstellung eines Druckindikators in einem ersten Zustand;
• 2b eine Längsschnittdarstellung eines Druckindikators in einem zweiten Zustand;
• 3a eine Querschnittsdarstellung eines Druckindikators in einem ersten Zustand;
• 3b eine Querschnittsdarstellung eines Druckindikators in einem zweiten Zustand;
• 4 eine weitere perspektivische Explosionsdarstellung eines Druckindikators;
• 5 eine perspektivische Darstellung eines Druckindikators;
• 6a eine Längsschnittdarstellung eines Druckindikators in einem ersten Zustand;
• 6b eine Längsschnittdarstellung eines Druckindikators in einem zweiten Zustand;
• 7a eine Querschnittsdarstellung eines Druckindikators in einem ersten Zustand;
• 7b eine Querschnittsdarstellung eines Druckindikators in einem zweiten Zustand;
• 8a eine Seitenansicht eines Druckindikators in einem ersten Zustand;
• 8b eine Seitendarstellung eines Druckindikators in einem zweiten Zustand;
• 9 eine weitere Darstellung eines Druckindikators;
• 10a eine perspektivische Darstellung eines Signalgebers;
• 10b eine weitere perspektivische Darstellung eines Signalgebers in einem deformierten Zustand;
• 10c eine perspektivische Darstellung eines Signalgebers in einem Druckelement;
• 11a eine schematische Frontansicht eines Signalgebers in einem nicht deformierten Zustand; und
• 11b eine schematische Frontansicht eines Signalgebers in einem deformierten Zustand.

Show it:

• 1 an exploded perspective view of a pressure indicator;
• 2a a longitudinal sectional view of a pressure indicator in a first state;
• 2 B a longitudinal sectional view of a pressure indicator in a second state;
• 3a a cross-sectional view of a pressure indicator in a first state;
• 3b a cross-sectional view of a pressure indicator in a second state;
• 4 another perspective exploded view of a pressure indicator;
• 5 a perspective view of a pressure indicator;
• 6a a longitudinal sectional view of a pressure indicator in a first state;
• 6b a longitudinal sectional view of a pressure indicator in a second state;
• 7a a cross-sectional view of a pressure indicator in a first state;
• 7b a cross-sectional view of a pressure indicator in a second state;
• 8a a side view of a pressure indicator in a first state;
• 8b a page representation of a pressure indicator in a second state;
• 9 another illustration of a pressure indicator;
• 10a a perspective view of a signal generator;
• 10b a further perspective view of a signal generator in a deformed state;
• 10c a perspective view of a signal generator in a pressure element;
• 11a a schematic front view of a signal generator in a non-deformed state; and
• 11b a schematic front view of a signal generator in a deformed state.

The 1 shows an exploded perspective view of a pressure indicator 100 for a fluid, in particular for air. The pressure indicator 100 includes a housing 102 , which has an inflow connection 104 and a discharge connection 114 having. The inflow connection 104 serves to flow a fluid into the housing 102 and the outlet connection 114 serves to discharge the fluid from the housing 102 out. A sealing element 118 gets into both the inflow port 104 as well as in the outlet connection 114 introduced, in each case additionally a hose holder 119 and a hose release device 120 be mounted axially in the flow direction. The hose holder 119 and the hose release device 120 Here are the usual means for a pneumatic hose or a pneumatic line with the pressure indicator 100 connect to. Laterally on the housing 102 of the pressure indicator 100 there is a viewing opening 108 , The sight opening 108 allows a visual check of the condition of a printing element 106 which is in the housing 102 of the pressure indicator 100 is arranged. The pressure element 106 is elastically deformable and made convertible between a first state and a second state. The first state is characterized in that the pressure element 106 in a non-deformed state, a cavity 122 Are defined. The second state is characterized in that the pressure element 106 the cavity 122 closes in a squeezed state. Due to the transfer of the pressure element 106 between the first state in which the pressure element 106 the cavity 122 defined, and the second state in which the pressure element 106 the cavity 122 at least partially closing, it is possible through the viewing aperture 108 a visual statement to realize if the printing element 106 is in the first state or in the second state. Here, the pressure element comprises 106 an additional collar 124 which arranges the pressure element 106 in the housing 102 of the pressure indicator 100 simplified. In addition, the pressure indicator includes 100 a cover 110 which the sight opening 108 protects against dirt or moisture from the outside. The cover 110 is designed as a transparent component to the visual detection through the viewing port 108 on the condition of the printing element 106 not restrict. The cover can in this case on the housing 102 screwed on, aufgeklippst or glued on. Immediately to an edge of the viewing aperture 108 adjacent there is a ventilation opening 116 to get air out of the cavity 122 of the printing element 106 to escape when transferring from the first state to the second state. It is equally possible when transferring the printing element 106 , which is formed elastically deformable, from the second state to the first state, air from outside the cavity 122 through the ventilation opening 116 in the cavity 122 of the printing element 106 to flow in. The pressure element 106 is so in a flow channel 112 (not shown) of the pressure indicator 100 arranged it from passing through the flow channel 112 flowing fluid can flow around. To the fluid through the flow channel 112 to flow through favorable flow and unhindered, has the pressure element 106 an elliptical cross section. An equally elliptical cross section includes the cavity 122 within the pressure element 106 , The resulting constant wall thickness of the pressure element 106 , allows a particularly controlled squeezing of the sealing element 106 as a function of a preferred pressure threshold within the flow channel 112 ,

The 2A shows a longitudinal sectional view of a pressure indicator 100 in the first state in which the pressure element 106 the cavity 122 Are defined. The housing 102 of pressure indicator 100 has the inflow port 104 and the outlet connection 114 , wherein in each case a sealing element 118 , a hose holder 119 and a hose release device 120 in the inflow connection 104 and the outlet connection 114 are introduced. Between the inflow connection 104 and the discharge connection 114 extends inside the housing 102 the flow channel 112. Centrally in the flow channel 112 is the pressure element 106 which has an elliptical cross-section. Inside the printing element 106 is the cavity 122 which also comprises an elliptical cross-section. Furthermore, the pressure element comprises 106 the collar 124 around the pressure element 106 in the middle in the flow channel 112 of the housing 102 to arrange. Due to the already mentioned first state of the printing element 106 is the pressure element 106 in a non-deformed state.

The 2 B shows a longitudinal sectional view of a pressure indicator 100 in the second state. Due to the pressure element 106, which is in the second state, the pressure element is 106 squeezed together, causing the cavity 122 is closed. The squeezing or closing of the cavity 122 is determined by a certain critical pressure threshold of a fluid, or of air within the flow channel 112 causes. Due to the exceeding of the desired pressure threshold of in the pressure indicator 100 , or in the flow channel 112 Air, is such a force on the pressure element 106 is applied so that it is transferred to the second state and the cavity 122 is arranged in a closed state. By closing the cavity 122 no light passes through the cavity 122 Through and in consequence, the closed state of the pressure indicator can be 106 through the viewing aperture 108 (not shown) from the outside by a user visually check. All other features of the present 2 B correspond in an identical way with the features of the 2a , A repeated description of the identical features is omitted here.

The 3a shows a cross-sectional view of a pressure indicator 100 in the first state. The pressure indicator 100 is located inside the flow channel 112 in the case 102 of the pressure indicator 100 , where the collar 124 of pressure indicator 100 for optimum fit within the housing 102 provides. By the pressure element 106 , or through its central arrangement, the flow channel 112 divided. The division of the flow channel 112 ensures an optimal flow around the pressure element 106 , whereby a uniform force on the elliptical cross section (not shown) of the pressure element 106 is possible. The pressure element 106 is in the first state in a non-deformed configuration, whereby the cavity 122 is completely open and a visual check through the cover 110 over the sight opening 108 is possible. The visual inspection can be done from two opposite sides.

The 3b shows a cross-sectional view of a pressure indicator 100 in the second state, in which the cavity 122 by the deformation of the pressure element 106 is closed. Due to the exceeding of a desired pressure load threshold of the flow channel 112 flowing air becomes the pressure element 106 deformed so elastically that the cavity 122 within the printing element 106 closes. As a consequence, the closed state of the cavity 122 can be checked visually through the cover 110 and through the viewing aperture 108 through. Thus, for a user of the pressure indicator 100 easily verifiable that a critical pressure threshold within the air supply line and thus within the pressure indicator 100 is exceeded.

The 4 shows an exploded perspective view of a pressure indicator 100 , The pressure indicator 100 has the already known housing 102 , which has both a Einströmanschluss 104 as well as a discharge connection 114 having. In addition, the housing includes 102 lateral alignment sections 130 in order to mount the pressure element 106 in the case 102 to ensure optimal alignment. The sight opening 108 includes two separate sections on each side of the housing 102. The viewing port 108 is thus separated by the alignment section 130 and allows a reduced view into the interior of the housing 102 to the state of the pressure element 106 determine. In addition, the shows 4 four covers 110 , which are formed like a lens and an improved verifiability of the state of the printing element 106 within the pressure indicator 100 allow. The pressure element 106 is so in the flow channel 112 of the pressure indicator 100 arranged it by the flow channel 112 formed flowing fluid through. The pressure element 106 includes a rectangular cross-section and has at its ends in each case the collar 124 on. Also in this embodiment, the collar is used 124 an improved fixation of the pressure element 106 in the case 102 of the pressure indicator 100 , As an additional aid to the pressure element 106 opposite the housing 102 To seal improved, is in the housing 102 of the pressure indicator 100 a fixing element 126 arranged. The fixing element 126 is here directly on the pressure element 106 arranged and can thus sealing and fixing on the collar 124 of the printing element 106 act. In addition, both the inflow port 104 and the outflow port are located 114 a sealing element 118 , a hose holder 119 and a hose release device 120 ,

The 5 shows a perspective view of a printing element 106 , Both in the inflow connection 104 as well as in the outlet connection 114 are each a hose holder 119 and a hose release device 120 inserted. The laterally arranged viewing openings 108 are due to the arrangement of the alignment section 130 which extends longitudinally on the outside of the housing 102 located in the middle, split. The alignment section 130 can also be used, for example, to print this example with a logo, symbols or technical information.

The 6a shows a longitudinal sectional view of a pressure indicator 100 in the first state. The pressure indicator 100 includes the housing 102 which the flow channel 112 Are defined. The sealing element 118 , the hose holder 119 and the hose release device 120 are both at the inflow connection 104 as well as at the outlet connection 114 arranged and serve, for example, the connection with an air line or an air hose. The pressure element 106 is inside the case 102 arranged such that the pressure element 106 for fluid passing through the flow channel 112 flows through, can be flowed through. Both Einströmanschlussseitig and Ausströmanschlussseitig is the pressure element 106 by means of a fixing element 126 fixed and sealed in the housing 102. In the area of the pressure element 106 has an inner wall of the housing 102 a concave contour 125 on.

The 6b shows a longitudinal sectional view of a pressure indicator 100 in the second state. The second state is known to be defined by the fact that the cavity 122 by the elastic deformation of the pressure element 106 at least partially completed. The pressure element 106 is in the 6b by exceeding a defined pressure load threshold within the flow channel 112 deformed in a radial direction, thereby forming an outer wall of the pressure element 106 to the concave contour 125 of the housing 102 of the pressure indicator 100 snugly. Through the sight opening 108 (not shown) it is possible to both the deformation on the upper side of the housing 102 as well as the deformation of the pressure element 106 at the bottom of the case 102 visually detect. The sight opening 108 can also consist of several partial openings, wherein the partial openings have different geometries. Thus, one could detect, for example, different pressure levels, which would be visually determined via different partial opening.

The 7a shows a cross-sectional view of a pressure element 106 in the first state. The pressure element 106 has a rectangular cross-section and is adapted to extend from the flow channel 112 starting to deform in the radial direction. Due to the first state, the actual air pressure is within the flow channel 112 below a desired critical pressure threshold, which, in consequence, does not deform the pressure element 106 justified in the first state. Consequently, the cavity is located 122 in an unimpaired condition and a visual inspection by one of the covers 110 allows a clear view through the viewing aperture 108 therethrough. Consequently, a user of the pressure indicator 100 can determine that the pressure conditions within the flow channel 112 at least below the desired specific pressure load. The alignment section 130 divides the viewing apertures 108 centered on each, with each of the viewing openings 108 by means of a transparent cover 110 is closed. The transparent covers 110 could also be designed contiguous on one side of the pressure indicator 100. This would greatly simplify assembly. The inner surfaces of the transparent covers, which the pressure element 106 are facing, arcuately designed so that the pressure element 106 at very high internal pressure within the flow channel 112 can lean against the inner surfaces of the transparent covers. In addition, the appropriately designed surfaces of the covers 110 for refraction of light on the optically dense material of the covers 110 serve. Thus, a better recognizability of the printing element 106 and its condition from a wider angle on the pressure indicator 100 possible.

The 7b shows a cross-sectional view of a pressure indicator 100 in the second state. The pressure element 106 is due to an excess critical pressure load threshold within the flow channel 112 in a deformed state, wherein the upper boundary wall and the lower boundary wall of the pressure indicator 100 deform in the radial direction and to the inner wall of the housing 102 which has a concave contour 125 has (not shown), nestle. The cavity 122 is partially filled in this second state, which is this state on the viewing ports 108 visually check. All other features of 7b correspond identically with the features of Figure 7a and are not described repeatedly at this point.

The 8a shows a side view of the pressure indicator 100 in the first state. The condition of 8a in the present case corresponds to the state which the 7a can be seen. The pressure element 106 is in the first state and thus is not deformed. A visual check of the condition of the printing element 106 is by simple visual inspection through the viewing aperture 108 possible. Due to the undeformed first state of the pressure element 106 can be passed through the viewing opening 108 through the cavity 122 of the pressure indicator 100 look through it completely.

The 8b shows a side view of a pressure indicator 100 in the second state. The condition of the pressure indicator 100 from this 8b corresponds to the state of the pressure indicator 100 according to 7b , Due to the exceeding of the critical pressure threshold in the flow channel 112 is the pressure element 106 in a deformed state, the cavity 122 above and below the pressure element 106 partially filled. During a visual inspection or when looking through the viewing opening 108 , are the deformed areas of the pressure element 106 to see. As a consequence, no light can pass through the viewing aperture 108 through the housing 102 of the pressure indicator 100 penetrate, creating a user of the pressure indicator 100 obtains reliable information that the air pressure within the flow channel 112 has exceeded the specific pressure threshold.

The 9 shows a pressure indicator 100 with a housing 102 and a printing element 106 , In contrast to the previous embodiments, this pressure indicator 100 only one inflow connection 104 on. This pressure indicator 100 can therefore be used particularly well as an end piece of an open air duct. Regarding the function of the pressure indicator 100 exist with respect to the operation of the pressure element 106 but no differences. Due to the elliptical cross-sectional view of the pressure element 106 is the pressure element 106 when exceeding a critical pressure load also formed from the first state to the second state transferable. Also in this embodiment, the pressure element 106 formed elastically deformable and closes in the case of exceeding the critical pressure load the cavity 122 at least partially. The closed state of the cavity 122 As a consequence, analogous to the previous embodiments, it can easily be determined by means of visual visual inspection.

The 10a shows a perspective view of a signal generator 128 , The signal generator 128 is designed as a simple elastically deformable clamp, which laterally into a cavity 122 (not shown) of a printing element 106 can be introduced. If due to the pressure overload within the flow channel 112 (not shown) the pressure element 106 transferred from the first state to the second state, the void-reducing or cavity-reducing force acts on the mutually elastically deformable legs 132 of the signal generator 128 a. By squeezing the thighs 132 of the signaler 128 be two each with the thighs 132 connected and orthogonal to these extending arranged first visible surface 134 and second visible surface 135 shifted relative to each other (see also 11a and 11b ). By moving the first visible surface 134 relative to the second visible surface 135 can be through inspection openings 136 , which only on the first visible surface 134 are located, a view of a signal surface 138 free, which only on the second visible surface 135 is arranged. Consequently, the signal transmitter is located 128 in the 10a in a non-deformed state, which coincides with the first undeformed state of the pressure element 106 corresponds. There are no signal surfaces from the outside 138 visible, noticeable.

The 10b shows the signal transmitter 128 in the deformed state, which corresponds to the deformed second state of the pressure element 106 (not shown) corresponds. The first visible surface 134 is in relation to the second visible surface 135 moved trained and through the viewing openings 136 the first visible surface 134 is a clear and visually undoubted view of the signal surface 138 possible. Thus, this signal generator serves 128 in a simple way of reliably improving the detectability of the state of the printing element 106.

The 10c shows the signal transmitter 128 , which in the cavity 122 of the pressure element 106 is introduced.

The 11a shows a schematic front view of a signal generator 128 which is in the undeformed state and which is in the first state of the pressure element 106 (not shown) corresponds. The mutually elastically deformable legs 132 (not shown) of the signal generator 128 are not pressed together. As a consequence, the first visible surface 134 and the second visible surface 135 not shifted relative to each other.

The 11b shows a schematic front view of a signal generator 128 in a deformed state. The mutually elastically deformable legs 132 of the signaler 128 are compressed and the first visible surface 134 and the second visible surface 135 are shifted relative to each other. By moving the first visible surface 134 relative to the second visible surface 135 lets itself through the view openings 136 , which at the first visible surface 134 are arranged, a look at a signal surface 138 become free, which at the second visible surface 135 is arranged.

All features explained and shown in connection with individual embodiments of the invention may be provided in different combinations in the article according to the invention, in order to simultaneously realize their advantageous effects.

All method steps may be implemented by means suitable for carrying out the respective method step. All functions performed by objective features may be a method step of a method.

The scope of the present invention is given by the claims and is not limited by the features illustrated in the specification or shown in the figures.

LIST OF REFERENCE NUMBERS

100

pressure indicator

102

casing

104

inflow

106

pressure element

108

view port

110

cover

112

flow channel

114

outflow

116

ventilation opening

118

sealing element

119

hose holder

120

Hose release device

122

cavity

124

collar

125

Concave contour

126

fixing

128

signaler

130

aligner

132

leg

134

First visible surface

135

Second visible surface

136

view port

138

signal area

Claims (19)

Pressure indicator (100) for a fluid, in particular for air, with: a housing (102), at least one inflow port (104) for flowing a fluid into the housing (102) and a pressure element (106) at least partially disposed in the housing (102), the pressure element (106) being movable between a first state wherein the pressure element (106) defines a cavity (122) in the housing (102) and a second state in which the pressure element (106) at least partially fills the cavity (122) is convertible. Pressure indicator (100) for a fluid according to Claim 1 , characterized in that the pressure element (106) is formed elastically deformable. The pressure indicator (100) for a fluid according to any one of the preceding claims, characterized in that the housing (102) comprises at least one viewing aperture (108) to enable a visual determination as to whether the pressure element (106) is in the first state or the second Condition is arranged. Pressure indicator (100) for a fluid according to Claim 3 , characterized in that the pressure element (106) releases the sighting opening (108) in the first state and closes in the second state. Pressure indicator (100) for a fluid, according to Claim 3 or 4 , characterized in that the viewing aperture (108) comprises a transparent cover (110). Pressure indicator (100) for a fluid according to Claim 5 , characterized in that the cover (110) is formed like a lens. Pressure indicator (100) for a fluid according to one of the preceding claims, characterized in that the pressure element (106) is arranged in or on a flow channel (112) of the fluid. Pressure indicator (100) for a fluid according to one of the preceding claims, characterized in that the pressure element (106) has at least one collar (124) in order to arrange the pressure element (106) on the housing (102). Pressure indicator (100) for a fluid according to one of the preceding claims, characterized in that the pressure element (106) is arranged in the flow channel (112) such that it can flow around fluid flowing through the flow channel (112). Pressure indicator (100) for a fluid after Claim 9 , characterized in that the pressure element (106) has an elliptical cross section. Pressure indicator (100) for a fluid according to one of Claims 9 or 10 , characterized in that the cavity (122) is formed within the pressure element (106). Pressure indicator (100) for a fluid according to one of Claims 1 to 8th , characterized in that the pressure element (106) in such a way in the housing (102) is arranged, that the pressure element (106) for a fluid can be flowed through. Pressure indicator (100) for a fluid after Claim 12 , characterized in that the pressure element (106) has a rectangular cross section. Pressure indicator (100) for a fluid according to one of Claims 12 or 13 , characterized in that an inner wall of the housing (102) in the region of the pressure element (106) has a concave contour (125). Pressure indicator (100) for a fluid according to one of Claims 12 to 14 , characterized in that the pressure element (106) is adapted to deform during the transition from the first state to the second state in a radial direction starting from the flow channel (112). Pressure indicator (100) for a fluid according to any one of the preceding claims, characterized in that the pressure indicator (100) comprises a signal generator (128) which is adapted to give a signal by the elastic deformation of the pressure element (106). Pressure indicator (100) for a fluid after Claim 16 , characterized in that the signal generator (128) in the cavity (122) of the pressure element (106) is designed to be insertable. Pressure indicator (100) for a fluid according to any one of the preceding claims, characterized in that the pressure indicator (100) comprises a fixing element (126) to seal the pressure element (106) relative to the housing (102). The pressure indicator (100) for a fluid according to any one of the preceding claims, characterized in that the pressure indicator (100) comprises an alignment section (130) for aligning the pressure element (106) with respect to the housing (102).

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