DE102004044890A1 - Device for determining and / or monitoring at least one process variable of a medium - Google Patents

Abstract

The invention relates to a device for determining and / or monitoring a process variable of a medium, comprising a sensor (1) having a sensor neck (2) and a housing (11) having a housing neck (12). The invention includes that the sensor neck (2) or the housing neck (12) has a radial groove (20) and an axial groove (21) that the housing neck (12) or the sensor neck (2) has a bayonet nose (25), in that there is a latching position in which the bayonet nose (25) can be introduced into the radial groove (20) via the axial groove (21), that the sensor neck (2) has a first retaining element (31), that of the housing neck (12). a second retaining element (32), and in that the first retaining element (31) and the second retaining element (32), in the event that the bayonet nose (25) is located in the radial groove (20), prevent the sensor neck (2 ) and the housing neck (12) against each other are rotatable in the latching position.

Description

The The invention relates to a device for determination and / or monitoring at least one physical or chemical process variable of a Medium, with at least one sensor, which has at least one sensor neck, and with at least one housing, which over at least one housing neck for the connection the sensor with the housing has, where the sensor neck and the housing neck designed and matched to one another that the Sensor neck in the housing neck or that of the housing neck insertable into the sensor neck and wherein the sensor neck and the housing neck are at least in the region in which they can be inserted into each other are, are designed substantially cylindrical. The process variables are For example, it is the level, the pressure, the viscosity, the temperature, the pH or the density e.g. a liquid in a container.

From the applicant becomes measuring instruments for determining the filling level manufactured and sold, in which a microwave signal in Direction of the medium radiated and e.g. from the term of the reflected Signal the level is calculated. Such and many other measuring devices exist at least from the actual measuring sensor, in which, for example Transmitter and receiver are located, and a housing, in the e.g. the transmitter and a display or other communication unit are housed. This modular design of the measuring device allows it, housing and replace the sensor separately. However, it is important that the sensor and housing be well and securely connected. There are several Points to note. For easy interchangeability also on site to ensure, the connection should be as possible easily detachable be. It is also useful if the housing opposite the built-in sensor remains rotatable, so that, for example, the display unit so can be made to be easily accessible to the user. Furthermore, the sensor and the housing via cables and wires with each other connected. Therefore, the connection should be such that the cables are in the assembly not or as possible hardly be twisted against each other. The connection should also be a Sealing of the interior of sensor and housing against environmental influences and across from allow the medium.

According to the prior art, a variant is that, for example, the sensor is inserted into the housing. Through the housing then a threaded screw is screwed against the sensor neck. However, this is often problematic when different materials - such as metal and plastic - are given by the sensor and housing. Furthermore, the transition region sensor housing is usually sealed by an O-ring against the environment and mechanically fixed, for example by a threaded pin. Due to the one-sided pressure of the threaded pin usually forms a leak on the opposite side. Another variant is that the sensor and housing are screwed together by means of threads. However, this does not allow for a quick disconnect and turning may cause difficulties for the cabling. Another variant shows the pending application to the German Patent and Trademark Office under the file number DE 103 16 299.2 the applicant. In this embodiment, the attachment via a clamping ring, which produces a rubbing connection on the full circumference. However, this requires the clamping ring and a union nut as additional components.

The The object of the invention is therefore to secure against unintentional release Connection between sensor and housing to give a twisting of sensor and housing allowed against each other and which is still inexpensive.

The Invention solves the task in that the sensor neck or the housing neck has at least one radial groove and at least one axial groove, that the case neck or the sensor neck has at least one bayonet nose that the radial groove, the axial groove and the bayonet nose are so designed and successive are agreed that there is at least one engagement, at the bayonet nose over the axial groove can be introduced into the radial groove, that the sensor neck, the case neck, the radial groove and the bayonet nose are designed in such a way and on each other are tuned that in the event that the bayonet nose in the Radialnut is located, the sensor neck and the housing neck against each other are rotatable, that the sensor neck at least a first retaining element having the housing neck at least one second retaining element and that the first retaining element and the second retaining element designed and matched to one another such that the first retaining element and the second retaining element in the event that the bayonet nose is located in the radial groove is to prevent the sensor neck and the housing neck against each other in the Snap-in position are rotatable.

The idea of the invention is thus that the housing and the sensor are connected to each other by a kind of bayonet closure. For this, the bayonet nose in the axial groove ("axial" means here in the direction of the longitudinal or symmetry axis of the sensor neck or the housing half Ses) introduced and then in the radial groove ("radial" here is the direction perpendicular to the longitudinal axis understood, which lies on the radius of the cylinder of the sensor or the housing neck) rotated .. About the radial groove then sensor and housing can rotate against each other. For the connection of the two components sensor and housing, there is preferably only one relative engagement position to each other If more axial grooves are provided, ie interruptions of the radial groove for insertion, then there are correspondingly more locking positions. To ensure the safety of the connection, ie to ensure that the sensor can not be unintentionally rotated out of the housing - by the bayonet nose in the axial groove - are two retaining elements - one in the sensor, the other in the housing - provided, which prevent the latching position can be taken when the bayonet nose in the If the bayonet lug is not in the radial groove, ie if the sensor and the housing are not connected to each other, then the latching position can be assumed so that such a connection is possible.

The Idea leaves So summarize as follows: The sensor and the housing are over a Bayonet closure connected together and in the event that Both are connected, the relative position of the two parts no longer be taken, in which the closure lifted again would become. Across from the prior art so no other components are required but the sensor neck and the housing neck can be configured directly be that over her the connection possible is. Furthermore, the production is easier, which continues to cost saves.

A Embodiment provides that it is the first retaining element or the second retaining element around a retaining leaf spring is. A leaf spring allows in at least one direction elastic deformation, so that they can be quasi "pushed out of the way" and there is usually at least one direction in which they act as a rigid obstacle element acts (usually the direction perpendicular to the direction of the elastic Deformation). This configuration can therefore be a simpler Allow assembly.

A Embodiment includes that it is in the second retaining element or the first retaining element around a retention nose is. Such a nose or a stamp is a simple element for example, to exert a force on the above leaf spring. Farther let yourself Such a nose already in the production of the corresponding component molding.

A Embodiment provides that the retaining leaf spring and the retaining nose designed and matched to one another such that the retention nose in the event that the sensor neck and the housing neck in the engaged position are so pressed against the retaining leaf spring, that the retention nose the retaining leaf spring at least partially elastically deformed. In the case, then, that sensor and housing are not connected to each other, that is the engagement position still be possible must, is the retaining leaf spring through the retention nose elastically deformed and thus pushed out of the way. Connected with it then also, that the retention nose not at any other position between sensor and housing elastically deformed the leaf spring, but preferably against it abuts and thus a rotation of sensor and housing to each other prevented in the locked position.

A Embodiment provides that the retaining leaf spring and the retaining nose designed in such a way and coordinated with each other that they are in in the event that the bayonet nose is located in the radial groove, prevent the retention nose the retaining leaf spring at least partially elastically deformed. The retention nose can thus in the Case that the bayonet nose has been inserted in the radial groove is, the retaining leaf spring do not deform elastically. Thus, the spring locks the further rotation. Preferably, the rotation is prevented in the angular range, in which the latching position would be achieved.

A Embodiment includes that of the housing neck or the sensor neck has at least two bayonet noses, and that the two angles between the two bayonet noses are different. With the number the bayonet noses also increases the number of axial grooves, i. two bayonet noses are connected with two axial grooves. The more bayonet noses provided are, the more stable the weight of the sensor on the radial groove distributed. The advantage that the angle between the noses is different, lies in the fact that there can be only one engagement position. Would that be Angle identical, so each 180 °, so there would be two engagement positions and both relative settings would need to be protected by the retention elements.

A Embodiment provides that the housing neck or the sensor neck has three bayonet noses, and that at least two angles between each two bayonet noses are different. This is a continuation of above embodiment. Here are three axial grooves required. Two Angles between the noses or groove may be the same, but at least An angle must be different. This brings with it that only one latching position must be "secured" by the retaining elements.

A Embodiment includes that the housing neck and / or the sensor neck Has at least one sealing groove for receiving a sealing ring.

The The invention will be explained in more detail with reference to the following drawings. It shows:

1 FIG. 2: a schematic representation of a part of the sensor of the device according to the invention with sensor neck, FIG.

2 : a schematic representation of the housing of the device according to the invention,

3 : A view of the device in which the sensor is connected to the housing.

1 shows the upper section of the sensor 1 with the sensor neck 2 , The sensor 1 here is generally cylindrical. You can see the radial groove 20 and the axial groove 21 (because in the case neck three bayonet noses 25 are provided, are also in the sensor neck 2 three axial grooves 21 attached), which are both connected to each other - ie there is a continuous path through axial 21 and radial groove 20 - and form part of the bayonet closure. The radial groove 20 located on the outer side of the cylinder jacket of the sensor neck 2 and surrounds the sensor neck 2 Completely. The radial groove 20 So it is perpendicular to the symmetry or longitudinal axis of the sensor 1 , The axial groove 21 runs along the longitudinal axis of the sensor 1 , As can be seen here, it is the axial groove 21 a recess in the upper, ie facing away from the process or the housing facing the boundary portion of the radial groove 20 , Above and below the radial groove 20 are here parallel to her sealing grooves 22 provided in the sealing rings for sealing can be introduced. At the upper section of the sensor neck 2 is in the direction of the longitudinal axis of the sensor 1 the first retaining element 31 attached, which here a retention nose 36 is. The position of the axial groove 21 and the first retaining element 31 are matched to one another such that an insertion of the sensor 1 in the case 11 is possible, and that subsequently by the retaining elements 31 . 32 the unintentional release of the connection is prevented.

2 shows the case 11 , in which usually the evaluation or processing electronics, the power supply, the transmission units, etc. are housed. The sensor neck 2 is in the case neck 12 introduced and connected via the bayonet closure with him. So that both plugged into each other and thus both can be rotated against each other, is the housing neck 12 like the sensor neck 2 likewise cylindrical. Because the sensor 1 and the case 11 directly connected by their special design, no additional component is required. This saves material and also production costs. In the sensor neck 12 Here are two of three bayonet noses 25 to see. At least one of the three angles between the three bayonet noses 25 is preferably different from the other two. In particular, the angles are not 120 ° in each case. This ensures that there is only one latching position over which the sensor 1 and the case 11 to connect with each other or to separate from each other.

In the 3 the state is shown in which the sensor 1 and the case 11 connected to an entire meter. The sensor neck 2 stuck here in the housing neck 12 ; however, it is obvious that a reverse constellation is equally possible. That both components 1 . 11 connected to each other, means that they have been first brought into engagement with each other, and then the bayonet nose 25 over the axial groove 21 in the radial groove 20 has been introduced (therefore plug-in rotary connection). For this to be possible, the first retaining element presses 31 the sensor neck 2 So the retention nose 26 , against the second retaining element 32 of the housing neck 12 , ie against the retaining leaf spring 37 that is shown here. The leaf spring 37 is elastically deformed and thus allows the engagement position to be taken and thereby sensor 1 and housing 11 be connected to each other. The leaf spring 37 is here with a screw on the housing 11 attached, so if necessary removable.

A twisting of the sensor 1 opposite the housing 11 is possible, as far as the radial groove 20 the whole cylinder jacket of the sensor 1 encloses. The extent of twistability thus depends on how large the radial groove 20 is dimensioned. Through the retention nose 36 and the retaining leaf spring 37 however, it prevents sensor 1 and housing 11 be turned into the latching position by the retention nose 36 against the retaining leaf spring 37 pushes and blocks further rotation. Thus, therefore, a rotation is possible, but it is also ensured that it does not unintentionally occupied the locking position and the connection is unintentionally solved.

1

sensor

2

sensor neck

11

casing

12

housing neck

20

radial groove

21

axial groove

22

seal groove

25

Bayonet lug

31

first Retaining element

32

second Retaining element

36

Retention tab

37

Retaining leaf spring

Claims (8)

Device for determining and / or monitoring at least one physical or chemical process variable of a medium, comprising at least one sensor ( 1 ), which via at least one sensor neck ( 2 ) and at least one housing ( 11 ), which via at least one housing neck ( 12 ) for the connection of the sensor ( 1 ) with the housing ( 11 ), wherein the sensor neck ( 2 ) and the housing neck ( 12 ) are designed and matched to one another such that the sensor neck ( 2 ) in the housing neck ( 12 ) or that the housing neck ( 12 ) in the sensor neck ( 2 ) is insertable, and wherein the sensor neck ( 2 ) and the housing neck ( 12 ) at least in the region in which they are insertable into each other, are substantially cylindrical, characterized in that the sensor neck ( 2 ) or the housing neck ( 12 ) at least one radial groove ( 20 ) and at least one axial groove ( 21 ), that the housing neck ( 12 ) or the sensor neck ( 2 ) at least one bayonet nose ( 25 ), that the radial groove ( 20 ), the axial groove ( 21 ) and the bayonet nose ( 25 ) are designed and matched to one another such that there is at least one latching position in which the bayonet nose ( 25 ) via the axial groove ( 21 ) in the radial groove ( 20 ) can be introduced, that the sensor neck ( 2 ), the housing neck ( 12 ), the radial groove ( 20 ) and the bayonet nose ( 25 ) are designed and matched to one another such that in the event that the bayonet nose ( 25 ) in the radial groove ( 20 ), the sensor neck ( 2 ) and the housing neck ( 12 ) are rotatable relative to each other, that the sensor neck ( 2 ) at least one first retaining element ( 31 ), that the housing neck ( 12 ) at least one second retaining element ( 32 ), and that the first retaining element ( 31 ) and the second retaining element ( 32 ) are designed and matched to one another such that the first retaining element ( 31 ) and the second retaining element ( 32 ) in the case that the bayonet nose ( 25 ) in the radial groove ( 20 ) prevents the sensor neck ( 2 ) and the housing neck ( 12 ) are rotatable against each other in the latching position. Apparatus according to claim 1, characterized in that it is in the first retaining element ( 31 ) or the second retaining element ( 32 ) around a retaining leaf spring ( 37 ). Apparatus according to claim 1, characterized in that it is in the second retaining element ( 32 ) or the first retaining element ( 31 ) around a retention nose ( 36 ). Device according to claim 2 and 3, characterized in that the retaining leaf spring ( 37 ) and the retention nose ( 36 ) are designed and matched to one another such that the retention nose ( 36 ) in the case that the sensor neck ( 2 ) and the housing neck ( 12 ) are in the latched position, in such a manner against the retaining leaf spring ( 37 ) expresses that the retention nose ( 36 ) the retaining leaf spring ( 37 ) at least partially elastically deformed. Device according to claim 4, characterized in that the retaining leaf spring ( 37 ) and the retention nose ( 36 ) are designed and matched to one another in such a way that, in the event that the bayonet nose ( 25 ) in the radial groove ( 20 ) prevents the retention nose ( 36 ) the retaining leaf spring ( 37 ) at least partially elastically deformed. Apparatus according to claim 1, characterized in that the housing neck ( 12 ) or the sensor neck ( 2 ) at least two bayonet noses ( 25 ), and that the two angles between the two bayonet lugs ( 25 ) are different. Apparatus according to claim 1, characterized in that the housing neck ( 12 ) or the sensor neck ( 2 ) three bayonet noses ( 25 ), and that at least two angles between each two bayonet lugs ( 25 ) are different. Apparatus according to claim 1, characterized in that the housing neck ( 12 ) and / or the sensor neck ( 2 ) at least one sealing groove ( 22 ) for receiving a sealing ring.