DE102019124083B3 - Absolute pressure measuring device with a relative measuring pressure measuring cell - Google Patents

Abstract

The invention relates to a measuring device for measuring the absolute pressure of a medium in a container, with at least one process connection (3) comprising a relatively measuring pressure measuring cell (10) and a housing (2) placed on the process connection (3), in the interior of which there is evaluation electronics ( 30) is arranged for evaluating and processing a measurement signal generated by the pressure measuring cell (10). In order to make the measuring device easy and inexpensive to manufacture, it is proposed according to the invention that the housing (2), in addition to the evaluation electronics (30), also have a processing unit (40) and a barometric air pressure transducer (20) for detecting the internal pressure inside the housing (2) plumfasst, and in the processing unit (40) the relative pressure measured value at the output of the evaluation electronics (30) is increased by the internal housing pressure pl detected by the barometric air pressure transducer (20).

Description

The invention relates to a measuring device for detecting the absolute pressure of a medium adjoining the pressure measuring device.

Pressure measuring devices or pressure sensors are used in many industrial sectors for measuring pressure. They often have a pressure measuring cell as a transducer for the process pressure, and evaluation electronics for signal processing. Typical pressure measuring cells measure the pressure either capacitively or resistively.

Typical capacitive pressure measuring cells consist of a compact unit with a ceramic base body and an elastic membrane, with an annular joint, typically a glass solder ring, being arranged between the base body and the membrane. The resulting cavity between the base body and the membrane - also referred to as the measuring chamber - enables the membrane to move longitudinally as a result of the influence of pressure. On the lower side of the membrane and on the opposite upper side of the base body, electrodes are provided which together form a measuring capacitor. The effect of pressure causes deformation of the membrane, which results in a change in the capacitance of the measuring capacitor. With the help of an evaluation unit, the change in capacitance is recorded and converted into a pressure reading. A capacitive pressure measuring device is, for example, from DE 10 2010 062 622 A1 known.

In contrast, pressure measuring cells with resistive measurements record the deflection of the membrane with the help of electromechanical converters, for example by means of strain gauges, which are deformed with the deflected membrane and convert the deflection into a corresponding resistance value or voltage or current value. Such pressure measuring cells are available both in one piece in the form of a monolith, but also in two pieces with a base body and a thin membrane. A resistive pressure measuring device is, for example, from DE 10 2010 035 862 A1 known.

The so-called process connection is located on the lower part of the measuring device, through which the measuring device is connected to a container or pipe carrying the medium. As a rule, these pressure gauges are used to monitor or control processes. They are therefore often connected to higher-level control units (PLC) via a plug connection.

Typically, pressure measuring devices used in process measurement technology are provided to measure a relative pressure, that is to say the output of the pressure values recorded by the pressure measuring cell in relation to the ambient or atmospheric pressure. In this case, it is particularly necessary that atmospheric pressure prevails in the room, which enables the longitudinal mobility of the measuring membrane of the measuring cell as a result of the influence of pressure. In the case of a capacitive measuring cell, this is the aforementioned measuring chamber between the base body and the membrane. In the case of a resistively measuring pressure measuring cell, this is usually the entire interior of the housing of the measuring device, provided the measuring cell is not encapsulated.

Correspondingly, the measuring devices that measure a relative pressure have a pressure compensation device that includes an opening of whatever type. This opening can be arranged in the housing wall, such as, for example DE 10 2013 200 840 A1 the applicant disclosed, or in the plug connection, as from the DE 10 2012 201 018 A1 known to the applicant. In this case, however, the measuring devices have to be cleaned frequently in order to maintain hygienic conditions, which is done, for example, by means of a high pressure or steam jet.

One-piece barriers in the form of foils or membranes are known for this from the prior art. The DE 102 32 028 B4 proposes, for example, to provide an opening in the housing wall which is closed off with a liquid-repellent and gas-permeable segment in order to achieve pressure equalization between the interior of the housing and the external environment of the housing. The segment consists of a film, for example a plastic film, or a membrane, for example made of PTFE. The DE 197 08 116 A1 suggests using a breathable and waterproof film such as those known for example under the name Goretex® or Sympatex®.

Under certain conditions, these foils and membranes can reach their technological limits and must be protected from contamination and the influence of cleaning emitters. In such cases, it is advisable to use pressure measuring devices that measure an absolute pressure, i.e. the pressure in comparison to a vacuum as a reference point, because these measuring devices do not require an opening as a pressure compensation device. However, measuring devices of this type are very expensive to manufacture, primarily because of the special pressure measuring cells with an evacuated cavity, and their use is therefore mostly uneconomical for comparatively simple applications.

The object of the invention is to propose an absolute pressure measuring device that can be produced simply and inexpensively.

According to the invention, this object is achieved by a pressure measuring device with the features of claim 1. Advantageous embodiments of the invention are specified in the subclaims.

The core of the invention is the use of a conventional, relatively measuring pressure measuring cell that does not require an evacuated cavity, as well as a barometric air pressure transducer that records the internal pressure within the measuring device housing, which also acts on the second side of the measuring membrane facing away from the medium. In addition to the evaluation electronics for evaluating and processing the measurement signal generated by the pressure measuring cell, a processing unit is also provided which increases the relative pressure measured value at the output of the evaluation electronics by the internal pressure of the housing recorded by the barometric air pressure transducer. As a result, the measuring device can thus provide a measured value, for example via a cable connection, which is independent of external pressure conditions.

Both the pressure measuring cell and the barometric air pressure transducer can be manufactured or procured inexpensively, among other things because no special structural requirements have to be made on the barometric air pressure transducer if it is located inside the measuring device housing and thus against external, in particular mechanical influences of a process environment is protected. Furthermore, no special requirements have to be placed on the measuring device housing or the connection between the measuring device housing and the process connection, e.g. with regard to tightness, since the barometric air pressure transducer immediately records pressure changes inside the measuring device housing and calculates them accordingly with the measurement results of the relative measuring pressure measuring cell .

It is particularly advantageous to design the barometric air pressure transducer as an SMD component, since these components are available very cheaply.

With the invention it is now possible in a very simple manner to produce a pressure measuring device without a pressure compensation opening and thus to operate it largely independently of external conditions.

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

• 1 ein elektronisches Druckmessgerät;
• 2 einen Querschnitt durch das Druckmessgerät.

They show schematically:

• 1 an electronic pressure gauge;
• 2 a cross section through the pressure measuring device.

In the following description of the preferred embodiments, the same reference symbols designate the same or comparable components.

In 1 is an electronic pressure measuring device 1 for use in process measurement technology, which is manufactured and sold by the applicant under the designation PNxxxx. The measuring device 1 consists essentially of a housing 2 , which is divided into a top 3 and a base 4th . The lower part 4th , also referred to as a process connection, includes the sensor unit on the one hand 10 (not shown) in the form of a pressure measuring cell and, on the other hand, enables the mechanical connection of the measuring device 1 with the container or pipe containing the medium. In the case 2 the evaluation electronics are located 30th (not shown) for evaluating and processing the data from the sensor unit 10 supplied measurement signals is provided, which then via the plug connection 8th can be tapped and, for example, forwarded to a PLC.

On the top 3 a housing head is attached 5 , which includes a display device 6 and controls 7th having. Via the controls 7th becomes the meter 1 operated, ie a parameterization or a setting of essential key data, such as. The switching points. The respective actions are shown to the user via the display 6 displayed.

2 shows in a very schematic representation a cross section through the measuring device 1 together with a representation of a conventional capacitive, relatively measuring pressure measuring cell 10 . The pressure measuring cell 10 consists essentially of a basic body 12 and a measuring membrane 11 . The structure and mode of operation of such pressure measuring cells is well known, for example from US Pat EP 2606330 B1 of the applicant. Even if in 2 a capacitive pressure measuring cell 10 is shown by way of example, the invention can also be implemented with a resistive pressure measuring cell, as it is, for example, from FIG DE 102010035862 B4 is known to the applicant.

The case 2 of the measuring device 1 essentially contains the electronic units, consisting of evaluation electronics 30th and a processing unit 40 , which is preferably designed as a microcontroller. Via a ventilation duct 13 is the pressure measuring cell 10 with the interior of the case 2 connected, ie on the side of the measuring membrane facing away from the medium 11 the pressure p _l is the same as that in the interior of the housing 2 prevails. In this way, in the case of a relative pressure measuring device, pressure equalization between the housing interior and the surroundings is achieved by means of an opening in the housing wall, so that atmospheric pressure is also applied to the measuring membrane. As already described at the outset, these pressure compensation openings, in particular the foils and membranes covering the openings, can reach their technological limits under certain conditions.

The measuring device according to the invention 1 has no such pressure compensation opening in the housing 2 on. As a result, the pressure p _l in the interior of the housing 2 change permanently, especially due to temperature influences, which must be taken into account accordingly in terms of measurement technology. This is in the interior of the housing 2 a barometric air pressure transducer 20th provided, which is preferably an SMD component on the same circuit board as the evaluation electronics 30th and the processing unit 40 is arranged. An example of such a barometric air pressure transducer 20th is the Bosch BME280.

In the processing unit 40 then - indicated by the arrows - the relative pressure measured value at the output of the evaluation electronics 30th around that from the barometric pressure transducer 20th detected internal pressure measurement value p _l increased and is at the indicated plug connection 8th made available for further processing. The case 2 of the measuring device 1 therefore does not have to be hermetically sealed. Any change in pressure inside the housing 2 is controlled by the barometric pressure transducer 20th detected and by the processing unit 40 taken into account when calculating the process pressure.

List of reference symbols

1

Measuring device

2

casing

3

Top

4th

Lower part, process connection

5

Housing head

6th

display

7th

Controls

8th

Plug connection

10

Pressure measuring cell

11

Measuring membrane

12

Base body

13

Ventilation duct

20th

barometric air pressure transducer

30th

Evaluation electronics

40

Processing unit

Claims (2)

Measuring device for measuring the absolute pressure of a medium in a container, with at least one process connection (3) comprising a relatively measuring pressure measuring cell (10) and a housing (2) placed on the process connection (3), in the interior of which there is evaluation electronics (30) for evaluation and processing of a measurement signal generated by the pressure measuring cell (10) is arranged, the pressure measuring cell (10) comprising a deflectable measuring membrane (11) whose first side is at least partially in contact with the medium and whose second side facing away from the medium is in contact with the housing interior is in contact and has an electromechanical transducer which converts a deflection of the measuring membrane (11), which is dependent on the pressure p acting on the measuring membrane (11), into an electrical variable, the housing (2) not only having the evaluation electronics (30) but also a processing unit ( 40) as well as a barometric air pressure transducer (20) for recording the inside of the housing (2) the pressure p _l prevailing and acting on the second side of the measuring membrane (11) facing away from the medium, and in the processing unit (40) the relative pressure measured value at the output of the evaluation electronics (30) is increased by the internal housing pressure p _l recorded by the barometric air pressure transducer (20) . Measuring device after Claim 1 , characterized in that the barometric air pressure transducer (20) is designed as an SMD component.

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