DE102019209030B3 - Pressure sensor device - Google Patents

Abstract

The present invention relates to a pressure sensor device (1) for measuring a pressure, with a cylindrical housing (2), with a pressure sensor (4) which has sensor contacts (13) and is inserted into the housing (2) and with evaluation electronics (6 ), which has evaluation contacts (7). An inexpensive and compact structure results from a holder (5) which is inserted into the housing (2), which has a sensor receptacle (19) on its inside (18), on or in which the pressure sensor (4) is arranged. The holder (5) has on its outside (20) an electronics receptacle (21) on or in which the evaluation electronics (6) are arranged. The holder (5) has several connection openings (22), which open on the one hand to the sensor receptacle (19) and on the other hand to the electronics receptacle (21), an electrically conductive contact element (23) being arranged in at least one of the connection openings (22), which is applied on the one hand to a sensor contact (13) and on the other hand to an evaluation contact (7).

Description

The present invention relates to a pressure sensor device for measuring a pressure with the features of the preamble of claim 1.

Pressure measurements are required in many areas of technology. In most cases, a pressure has to be measured in a space or in a fluid that is located in said space. Pressure sensors are used here. In order to be able to easily mount the respective pressure sensor at a pressure measuring point or measuring point at which the pressure is to be recorded, a pressure measuring device can be provided which comprises a housing and a pressure sensor which is accommodated in the housing. Depending on the medium or fluid whose pressure is to be recorded, more or less effort has to be made to prevent leakage within the housing and / or contamination or contamination of electronics on the pressure sensor or in the housing. These requirements increase the manufacturing costs and in particular make series production more difficult.

A generic pressure sensor device is, for example, from DE 10 2010 061 322 A1 known. It comprises a cylindrical housing, a pressure sensor which is inserted into the housing, and a holder which is inserted into the housing, the pressure sensor having a sensor circuit with sensor contacts and a sensor body with an annular area and with a membrane area, the housing having a Has pressure measurement opening which opens on the one hand inside the housing on the membrane area and on the other hand opens out on the housing, and wherein the holder has a sensor receptacle on its inside facing the pressure measurement opening on which the pressure sensor is arranged. In the known pressure sensor device, the holder is designed as a cylindrical sleeve, on the front edge of which the sensor receptacle is formed by an annular step in which a ring is arranged on which the pressure sensor is axially supported.

The DE 10 2012 210 752 A1 shows another pressure sensor device in which the holder has a through opening through which a contact element rests on a sensor contact that is connected to a connector on the housing.

From the EP 3 128 305 A1 Another pressure sensor device is known in which a ring rests on the pressure sensor, which in turn carries a circuit board which has evaluation electronics with evaluation contacts. The evaluation contacts are electrically connected to the sensor contacts via cables that are passed through a common opening in the board. The known pressure sensor device also has an alignment unit which is arranged in the housing on a side of the board facing away from the pressure sensor and which contains several connection openings in each of which an electrically conductive contact element designed as a spring is arranged. These contact elements rest on the one hand on further contacts of the evaluation electronics and on the other hand against contacts on the housing side which lead out of the housing.

Further pressure sensor devices are from DE 10 2009 027 742 A1 and from the DE 10 2016 203 428 B3 known.

The present invention deals with the problem of specifying an improved or at least a different embodiment for such a pressure measuring device, which is characterized in particular by being inexpensive to manufacture. Furthermore, the pressure sensor device should be suitable for series production. A compact design is also sought.

According to the invention, this problem is solved by the subject matter of the independent claim. Advantageous embodiments are the subject of the dependent claims. The invention is based on the general idea of equipping the pressure sensor device with a holder which is separate with respect to the housing and which is inserted into the housing and which has a sensor receptacle on or in which the pressure sensor is arranged. Furthermore, the holder has an electronics receptacle on or in which evaluation electronics of the pressure sensor device are arranged. In addition, the holder contains several connection openings which open on the one hand to the sensor receptacle and on the other hand to the electronics receptacle. In at least one of these connection openings an electrically conductive contact element is arranged, which represents a separate component with respect to the holder and which is applied on the one hand to a sensor contact of the pressure sensor and on the other hand to an evaluation contact of the evaluation electronics. In this way, with the aid of the holder, a pre-assembly group can be formed which comprises the holder, the evaluation electronics, the pressure sensor and the contact elements. At the same time, the electrical coupling between the evaluation electronics and the pressure sensor or a sensor circuit of the pressure sensor can take place within this pre-assembly group. This pre-assembly group can be inserted into the housing as a unit and fixed therein in a suitable manner. The pressure sensor device presented here has a comparatively simple structure that can be implemented inexpensively and is particularly suitable for series production.

In the present context, the axial direction is defined by the longitudinal center axis of the cylindrical housing. The axial direction extends parallel to the longitudinal center axis of the housing. The radial direction runs perpendicular to the axial direction. The circumferential direction runs around the longitudinal center axis.

According to an advantageous embodiment, the holder can be fixed to the housing by means of a flanged connection or by means of a crimp connection or by means of adhesive bonding. These fastening measures can be implemented particularly easily and thus inexpensively, even in the context of series production.

Another advantageous embodiment provides that the respective contact element rests on the respective sensor contact and on the respective evaluation contact without soldering. In other words, the electrical contacting of the contact elements with the sensor contacts and the evaluation contacts takes place without a soldered connection. As a result, a complex and expensive soldering process can be dispensed with, which simplifies inexpensive series production. In addition, a thermally less stable and thus less expensive material can be used for the holder, such as e.g. a plastic.

The holder can preferably be made of a pressure-resistant plastic so that it acts like an electrical insulator. In contrast to this, the contact elements are designed to be electrically conductive and can in particular consist of a metal.

In another advantageous embodiment, the respective contact element can rest axially pretensioned on the respective sensor contact and on the respective evaluation contact. The axial preload ensures efficient electrical contact and is easy to implement.

For example, according to one embodiment, the respective contact element can be designed as a helical spring. Such a helical spring can be made of metal and accordingly form a relatively good electrical conductor. The helical spring is dimensioned so that it is axially elastically compressed in the assembled state of the aforementioned preassembly assembly or the assembled state of the pressure sensor device, so that in the assembled state it generates the desired axial preload on the respective contact.

Another embodiment provides that the sensor receptacle is designed as a sensor receptacle recess into which the pressure sensor is inserted, preferably axially. As a result, the pressure sensor is positioned radially with respect to the holder.

According to an advantageous development, at least one sensor alignment element can be formed on the sensor receiving recess, which works together with a sensor counter aligning element formed on the pressure sensor, in such a way that the pressure sensor can only be inserted into the sensor receiving recess in a predetermined sensor rotational position between the pressure sensor and the holder, the connection openings in this sensor rotational position are axially aligned with the sensor contacts. This measure allows assembly errors to be avoided, which reduces scrap and thus production costs.

In addition, the sensor alignment element and sensor counter alignment element can also be designed in such a way that the pressure sensor can only be inserted into the sensor receiving recess with its sensor contacts in advance. This measure also prevents incorrect assembly.

According to the invention, the electronics receptacle is designed as an electronics receptacle recess into which the evaluation electronics are inserted, in particular axially. This allows the evaluation electronics to be positioned radially on the holder.

According to an advantageous development, at least one electronics alignment element can be formed on the electronics receptacle recess, which interacts with an electronics counter-alignment element formed on the evaluation electronics, such that the evaluation electronics can only be inserted into the electronics receptacle recess in a predetermined evaluation rotational position between evaluation electronics and holder, in this evaluation rotational position the Connection openings are axially aligned with the evaluation contacts. This measure avoids incorrect assembly, which reduces scrap and thus production costs.

In addition, it can be provided that the electronic alignment element and electronic counter-alignment element are designed in such a way that the evaluation electronics can only be inserted into the electronics receptacle recess with the evaluation contacts in advance. This measure also reduces the risk of incorrect assembly.

The respective sensor alignment element and the associated sensor counter-alignment element can be designed as a tongue and groove connection, which is axially oriented and defines the respective sensor rotational position. Additionally or alternatively, the respective electronics alignment element and the associated counter alignment element can be used as axially oriented groove Be designed spring connection, which is also axially oriented and defines the evaluation rotational position. Only when the tongue is axially aligned with the associated groove is the desired rotational position available and the tongue can be inserted axially into the groove. As a result of an asymmetrical distribution in the circumferential direction of at least two such tongue and groove connections it can also be ensured that the pressure sensor or the evaluation electronics can only be inserted into the associated recess with the correct side first.

Another advantageous embodiment suggests that the housing has an annular sensor recess in the housing interior, which is axially delimited on the housing side by a recess base and into which the pressure sensor is axially inserted with its ring area. The housing can furthermore have a housing projection concentric to the sensor recess, which protrudes axially into the housing interior. The pressure measurement opening of the housing extends through this housing projection, in particular concentrically. A ring seal is arranged radially between the housing projection and the ring area, e.g. an O-ring, this ring seal sealing the pressure sensor radially with respect to the housing. In the sensor recess, a disk seal is now also arranged axially between the ring area and the recess base, which is arranged coaxially to the housing projection and which seals the pressure sensor axially with respect to the housing. In other words, in the embodiment presented here, the pressure sensor is sealed against the housing with the aid of two successive seals, namely with the aid of the ring seal and with the aid of the disk seal. This two-stage seal efficiently seals the inside of the housing, which accommodates the pressure sensor, from the pressure measurement opening through which the pressure measurement device is in contact with the respective fluid whose pressure is to be measured. The double or two-stage sealing means that contamination of the interior of the housing can be efficiently avoided. Of particular importance is the fact that the disk seal limits the volume inside the housing that adjoins the ring seal on a side facing away from the pressure measurement opening to the very small volume between the ring seal and the disk seal. As a result, an axial movement of the ring seal in the event of negative pressure pulses that are transmitted through the pressure measurement opening to the interior of the housing can be reduced. The fact that, in the event of a leak at the ring seal, the disk seal still seals the rest of the housing interior with respect to the pressure measurement opening is also advantageous. Such a leak at the ring seal can e.g. come when a strong negative pressure pulse is followed by an overpressure pulse. The negative pressure pulse can move the ring seal axially in the direction of the membrane area, in individual cases so far that the ring seal no longer rests completely on the ring area of the sensor and / or on the projection of the housing. A subsequent overpressure pulse can move the ring seal back into the correct position, but at the same time a small amount of the respective fluid can flow past the ring seal. At the latest at the disk seal, this fluid can then no longer flow, so that the rest of the housing interior is protected from contact with the fluid and from contamination carried along therein. Furthermore, the disk seal, which is expediently made of an elastic plastic, can simplify assembly, since it helps prevent damage to the pressure sensor when it is inserted into the housing. The sensor body can usually be made from a ceramic. The sensor body with its ring area and the membrane area is preferably a monolithic ceramic body. If this ceramic body comes into direct contact with the usually metallic housing, the ceramic can be damaged when subjected to pressure. By arranging the elastic disk seal axially between the housing and the sensor body, such direct contact and thus damage to the pressure sensor can be avoided.

Another advantageous embodiment provides that the pressure sensor device also has a separate electrical connection with respect to the housing, which is inserted into the housing so that the electrical connection connects to the holder on a side facing away from the pressure sensor and rests against it. The electrical connection can now have an external interface for the transmission of electrical signals and electrical power on its outside facing away from the holder. Furthermore, on its inside facing the holder, the electrical connection can have an internal interface which is electrically coupled to the external interface for transmitting electrical signals and electrical power and which is electrically coupled to an evaluation interface of the evaluation electronics that is complementary thereto. Thus, the evaluation electronics and also the sensor circuit can be supplied with electrical power via the electrical connection. At the same time, the measured values for the respective pressure determined with the help of the evaluation electronics can be read out or transmitted to the outside in the form of corresponding signals via the electrical connection. The internal interface and the external interface of the electrical connection are then expediently electrically coupled to one another via corresponding electrical lines running in a body of the electrical connection. Said body of the electrical connection can for example consist of a be formed pressure-stable plastic, which represents an electrical insulator.

The internal interface and the evaluation interface are expediently contacted without soldering, e.g. via spring-loaded contact pins or the like. Thus, the electrical connection can also be made from a plastic and thus inexpensively.

According to an advantageous development, the electrical connection can be fixed to the housing by means of a crimped connection or by means of a crimp connection or by means of gluing and thereby fix the holder axially in the housing. This fixation can also be implemented easily and thus inexpensively. It is also suitable for series production. The respective connection technology fixes the electrical connection directly to the housing, while the respective connection technology in this case fixes the holder indirectly, namely via the electrical connection on the housing.

Another advantageous embodiment proposes that the housing in the area of the pressure measurement opening has on its axial outside an axially protruding pressure connection area integrally formed on the housing, through which the pressure measurement opening extends, in particular concentrically. This pressure connection area can in principle be designed as a pressure measurement connection or have one.

However, an embodiment is preferred in which the pressure measuring device is also equipped with an adapter which has a pressure connection receptacle complementary to the pressure connection area, a pressure measurement connection and a connecting channel. This connection channel creates a fluidic connection between the pressure connection receptacle and the pressure measurement connection within the adapter. With respect to the housing, the adapter represents a separate component that can be attached to the housing. In the installed state, the adapter is arranged on the outside of the housing in such a way that the pressure connection area is inserted into the pressure connection receptacle and the pressure measurement opening is fluidically connected to the pressure measurement connection through the connection channel.

By using such a separate adapter, the pressure measuring device can be adapted particularly easily to different pressure measuring points by using an adapter suitable for the respective pressure measuring point. The different adapters then differ in terms of different configurations of the pressure measurement connection. However, the different adapters are designed essentially identically with regard to their coupling to the housing, so that the pressure measuring device can be designed identically for a large number of different applications apart from the adapter. The unit costs can be reduced by increasing the number of items, so that this embodiment is also particularly suitable for series production.

In principle, the respective adapter can be attached to the housing in a detachable and thus exchangeable manner. For this, however, a great deal of effort is required to achieve a reliable and permanent seal. An embodiment is therefore preferred in which the adapter is permanently attached to the housing. In the present context, a non-detachable connection is understood to be a connection in which the separation of the two connection partners is usually accompanied by the destruction of at least one of the connection partners. In the present case, the adapter and / or the housing would be damaged if the adapter were separated from the housing, as a result of which the adapter or the housing or both would / would be unusable.

The adapter and the housing are separate components, which, however, are securely attached to one another in a suitable manner. For this permanent connection between the adapter and the housing, connection techniques can be used which enable permanent tightness and which can be implemented inexpensively. For example, the adapter and housing can be glued together. In addition, a screw connection can be formed between the adapter and the housing for increased stability. In addition, a conical engagement at the transition between the connecting channel and the pressure measurement opening can be formed for the increased tightness.

Further important features and advantages of the invention emerge from the subclaims, from the drawings and from the associated description of the figures on the basis of the drawings.

It goes without saying that the features mentioned above and those yet to be explained below can be used not only in the respectively specified combination, but also in other combinations or alone, without departing from the scope of the present invention.

Preferred exemplary embodiments of the invention are shown in the drawings and are explained in more detail in the following description, with the same reference symbols referring to the same or similar or functionally identical components.

• 1 einen Längsschnitt einer Druckmesseinrichtung bei einer ersten Ausführungsform,
• 2 ein vereinfachter Längsschnitt der Druckmesseinrichtung aus 1 in einer auseinander gezogenen Darstellung,
• 3 ein Längsschnitt der Druckmesseinrichtung, jedoch bei einer zweiten Ausführungsform,
• 4 ein Längsschnitt der Druckmesseinrichtung aus 3 in einer auseinander gezogenen Darstellung,
• 5 ein vergrößertes Detail V aus 3,
• 6 eine Seitenansicht eines Adapters bei drei verschiedenen Ausführungsformen A, B und C,
• 7 eine Axialansicht auf eine Außenseite eines Halters der Druckmesseinrichtung,
• 8 eine Axialansicht auf eine Innenseite des Halters,
• 9 eine Axialansicht auf eine Innenseite einer Auswerteelektronik der Druckmesseinrichtung, und
• 10 eine Axialansicht auf eine Innenseite eines Drucksensors der Druckmesseinrichtung.

They show, each schematically,

• 1 a longitudinal section of a pressure measuring device in a first embodiment,
• 2 a simplified longitudinal section of the pressure measuring device 1 in an exploded view,
• 3 a longitudinal section of the pressure measuring device, but in a second embodiment,
• 4th a longitudinal section of the pressure measuring device 3 in an exploded view,
• 5 an enlarged detail V. 3 ,
• 6th a side view of an adapter in three different embodiments A, B and C,
• 7th an axial view of an outside of a holder of the pressure measuring device,
• 8th an axial view of an inside of the holder,
• 9 an axial view of an inside of an electronic evaluation system of the pressure measuring device, and
• 10 an axial view of an inside of a pressure sensor of the pressure measuring device.

According to the 1 to 4th comprises a pressure measuring device 1 , which is suitable and intended for measuring a pressure, a cylindrical housing 2 , which has a longitudinal central axis 3 which defines an axial direction which is parallel to the longitudinal central axis 3 runs. A radial direction extends perpendicular to the axial direction. A circumferential direction runs around the longitudinal center axis 3 around. In the 1 to 6th the axial direction extends parallel to the plane of the drawing. In the 7th to 10 the axial direction extends perpendicular to the plane of the drawing.

The pressure sensor device 1 also includes a pressure sensor 4th that is in the case 2 is inserted, as well as a holder 5 , which is also in the housing 2 is used, and evaluation electronics 6th that have multiple evaluation contacts 7th having. The cutting plane in the 1 to 4th runs only through an evaluation contact 7th . The remaining evaluation contacts 7th lie behind or in front of the cutting plane. In particular, according to 9 these evaluation contacts 7th be arranged in a straight line next to each other. The evaluation electronics 6th has at least one electronic component 8th , that in a suitable way with the evaluation contacts 7th is electrically coupled. The evaluation electronics 6th also includes a circuit board here 9 , which are the evaluation contacts 7th and the component 8th wearing. The component 8th is here as well as the evaluation contacts 7th on one the pressure sensor 4th facing inside 10 the evaluation electronics 6th or the board 9 arranged. In the example of 9 are exactly five evaluation contacts 7th shown. It is clear that there are basically more or less than five evaluation contacts 7th could be.

The pressure sensor 4th has a sensor circuit 11 on, in particular on one of the evaluation electronics 6th facing inside 12th of the pressure sensor 4th can be printed. The sensor circuit 11 has multiple sensor contacts 13 on. In the cutting planes of the 1 to 5 is only one such sensor contact 13 recognizable. The other sensor contacts 13 are arranged behind or in front of this cutting plane. In particular, according to 10 the sensor contacts 13 in a straight line next to each other at the pressure sensor 4th be arranged. The pressure sensor 4th also has a sensor body 14th on, the one ring area 15th and a membrane area 16 owns. The ring area 15th is concentric in the housing 2 arranged and carries the membrane area 16 . The sensor circuit 11 is on the membrane area 16 arranged, in particular printed thereon. Appropriately, it is the sensor body 14th around a ceramic monolith. In the example of 10 are exactly five sensor contacts 13 shown. It is clear that there are basically more or less than five sensor contacts 13 could be. The number of sensor contacts is preferred 13 same as the number of evaluation contacts 7th .

The case 2 is with a pressure measurement port 17th equipped, the one hand inside the case 2 on the membrane area 16 opens and on the other hand on an outside of the housing 2 flows out. Via this pressure measurement opening 17th a pressure that prevails in a fluid or in a room reaches the respective measuring point up to the membrane area 16 which then deforms elastically depending on the pressure. This deformation can be caused by the sensor circuit 11 converted into an electrical voltage. For example, the sensor circuit 11 have a bridge circuit made up of several strain gauges. These voltage signals, which correlate with the pressure, can be read with the aid of the evaluation electronics 6th evaluated and converted into corresponding pressures and provided as corresponding pressure signals.

The holder 5 points at its the pressure measurement port 17th facing inside 18th a sensor holder 19th on, at or in which the pressure sensor 4th is arranged. Furthermore, the holder 5 at his from the pressure measurement port 17th facing away from the outside 20th an electronics recording 21st on, on or in which the evaluation electronics 6th is arranged. The holder also contains 5 several connection openings 22nd on the one hand at the sensor mount 19th and on the other hand on the electronics mount 21st flow out. In the cutting planes of the 1 to 5 is only one such connection opening 22nd recognizable. The other connection openings 22nd lie in front of or behind this cutting plane. Appropriately, according to the 7th and 8th the connection openings 22nd be arranged side by side along a straight row. In the example of 7th and 8th are exactly five connection openings 22nd shown. It is clear that there are basically more or less than five communication openings 22nd could be. The number of connection openings is preferred 22nd equal to the number of sensor contacts 13 and / or the same as the number of evaluation contacts 7th .

In at least one of these connection openings 22nd is an electrically conductive contact element 23 arranged, the one hand on such a sensor contact 13 and on the other hand such an evaluation contact 7th is applied so that the respective sensor contact 13 via the contact element 23 electrically conductive with the respective evaluation contact 7th connected is. It is useful for each sensor contact 13 a connection opening 22nd with contact element 23 provided to each sensor contact 13 with an associated evaluation contact 7th to connect electrically. In the example of 7th to 10 are then five connection openings 22nd and five contact elements 23 intended.

According to 1 can the holder 5 on the housing 2 directly by means of a flange connection 24 or crimp connection 24 be fixed. It is also conceivable to use the holder 5 by means of gluing on the housing 2 to fix. For the flare connection 24 is in 1 a front edge 25th of the housing 2 reshaped so that the reshaped edge is the outside 20th of the holder 5 overlaps radially. The beaded or crimped edge 25th is in 1 shown with broken line. The edge, on the other hand, has a continuous line 25th shown before the forming process.

The respective contact element can preferably 23 at the respective sensor contact 13 and at the respective evaluation contact 7th lie loosely, in particular without soldering and / or axially pretensioned. The contact element 23 by a coil spring 26th be educated. The associated connection opening can be used to simplify assembly 22nd a holding section at least in one longitudinal section, that is to say either over its entire axial length or only over part of its axial length 27 form, which is characterized by a, in particular reduced, cross section, such that therein a certain axial fixation of the contact element 23 inside the connection opening 22nd enables. The fixation takes place via frictional engagement, so that the contact element 23 for example for installation in the connection opening 22nd can be inserted and properly axially positioned therein, in particular such that the contact element 23 at both axial ends axially out of the connection opening 22nd protrudes.

In the embodiments shown here of the 1 to 5 and 8th is the sensor mount 19th as an axial sensor recess 28 configured in which the pressure sensor 4th with the membrane area 16 is previously inserted axially. At this sensor recess 28 can at least one sensor alignment element 29 be designed with a pressure sensor 4th trained sensor counter-alignment element 30th cooperates. In the 1 to 4th is such a bar-shaped or rib-shaped sensor alignment element 29 recognizable and in the 1 and 3 is such a sensor counter-alignment element 30th recognizable, for example, a notch or groove on the circumference of the pressure sensor 4th can be. In 8th are purely by way of example three sensor alignment elements, distributed in the circumferential direction and designed as ribs or springs 29 shown. In 10 are suitable for this purely by way of example three sensor counter-aligning elements, distributed in the circumferential direction and designed as grooves 30th shown. In particular, sensor alignment elements 29 and sensor counter alignment element 30th form a tongue and groove connection which is axially aligned. In any case, sensor alignment elements act 29 and sensor counter alignment element 30th together so that the pressure sensor 4th only in a pre-determined sensor rotation position between the pressure sensor 4th and holder 5 into the sensor recess 28 can be used axially. The connection openings are in this rotational position of the sensor 22nd axially on the sensor contacts 13 aligned. Through the in the 8th and 10 shown, with respect to the circumferential direction uneven distribution of the sensor alignment elements 29 and the sensor counter-alignment elements 30th the pressure sensor 4th also only with the sensor contacts 13 ahead into the sensor recess 28 deploy.

Furthermore, according to the 1 to 4th and 7th be provided that the electronics receptacle 21st as an axial electronics recess 31 is designed in which the evaluation electronics 6th is inserted axially. Appropriately, this electronics receptacle recess 31 Electronics alignment elements 32 be designed, each with one on the evaluation electronics 6th trained electronics counter alignment element 33 work together. Electronics alignment element can also be used here 32 and electronics counter alignment element 33 form an axial tongue and groove connection. In the 1 to 4th and 7th are several electronic alignment elements designed as longitudinal webs or springs 32 recognizable. In 1 , 3 and 9 are several electronic counter-alignment elements designed as a suitable groove 33 recognizable. In 7th are purely by way of example three electronics alignment elements distributed in the circumferential direction and designed as ribs or springs 32 shown. In 9 are suitable, purely by way of example, three circumferentially distributed and designed as grooves Electronic counter alignment elements 33 shown. The at least one electronics alignment element expediently act 32 and the at least one electronic counter alignment element 33 together in such a way that the evaluation electronics 6th only in a predetermined evaluation rotational position between evaluation electronics 6th and holder 5 into the electronics receptacle 31 can be used. The connection openings are in this evaluation rotational position 22nd axially on the evaluation contacts 7th aligned. Through the in the 7th and 9 shown, with respect to the circumferential direction uneven distribution of the electronic alignment elements 32 and the electronic counter alignment elements 33 the evaluation electronics 6th also only with the evaluation contacts 7th advance into the electronics receptacle 31 deploy.

The two embodiments described above are expediently combined with one another, so that the pressure sensor 4th and the evaluation electronics 6th just like that on the holder 5 let assemble that then the connection openings 22nd axially to the sensor contacts 13 and the evaluation contacts 7th are aligned. This enables reliable contacting through the contact elements 23 be improved.

In the embodiments shown here, the housing has 2 a ring-shaped sensor recess inside the housing 34 , which on the housing side through a recess base 35 is axially limited. In this sensor recess 34 is the pressure sensor 4th with its ring area 15th inserted axially. Concentric to this sensor recess 34 has the housing 2 a housing projection 36 which protrudes axially into the housing interior. As a result, the housing protrusion protrudes 36 also in the ring area 15th of the pressure sensor 4th enclosed interior 37 inside. It is important that the housing protrusion 36 the membrane area 16 not touched, but an axial distance 38 owns. The pressure measurement port 17th extends concentrically through the housing projection 36 through. Furthermore, it is now radial between the housing projection 36 and the ring area 15th a ring seal 39 arranged that the pressure sensor 4th opposite the housing 2 radial seals. For this purpose, the housing projection 36 appropriately a ring stage 40 on which the ring seal 39 is attached. It is expedient to use the ring seal 39 around an O-ring.

Furthermore, in the sensor recess 34 axially between the ring area 15th and the recess bottom 35 a washer seal 41 be arranged, the coaxial to the housing projection 36 is arranged and which the pressure sensor 4th opposite the housing 2 axially seals. The disc seal 41 is therefore designed in a ring shape and differs from the ring seal 39 a flat cross-sectional profile and thereby enables an axial flat contact on the ring area 15th and at the bottom of the recess 35 .

The pressure sensor 4th is supported axially by the disc seal 41 on the housing 2 from. The disc seal 41 also improves the protection of the interior of the housing from contamination via the pressure measurement opening 17th can be fed. In the event of a strong negative pressure pulse, the ring seal 39 from the ring stage 40 lift off axially and up to the membrane area 16 arrive, whereby the sealing effect against the projection 36 is impaired. If an overpressure pulse now follows, fluid can flow from the pressure measurement opening 17th on the ring seal 39 over into an annulus 42 enter, which is at one of the pressure measurement opening 17th facing away from the ring seal 39 connects. This annulus 42 however, is through the washer seal 41 limited and separated from the rest of the housing interior. This means that impurities cannot get into the rest of the housing interior.

In the example of 1 and 2 is the holder 5 directly through the flared or crimp connection 24 on the housing 2 fixed. In the 2 and 4th The embodiment shown is used to fix the holder 5 on the housing 2 indirectly, namely with the help of an electrical connection 43 , which in this embodiment of the 3 and 4th is also optionally available. It is clear that this electrical connection 43 also in the 1 and 2 Can be realized embodiment shown.

The electrical connection 43 is in the housing 2 inserted axially in such a way that the electrical connection 43 on one of the pressure sensor 4th facing away from the holder 5 connects and in particular rests directly on it. The electrical connection 43 points to his from the holder 5 facing away from the outside an external interface 44 which is designed to transmit electrical signals and electrical power. Furthermore, the electrical connection 43 at his the holder 5 facing inside an internal interface 45 on that in an appropriate manner with the external interface 44 is electrically coupled. For example, this can be done in a body 46 of the electrical connection 43 corresponding electrical conductors (not shown) run. The internal interface 45 is with a complementary evaluation interface 47 the evaluation electronics 6th coupled. For example, the internal interface 45 for this purpose, springs or spring-loaded contact pins which are connected to corresponding contact points of the evaluation electronics 6th for example on the circuit board 9 are provided, get in touch. Here, too, the electrical contact is expediently made between the internal interface 45 and the evaluation interface 47 the evaluation electronics 6th solderless.

In the example of 3 is the electrical connection 43 by means of a flange or crimp connection 24 on the housing 2 fixed. This becomes the holder 5 in the housing 2 axially fixed. In 4th is the edge 25th of the housing 2 shown already in the formed state; it is clear that the holder 5 and the electrical connection 43 just before reshaping the edge 25th in the housing 2 can be used. The electrical connection 43 can with an additional ring seal 48 opposite the housing 2 be sealed. This additional ring seal 48 can do this in a circumferential annular groove 49 used on the electrical connection 43 is trained.

According to the embodiments of 1 to 4th can the housing 2 in the area of the pressure measurement opening 17th an axially protruding pressure connection area on its axial outside 50 exhibit. Through this integral to the housing 2 molded pressure connection area 50 the pressure measurement opening extends 17th through, preferably concentrically. In the example of 1 and 2 is this pressure connection area 50 as a pressure measurement connection 53 ' designed in the manner of a connection piece, which can be inserted axially into a matching receiving opening at the respective measuring point.

The 3 to 6th show another embodiment in which the pressure measuring device 1 additionally with an adapter 51 is equipped with respect to the housing 2 represents a separate component. This adapter 51 has one to the pressure connection area 50 complementary pressure connection 52 . The adapter also has 51 a pressure measurement connection 53 and a connecting channel 54 , the pressure measurement connection 53 with the pressure connection holder 52 fluidly connects, at least when the adapter 51 as in 4th not to the housing 2 connected. However, is the adapter 51 like in the 3 and 5 on the outside of the case 2 The pressure connection area is properly arranged 50 into the pressure connection receptacle 52 used. The result is the pressure measurement port 17th through the connecting channel 54 with the pressure measurement connection 53 fluidically connected. The pressure measuring device 1 can now with the help of the adapter 51 via its pressure measurement connection 53 be attached to the desired measuring point. Via the pressure measurement connection 53 the pressure to be measured is tapped, i.e. the pressure to be measured passes through the connecting channel 54 and the pressure measurement port 17th up to the membrane area 16 .

The two embodiments of the 1 and 2 one hand and the 3 and 4th on the other hand, they can be combined as desired. Accordingly, the in 1 and 2 Shown embodiment with the electrical connection 43 and / or instead of the integrated pressure measurement connection 53 ' the attached adapter 51 exhibit. The embodiment of 3 and 4th without the electrical connection 43 and / or without the adapter 51 will be realized.

The adapter is useful 51 In the examples shown here, it cannot be removed from the housing 2 attached. That means that the adapter 51 not from the housing 2 can be separated without causing more or less serious damage to the adapter 51 and / or the housing 2 comes. As a rule, at least one connection partner becomes unusable, in particular both connection partners become unusable.

For example, the pressure connection area 50 an axial cylindrical recess 55 have, suitably concentric on the housing 2 is arranged. On the adapter 51 a complementary adapter projection is useful 56 formed in the recess 55 engages axially. The connecting channel 54 extends axially through the adapter projection 56 through, appropriately concentric. Furthermore, an axially acting O-ring 57 axially between the adapter projection 56 and the deepening 55 be used. For example, this can be done axially on the end face of the adapter projection 56 a corresponding ring groove 58 be formed in which the O-ring 57 is used. Alternatively, the ring groove 58 also in the recess 55 be formed, or partially in the adapter projection 56 and partly in the recess 55 . In any case, the O-ring seals 57 the adapter 51 opposite the housing 2 from.

The pressure connection area 50 can be an external thread 59 exhibit. The pressure connection receptacle 52 can have a complementary internal thread 60 exhibit. Thus, the adapter 51 on the pressure connection area 50 of the housing 2 unscrew. The pressure connection area 50 can be at the transition between the external thread 59 and the rest of the case 2 a notch or throat 77 have, which can be designed in particular as a predetermined breaking point, so that the entire pressure connection area 50 from a predetermined failure torque from the rest of the housing 2 breaks off.

In the adapter 51 can between the pressure connection area 50 and the pressure connection receptacle 52 an annulus 61 be designed in the fully assembled state of the adapter 51 from an adhesive 62 is filled out. The adhesive 62 can before screwing on the adapter 51 into the pressure connection receptacle 52 introduced and / or on the pressure connection area 50 be applied. It is also conceivable to use the adhesive 62 over at least one adhesive filler opening 63 in the annulus 61 to fill in the in 3 indicated by a broken line when the adapter 51 already on the housing 51 is mounted. This adhesive filler opening is in the fully assembled state 63 from the glue 62 filled in and thus tightly closed. The additional between the pressure connection area 50 and pressure connection 52 formed adhesive connection can be a torque required to loosen the screw connection between the adapter 51 and housing 2 is required, increase so that it exceeds the failure torque mentioned above. As a result, the pressure connection area breaks 50 when trying to use the adapter 51 from the housing 2 unscrew, off. This will make the adapter 51 with the pressure connection area glued in 50 and the case 2 with broken pressure connection area 50 unusable.

How in particular 5 can be removed, the connection channel 54 via a conical engagement 64 into the pressure measurement opening 17th pass over. This conical engagement 64 can have an axially protruding cone 65 and a complementary seat 66 have in which the cone 65 engages axially. The seat 66 can also be conical or rounded like a torus section. In the example of 3 to 5 is the cone 65 on the adapter projection 56 , so on the adapter 51 trained while the seat 66 inside the recess 55 , i.e. at the pressure connection area 50 or on the housing 2 is trained. It is clear that in another embodiment the cone 65 also on the housing 2 can be formed while then the seat 66 on the adapter 51 is trained.

The aforementioned sealing measures, namely O-ring, are preferred 57 , conical engagement 64 and glue 62 , as well as the aforementioned fastening measures, namely screwing and gluing cumulative for use, creating a permanent connection between the adapter 51 and housing 2 is created, which is characterized by a permanent and efficient tightness.

In the embodiment presented here, the 3 to 5 is the annulus 61 through an annular axial gap 72 formed axially between an end face 73 of the ring-shaped pressure connection area here 50 and a floor 74 the electrical connection recording 52 is formed, the bottom 74 here is also designed ring-shaped. The axial gap 72 is defined by having an axial height 75 of the adapter projection 56 is greater than an axial depth 76 the deepening 55 in the pressure connection area 50 . The height 75 is doing this from the ground 74 measured. The depth 76 is up to the front 73 measured.

By using the adapter 51 it is possible for the pressure measuring device 1 to create different embodiments that are suitable for different measuring points without the entire pressure measuring device 1 needs to be adjusted. To adapt to different measuring points, you only need to adapt the adapter 51 required. In addition, the entire pressure measuring device 1 remain identical. Accordingly, for the pressure measuring device presented here 1 a kit can be provided which can be used to manufacture different pressure measuring devices 1 suitable. This kit includes the pressure measuring devices 1 who still do not have an adapter 51 are provided. The kit also includes several different adapters 51 through different pressure measurement connections 53 differ from each other.

In the 6A , 6B and 6C are purely exemplary side views of different adapters 51 reproduced. The different adapters are noticeably different 51 only through different pressure measurement connections 53 from each other, which for clarification also with 53A , 53B and 53C are designated. The adapters can be seen 51 an outer polygon on its outer contour 79 have, which simplifies the introduction of a predetermined tightening torque for the screw connection.

Depending on the respective use of the pressure measuring device 1 the suitable adapter can now 51 selected and on the case 2 are attached, so that a pressure measuring device adapted for the respective application 1 with adapter 51 present.

Provided this washer seal mentioned above 41 is used, it can be provided according to an advantageous embodiment that the holder 5 a sensor support surface 67 has at which the pressure sensor 4th is axially supported. In the examples shown here, the sensor support surface is located 67 in the sensor holder 19th or in the sensor recess 28 . The case 2 can have a holder support surface inside the housing 68 have on which the holder 5 is axially supported. The sensor body 14th now has in the area of the sensor support surface 67 an axial height 69 that is smaller than an axial distance 70 between the sensor support surface 67 and the recess bottom 35 . The result is axially between the pressure sensor 4th and the recess bottom 35 an axial gap 71 educated. In this axial gap 71 is the washer seal 41 arranged. The axial gap is useful 71 through the disc seal 41 completely filled in the axial direction and largely filled in the radial direction. In particular, there is the disk seal 41 Made of an elastic material and is dimensioned in such a way that the disc seal in the assembled state 41 in the axial gap 71 is axially compressed.

In the examples shown here, the holder 5 inside the electronics mount 21st or within the electronics receptacle recess 31 at least one axial recess 78 in which the at least one electronic component 8th the evaluation electronics 6th axially immersed. This results in a particularly compact design. The compact design of the pressure sensor device presented here 1 is also due to the recessed arrangement of the evaluation electronics 6th in the electronics receptacle 31 and the partially recessed arrangement of the pressure sensor 4th in the sensor recess 28 supported.

Claims (15)

Pressure sensor device (1) for measuring a pressure, - with a cylindrical housing (2), - with a pressure sensor (4) which is inserted into the housing (2), - with a holder (5) which is inserted into the housing (2 ) is used, - the pressure sensor (4) having a sensor circuit (11) with sensor contacts (13) and a sensor body (14) with an annular area (15) and with a membrane area (16), - the housing (2) having a Has pressure measuring opening (17) which on the one hand opens inside the housing (2) on the membrane area (16) and on the other hand opens outside on the housing (2), - the holder (5) on its inside (18) facing the pressure measuring opening (17) has a sensor receptacle (19) on or in which the pressure sensor (4) is arranged, characterized in that - the pressure sensor device (1) is also equipped with evaluation electronics (6) which has evaluation contacts (7), - that the holder (5) on its outside facing away from the pressure measurement opening (17) (20) has an electronics receptacle (21) on or in which the evaluation electronics (6) are arranged, - that the holder (5) has several connection openings (22), which are located on the one hand on the sensor receptacle (19) and on the other hand on the electronics receptacle ( 21) open, - that an electrically conductive contact element (23) is arranged in at least one of the connecting openings (22), which is in contact on the one hand with a sensor contact (13) and on the other hand with an evaluation contact (7), - that the electronics receptacle (21) Electronics receiving recess (31) is designed, in which the evaluation electronics (6) is axially inserted. Pressure sensor device (1) Claim 1 , characterized in that the holder (5) is fixed to the housing (2) by means of a flanged connection (24) or by means of a crimp connection (24) or by means of adhesive bonding. Pressure sensor device (1) Claim 1 or 2 , characterized in that the respective contact element (23) rests on the respective sensor contact (13) and on the respective evaluation contact (7) without soldering. Pressure sensor device (1) according to one of the preceding claims, characterized in that the respective contact element (23) rests axially pretensioned on the respective sensor contact (13) and on the respective evaluation contact (7). Pressure sensor device (1) according to one of the preceding claims, characterized in that the respective contact element (23) is a helical spring (26). Pressure sensor device (1) according to one of the preceding claims, characterized in that the sensor receptacle (19) is designed as a sensor receptacle recess (28) into which the pressure sensor (4) is axially inserted. Pressure sensor device (1) Claim 6 , characterized in that at least one sensor alignment element (29) is formed on the sensor receiving recess (28) which interacts with a sensor counter alignment element (30) formed on the pressure sensor (4) such that the pressure sensor (4) is only in a predetermined sensor rotational position between The pressure sensor (4) and holder (5) can be inserted into the sensor receiving recess (28), the connection openings (22) being axially aligned with the sensor contacts (13) in this sensor rotational position. Pressure sensor device (1) Claim 7 , characterized in that the respective sensor alignment element (29) and the associated sensor counter alignment element (30) are designed as a tongue and groove connection. Pressure sensor device (1) according to one of the preceding claims, characterized in that at least one electronics alignment element (32) is formed on the electronics receiving recess (31), which interacts with an electronics counter-alignment element (33) formed on the evaluation electronics (6), in such a way that the Evaluation electronics (6) can only be inserted into the electronics receiving recess (31) in a predetermined evaluation rotational position between evaluation electronics (6) and holder (5), in which evaluation rotational position the connection openings (22) are axially aligned with the evaluation contacts (7). Pressure sensor device (1) Claim 9 , characterized in that the respective electronics alignment element (32) and the associated electronics counter-alignment element (33) are designed as a tongue and groove connection. Pressure sensor device (1) according to one of the preceding claims, characterized in that the housing (2) has an annular sensor recess (34) in the interior of the housing, which is axially limited on the housing side by a recess base (35) and in which the pressure sensor (4) with its ring area (15) is inserted axially, - that the housing (2) has a housing projection (36) concentric to the sensor recess (34), which protrudes axially into the interior of the housing, - that the pressure measurement opening (17) extends through this housing projection (36) extends therethrough, - that a ring seal (39) is arranged radially between the housing projection (36) and the annular region (15), which seals the pressure sensor (4) radially with respect to the housing (2), - that in the sensor recess (34) axially A disk seal (41) is arranged between the ring area (15) and the recess base (35), which is arranged coaxially to the housing projection (36) and which the pressure sensor (4) relative to the housing ( 2) axially seals. Pressure sensor device (1) according to one of the preceding claims, characterized in that the pressure sensor device (1) also has an electrical connection (43) which is inserted axially into the housing (2) so that the electrical connection (43) is connected to one of the pressure sensor ( 4) adjoins the holder (5) facing away, - that the electrical connection (43) has an external interface (44) on its outside facing away from the holder (5) for the transmission of electrical signals and electrical power, - that the electrical connection (43 ) has on its inside facing the holder (5) an internal interface (45) coupled to the external interface (44) for the transmission of electrical signals and electrical power, which is coupled to an evaluation interface (47) of the evaluation electronics (6) complementary thereto . Pressure sensor device (1) Claim 12 , characterized in that the electrical connection (43) is fixed to the housing (2) by means of a crimp connection (24) or by means of a crimp connection (24) or by means of gluing, thereby fixing the holder (5) axially in the housing (2). Pressure sensor device (1) according to one of the preceding claims, characterized in that the housing (2) in the area of the pressure measurement opening (17) has an axially protruding pressure connection area (50) on its axial outside, through which the pressure measurement opening (17) extends - that the pressure sensor device (1) also has an adapter (51) which has a pressure connection receptacle (52) complementary to the pressure connection area (50), a pressure measurement connection (53) and a connection channel (54), - that the adapter (51) is connected to the outside of the housing (2) is arranged so that the pressure connection area (50) is inserted into the pressure connection receptacle (52) and the pressure measurement opening (17) is fluidically connected to the pressure measurement connection (53) through the connection channel (54). Pressure sensor device (1) Claim 14 , characterized in that the adapter (51) is permanently attached to the housing (2).

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