Patent Application
20220155118
The invention is based on a flowmeter with at least one measuring tube, with a measuring arrangement for measuring the flow of a medium flowing through the measuring tube, with at least one receiving unit for a sensor unit and with a sensor unit, wherein the receiving unit is arranged on the measuring tube. In addition, the invention relates to a sensor unit for installation in a flowmeter according to the invention, with at least one sensor, with at least one flexible printed circuit board and with at least one carrier, as well as a method for manufacturing a flowmeter according to the invention.
In some applications, it is advantageous that a flowmeter has at least one further sensor unit for measuring at least one further parameter in addition to the actual measuring unit for determining the flow. In these cases, the at least one additional sensor unit has to be arranged or placed on or in the measuring tube such that the additional sensor can, on the one hand, reliably measure the parameter to be measured and, on the other hand, can be easily installed and removed.
A measuring device with an electronic unit is known from the document DE 10 2011 119 841 A1, wherein the electronic unit comprises a flexible printed circuit board on which at least two rigid contact pins are soldered such that one end of the contact pins protrudes over the flexible printed circuit board and wherein the flexible printed circuit board is formed into a three-dimensional body by folding and/or bending, wherein the body is held in its three-dimensional form by means of a foldable carrier. In addition, a sensor can also be soldered to the flexible printed circuit board, wherein the printed circuit board is bent so that the sensor is positioned in the desired position within the measuring device.
Based on this state of the art, the object of the invention to provide a flowmeter with an additional sensor unit which can be arranged and exchanged particularly easily. In addition, the object of the invention is to provide a sensor unit which can be particularly easily arranged and exchanged in a flowmeter according to the state of the art and a method for manufacturing a flowmeter.
According to a first teaching of the present invention, the aforementioned object is achieved by a flowmeter mentioned at the beginning in that the sensor unit comprises at least one sensor, at least one flexible printed circuit board and at least one carrier,
According to the invention, it was recognized that the connection of a flexible printed circuit board to a carrier is advantageous in that the printed circuit board can be at least partially adapted to the shape of the carrier. The mounting of the sensor unit can thus be carried out in an advantageous way by mounting the carrier, wherein the carrier is only inserted into the receiving unit. At the same time, the sensor, which is arranged on the flexible printed circuit board, is thereby placed in the measuring tube for measuring at least one additional parameter.
Because the flexible printed circuit board is only wrapped or folded around the carrier, a complex installation and mounting of the printed circuit board or the additional sensor can be avoided.
If it is said that the sensor unit or the sensor is placed exchangeably in the flowmeter, it is meant that neither the sensor unit nor the sensor in the flowmeter is bonded, in particular glued. The sensor and/or the sensor unit are therefore only arranged in the flowmeter via positive and/or non-positive connections.
The advantage of this arrangement according to the invention is that it is particularly easy to install and the sensor can be easily replaced.
According to a first design, the receiving unit is cup-shaped and the carrier of the sensor unit is at least partially plug-shaped, so that the carrier acts as a plug to close the cup-shaped receiving unit.
It is particularly preferred that the plug-shaped sensor unit is held in the cup-shaped receiving unit by a frictional connection, so that the sensor unit is fixed in place even in case of vibrations and cannot slip out.
It is especially preferred that the at least one sensor is a temperature sensor and/or a pressure sensor and/or a conductivity sensor.
For example, by arranging a conductivity sensor in the measuring tube during operation, it can be determined whether the measuring tube is completely or only partially filled with the medium to be measured.
The flexible printed circuit board is, for example, a bendable printed circuit board, in particular a flex foil, or a rigid-flexible printed circuit board or a semi-flexible printed circuit board. The bendable printed circuit board is completely bendable, i.e. it can be bent at any point. Such a design is advantageous in that the flexible printed circuit board can be wrapped or folded particularly flexibly around the carrier. In addition, the flexible printed circuit board can also be designed as a rigid-flexible printed circuit board or as a semi-flexible printed circuit board. In this case the flexible printed circuit board has rigid areas which are connected by flexible areas. According to this design, the circuit board is wrapped or folded over the bendable areas around the carrier.
According to a further preferred design, the flexible printed circuit board encloses the carrier at least partially in the longitudinal direction and/or at least partially transverse to the longitudinal direction. According to this design the carrier has a longitudinal axis. Especially when the flexible printed circuit board encloses the carrier at least partly in the longitudinal direction and at least partly transverse to the longitudinal direction, the printed circuit board is arranged sturdily around the carrier.
It is particularly preferred that the carrier is of polyamide. According to a further design, the carrier additionally has at least partially a layer comprising an adhesive and/or comprising electrolytic copper. Preferably, a plurality of additional layers is present, in particular comprising an adhesive and/or electrolytic copper.
According to a next design, the carrier has at least one first recess and the flexible printed circuit board has at least one first connection area, wherein preferably the shape of the first recess essentially corresponds to the shape of the first connection area and wherein the flexible printed circuit board is placed with the first connection area into the first recess. Because the flexible printed circuit board with the connection area is inserted into the first recess preferably with a perfect fit, it is held by the carrier at least such that the flexible printed circuit board cannot slip during insertion into the receiving unit.
Particularly preferably, the carrier has at least a first and a second recess, wherein the printed circuit board has at least a first and a second connection area, and wherein the printed circuit board is arranged with the first connection area in the first recess and with the second connection area in the second recess.
According to a next design, the carrier has a recess substantially corresponding to the shape of the contact surface of the flexible printed circuit board with the carrier so that the flexible printed circuit board is held continuously to the carrier at least by the edges of the recess.
According to the next design, the carrier has at least one fixing element for fixing the circuit board on the carrier.
It is particularly preferred that the at least one fixing element is a slot and/or a groove and/or a seam and/or a chamfer and/or an edge protruding, preferably obliquely, beyond the printed circuit board.
An edge protruding obliquely beyond the printed circuit board forms an acute angle, preferably between 45° and 90°, with the receiving surface of the carrier. It is especially preferred that the carrier has at least two edges that protrude obliquely from the printed circuit board and that are arranged opposite to each other.
According to a next design, the flexible printed circuit board has at least one mounting element, preferably in the connection area, wherein the at least one mounting element is preferably in operative connection with the at least one fixing element.
For example, the mounting element is designed as a projection which is arranged in the fixing element so that the printed circuit board is held on the carrier with a positive fit at least in one spatial direction. For example, the projection can be designed and arranged such that it is bent or pushed into the fixing element for fixing.
The fixing of the printed circuit board is particularly preferred by combining the at least one fixing element and the at least one mounting element such that the printed circuit board is fixed in three spatial directions.
According to another preferred design, a ground connection is arranged on the flexible printed circuit board, wherein the ground connection is connected to the housing of the flowmeter. It is particularly preferred that the ground connection is on a second connection area of the flexible printed circuit board, wherein the second connection area is arranged to fit, preferably essentially exactly, in the second recess of the carrier.
According to a next preferred design, the flexible printed circuit board has several functional subsections, wherein the functional subsections are arranged on different arms of the flexible printed circuit board, such that the functional subsections are positioned at the point of their connection by separately bending of the arms.
A first subsection is designed for connection to the carrier. A second subsection is designed for the connection to the measuring arrangement. A third subsection is designed for connection to the power supply. In this subsection, a plug is connected particularly preferably to the printed circuit board.
According to a further preferred design a cover element is arranged on the sensor. The cover element is preferably designed as an insulation element to insulate the sensor. Alternatively or additionally, the cover element has a high thermal conductivity, so that in the case in which the sensor is designed as temperature sensor, a fast response time of the temperature sensor can be guaranteed. According to one design, the cover element has at least two layers, wherein at least one layer is conductive and wherein at least one layer is non-conductive. Particularly preferably, the non-conductive, insulating layer is thinner, in particular much thinner, than the conductive layer. According to one embodiment, the non-conductive layer is a polyamide layer.
According to a further preferred design, the sensor unit is positively and/or non-positively held in the receiving unit. For this, the sensor unit is preferably pressed into the receiving unit.
According to a second teaching of the present invention, the object described above is achieved by a sensor unit described above for installation in a flowmeter according to the invention in that the at least one sensor is arranged on the at least one flexible printed circuit board, wherein the at least one flexible printed circuit board is at least partially wrapped or folded around the carrier.
The sensor unit according to the invention has the advantage that the installation of the sensor can be carried out particularly easily, on the one hand, because the sensor unit only has to be inserted into the receiving unit and, on the other hand, the sensor can be easily exchanged.
It is particularly preferred that the sensor unit is designed according to one of the designs described above.
According to a third teaching of the present invention, the object mentioned above is thereby achieved by a method for manufacturing a flowmeter described above,
The advantage of this method is that the sensor unit is simply plugged in for mounting and correctly positioning the additional sensor.
There is now a plurality of possibilities for designing and further developing the flowmeter, the sensor unit and the method according to the invention. For this, reference is made to the following description of preferred embodiments in conjunction with the drawings.
The illustration shows the sensor unit 2 in an unconnected state, i.e. the flexible printed circuit board 5 is not arranged directly on the carrier 6. The printed circuit board 5 has a connection area 12 for connection to the carrier 6. To accommodate the printed circuit board 5, the carrier 6 has an intake area 8 into which the connection area 12 can be inserted.
To fix the printed circuit board 5 on the carrier 6, the carrier has fixing elements in the form of edges 7. For better fixation, the edges can also form an acute angle between 45 and 90° with the receiving surface of the carrier 6. For connection to the carrier, the printed circuit board 5 can thus be inserted into the intake area 8 of the carrier 6 and fixed by the edges 7 protruding beyond the printed circuit board 5. Furthermore, the carrier 6 has a slot 10 in the intake area 8 for fixing into which the printed circuit board 5 can be inserted.
In addition, the carrier 6 has two chamfers 9 in the area of the receiving area for further fixation. For connection, the printed circuit board 5 has mounting elements in the form of lateral projections 11 which can be folded into the chamfers 9 when connected.
In a first step 19, the flexible printed circuit board 5 is at least partially folded around the carrier 6 and fixed to it.
Then the sensor unit 2 is inserted 20 into the receiving unit 16 so that the sensor 4 is located inside the measuring tube 17. At the same time the additional functional subsections 22 and 24 are positioned intended for their connection.
The installation of the sensor 4 is therefore particularly easy. In addition, the sensor unit can also be replaced very easily.
| Number | Date | Country | Kind |
|---|---|---|---|
| 102020130596.6 | Nov 2020 | DE | national |
