CH717316B1 - load cell. - Google Patents

Abstract

The invention relates to a load cell for determining point and/or surface forces, comprising: an elastically deformable front body (1) for contacting a force (F) to be determined on an outside of the front body (1), a transmission sleeve (2), which with an end face facing the front body contacts a circumferential area on an inner side of the front body opposite the outside, preferably a circumferential edge area on the inside of the front body, and an elastically deformable measuring body (3) which is arranged on an end face of the transmission sleeve facing away from the front body, wherein the inside of the front body and / or the inside of the measuring body facing the front body is / are designed such that the two insides of the front and measuring body touch each other. The load cell is characterized in that the transmission sleeve has a cross section that tapers from the front body towards the measuring body.

Description

The present invention relates to a load cell for determining point and/or surface forces. The load cell of the invention is used, for example, when weighing objects, in testing systems or in torque supports.

[0002] The increasing automation of processes and complex fully automatic operations requires appropriately adapted sensor technology to reliably carry out the associated process control. Force sensors, for example in the form of a load cell, are particularly important here. High demands are placed on the reliability and reproducibility of a measurement, so that these load cells can also be used in chemical processes or in the food sector. It is advantageous if such a load cell has a design that is as flat as possible and can also be cleaned particularly easily.

[0003] In addition, due to the unavoidable intervention in the measuring space in which, for example, the item to be determined in terms of weight is arranged, increasing miniaturization is required when measuring the force or surface force in order to keep the space required for mounting the load cell small to keep.

[0004] A large number of load cells are known from the prior art, which have different designs. The best-known design is the so-called ring torsion sensor, as shown in various embodiments, for example, in DE 3 924 629 C2, EP 1 181 514 B1, DE 10 2016 109 292 A1 or DE 3 837 683 A1. Another known design is the so-called rod-shaped transducer (see DE 19 537 288 A1).

Each of these designs has its individual advantages and disadvantages, for example ring torsion transducers have a relatively flat overall height while rod-shaped transducers have advantages when force is not introduced centrally. Due to the principle, the electrical connection for both types is radial, which is a disadvantage in terms of the compactness of the load cell.

It is the aim of the present invention to create a load cell that combines the respective advantages of the two designs currently on the market. In addition, the load cell according to the invention should also be usable in very limited spaces where the implementations known from the prior art cannot be used. In particular, a load cell must be provided that is easier to manufacture and in which the force measuring sensors are easier to attach and connect.

[0007] This object is achieved by a load cell according to the invention according to claim 1. Advantageous embodiments are listed in the dependent claims.

[0008] Accordingly, a load cell according to the invention for determining point and/or surface forces comprises an elastically deformable front body for contacting a force to be determined on an outside of the front body, a transmission sleeve which, with an end face facing the front body, has a circumferential area on an outside opposite inside of the front body, preferably a circumferential edge region on the inside of the front body, contacted, and an elastically deformable measuring body, which is arranged on an end face of the transmission sleeve facing away from the front body, the inside of the front body and / or the inside of the measuring body facing the front body is/are designed in such a way that the two insides of the front and measuring body touch each other. The load cell is characterized in that the transmission sleeve has a cross section that tapers from the front body towards the measuring body.

Due to the reduction in cross-section of the transmission sleeve from the front body to the measuring body, it is possible to arrange the force measurement to be carried out by the load cell in a simple manner in a measuring room. All that needs to be provided is a hole into which the interconnected structure consisting of the front body, transmission sleeve and measuring body is to be inserted. The reduction in cross-section of the transmission sleeve then ensures that the measuring body has sufficient space in the event of a deformation occurring during the force measurement

It can be provided that the cross-sectional area of the transmission sleeve remains the same or decreases in the course from the front body towards the measuring body, but no longer increases.

It can also be provided that the measuring body connects to the cross-sectional area of the end face of the transmission sleeve facing it in such a way that it does not extend beyond the transmission sleeve in the cross-sectional direction.

The cross-sectional area of the measuring body (in a longitudinal direction that extends from the front body towards the measuring body) is equal to or smaller than the largest or smallest cross-sectional area of the transmission sleeve.

According to the basic functional principle of the load cell, a force acting on the front body leads to a corresponding elastic deformation of the front body. Since the inside of the front body is in contact with the inside of the measuring body, this elastic deformation is passed on to the contacting elements of the front and measuring body, so that a corresponding deformation of the measuring body occurs. This deformation can then be measured using a force measuring device so that the force acting on the load cell can be determined.

Furthermore, it can be provided according to the invention that the transmission sleeve has a flange which projects radially outwards on its front end section facing the front body and which is preferably formed continuously in the circumferential direction.

[0015] It can also be provided that the transmission sleeve also consists of an elastically deformable material.

A connection area with the front body can be formed on the flange collar facing away from the transmission sleeve. The flange collar facing the transmission sleeve can be used to place on a complementary step of a housing or a correspondingly shaped bore.

According to a further optional modification of the invention, it can be provided that the transmission sleeve has a radially inwardly extending transition region between its two front end sections, which is preferably continuous in the circumferential direction. This feature, which can be provided in addition to the outwardly projecting flange, therefore describes a reduction in cross-section in a middle section encompassed by the two front end sections. If you insert the transmission sleeve into a correspondingly dimensioned cylindrical recess (e.g. a bore or a housing), the area of the transmission sleeve that does not have a reduced cross-section can be used for fixation and stabilization, whereas the area that is offset inwards has a (preferably circumferential) gap opposite the cylindrical recess.

According to the invention, the load cell is provided with a force measuring device comprising a plurality of strain measuring sensors, the strain measuring sensors being arranged on the outside of the measuring body facing away from the front body, preferably the strain measuring sensors being strain gauges which have a high k-factor of 4.5 to 5 .5 and/or consist of titanium oxynitride (TiON).

[0019] It can be advantageous if the several strain gauges are connected to form a Wheatstone full bridge. A particularly precise determination of the force is obtained if one strain gauge for each half bridge in the Wheatstone full bridge is loaded for compression and one for expansion, which means that maximum sensitivity to the effect of force can be achieved.

Preferably, the load cell according to the invention further comprises a temperature-dependent resistance on the outside of the measuring body to compensate for a temperature influence of the measurement carried out by the force measuring device. The temperature-dependent resistance is then used to compensate for the temperature-induced expansion or compression of the measuring body, since this is also recorded by the force measuring device and used to determine an acting force. This effect needs to be compensated for, for which the temperature-dependent resistance is now used.

According to a further advantageous modification of the invention, it can be provided that the front body, transmission sleeve and measuring body are rotationally or rotationally symmetrical about a common axis, preferably arranged coaxially to this axis. The mechanical structure of these parts and also their assembled structure can be radially symmetrical, in particular the force introduction axis of a force to be determined coincides with the axis of symmetry, i.e. can be identical to it.

Furthermore, it can be provided according to the invention that the introduction of a force towards the measuring body takes place via the touching inner sides of the front body and measuring body. For this purpose, the inside of the front body can have a design that extends towards the measuring body. The inside preferably has a circular base area, which extends further and further towards the measuring body starting from an edge of the base area. The same can also apply to the inside of the measuring body, whereby the contact section of the two insides can of course be designed differently, so one of the two insides tapers to a point and is accommodated in a corresponding recess on the other inside or even pierces it. Both inner sides can rise continuously from one edge to the middle.

The inside of the front body, which extends in the direction of the measuring body, can have an approximately funnel-shaped basic structure, which may have an arc-like slope and has a recess around its center for inserting a measuring body component. This structure on the inside of the front body is also known in technical language as a force flow concentrator, as it focuses or concentrates a force acting on the front body onto a small area.

Preferably, according to the invention it can be provided that the outside of the front body and/or the outside of the measuring body is/are flat.

These configurations are particularly advantageous because a flat outside of the front body allows for easy cleaning, which can be carried out without much effort and also makes it easier for foreign particles to accumulate, in contrast to a design with edges or that is not flat.

According to a further development of the invention, it can be provided that the inside of the front body rises towards its center towards the measuring body and/or the inside of the measuring body rises towards its middle towards the front body, with a radial gap between the transmission sleeve and the mutually contacting inner sides remain, preferably with the inner side of the measuring body penetrating into or penetrating a central recess in the front body.

[0027] Preferably, the load cell also comprises a receiving body, in particular a bore, for receiving the components connected to one another, comprising the front body, transmission sleeve and measuring body, the cross section of the transmission sleeve tapering from the front body towards the measuring body in its not yet tapered area for fastening and centering and in its tapered area ensures a radial distance between the transmission sleeve and the measuring body from the receiving body, the receiving body preferably having a cylindrical basic shape which has a step-like inwardly directed support flange in the area of the front body in order to ensure a flat or almost flat finish Front body in the receiving body in a load cell whose transmission sleeve has a flange projection on the front body side.

[0028] Furthermore, it can be provided that at least one electrical connection to the force measuring device can be made axially, preferably via contacting surfaces arranged on the outside of the measuring body opposite the inside. The advantage of this is that, in contrast to load cells known from the prior art, an axial connection guide of the load cell is possible. A simple hole can therefore already be sufficient as a receiving body or as a receptacle, so that the implementation of the present load cell is very cost-effective and can be used in a variety of applications.

[0029] Furthermore, it can be provided according to the invention that the front body, the transmission sleeve and/or the measuring body is made of a metal, preferably a high-strength metal, preferably martensitic steel 1.4542 or 1.4548 and/or the nickel-based alloy Inconel 718, the chemical thereof Composition of 50.0 -5 5.0% Ni, 17.0 - 21.0% Cr, 4.75 - 5.50% TA + Nb, 2.80 - 3.30% Mo, 0.65 - 1 .15% Ti, 0.20 - 0.80% Al, ≤ 0.3% Cu, ≤ 0.08% C, ≤ 0.35% Si and ≤ 1.0% Co.

Preferably, it can be provided that the thermal expansion coefficient of the front body, transmission sleeve and measuring body is identical or deviates by less than 5% from the nominally largest coefficient. This ensures that undesirable, asymmetrical or inhomogeneous deformations caused by the thermal expansion of the material are avoided.

[0031] Furthermore, according to an optional modification, it can be provided that a connection board is provided, which is arranged on the outside of the measuring body, preferably wherein the connection board is cohesively connected to the outside of the measuring body. The connection board can be provided for the electrical connection of the force measuring device.

The invention further relates to a load cell whose strain measuring sensors and/or whose temperature-dependent resistance can be or has been applied to the measuring body using thin-film technology.

It can further be provided that the entire structure consisting of the front body, transmission sleeve and measuring body has such a small thickness in the axial direction that it can be coated using available thin-film coating systems. For example, the application of the strain measuring sensors is then easy to accomplish.

Further advantages, features and details of the invention become apparent from the following description of the figures. Show: Fig. 1: shows a sectional view of the most important components of the load cell according to the invention, Fig. 2: shows a further sectional view of the structure known from Fig. 1, which is inserted into a receiving opening and is also provided with further components, Fig 3: shows the circuit diagram of a Wheatstone full bridge, and Fig. 4: shows a top view of the outside of the measuring body.

1 shows a sectional view of the load cell according to the invention, in which an elastically deformable front body 1 is designed to contact a force F. This front body 1 has an approximately flat outside, which is suitable for determining a force F acting on it. The inside facing away from the outside of the front body 1 has a force flow concentrator 4 that rises towards its center. This force flow concentrator 4 causes a force F acting from the outside of the front body to be concentrated on a specific area on the inside. A possible embodiment of the force flow concentrator 4 is a funnel-shaped elevation on the inside, or an elevation running at an angle to the flat surface of the outside, which rises approximately perpendicular to the plane formed by the flat outside of the front body 1. It is preferably provided that the front body is a disk, in which a first flat side represents the outside and the second flat side represents the inside.

[0036] In an edge region of the front body 1, there is a transmission sleeve 2, which is formed inwardly offset from the contact region to the front body via a flange-like projection 7, and then essentially parallel to the force introduction axis 19, or in the normal direction to the flat outside of the front body 1 runs away from the front body 1. At its front end applied by the front body 1, this transmission sleeve touches a measuring body 3, which closes the opening defined by the transmission sleeve 2. The measuring body 3 has an inner surface facing the front body 1 and an outer surface facing away from the front body 1. Similar to the inner surface of the front body, the inner surface has a section which extends parallel to the force introduction axis 19 and which contacts the force flow concentrator 4.

1, it can even be provided that the force flow concentrator 4 has a recess or even a continuous recess radially to the force introduction axis 19, into which the counterpart of the measuring body 3, which runs parallel to it, penetrates. A part of this element of the measuring body 3 penetrating into the recess of the force flow concentrator 4 can also run towards the outside of the front body 1. The person skilled in the art is aware that this does not have to be the case for every load cell covered by the invention, but that a normal intervention or the flat contact of two rectilinear planes of the two contact pieces in contact also realizes the active principle of the invention.

The transmission sleeve 2 is designed in such a way that a radial clearance 5 is formed between the components of the respective inner sides of the front body 1 and measuring body 3, which are parallel to the force introduction axis 19 and come into contact with one another, and which defines the contact section of the front body 1 and measuring body 3 all around. Furthermore, it can be seen that the transmission sleeve 2, in addition to its flange-like projection 7, has a cross-sectional reduction in the contact area with the front body 1 (near the reference number 8), which makes it particularly easy to mount the load cell in a receiving body, such as a housing or a correspondingly sized bore 18 enabled. It is important that this reduction in cross-section enables the mobility of the measuring body 3 when a force F is applied, so that the basic operating principle of force measurement can be maintained. Furthermore, it can be provided that a force measuring device is provided on the outside of the measuring body 3 facing away from the front body 1, which detects an expansion of the outside of the measuring body 3 and converts it into an electrical signal. For this purpose, several strain measuring sensors can be interconnected in the form of strain gauges, preferably in accordance with a Wheatstone bridge, so that an expansion of the outside caused by the action of the force F is detected and converted into an electrical signal corresponding to an acting force. Attaching it to the outside of the measuring body 3 is sufficiently far away from the measuring space 13 so that the harsh conditions that typically prevail there cannot affect the force measuring unit.

The advantage of the embodiment of the present invention shown in Fig. 1 is that the structure consists of the flat, elastically deformable front body, for example in the form of a disc spring, the transmission sleeve 2 and the measuring body 3, which has contact with the center of the force introduction axis Front body 1 has a particularly clever introduction of force of a force to be measured. The axial distance 15 from force introduction to force output is very small, which enables simplified installation and a particularly effective measurement using a bending of the measuring body 3. The force is introduced via the front body, which passes on the acting force to the measuring body 3 via the force flow concentrator 4. There the flow of force is redirected so that it is directed out of the flange 7 via the transmission sleeve. Since the flange 7 and the front body 1 rest against each other, the axial distance 15 from force introduction and force output is very small, so that very compact and structurally advantageous arrangements of load cells can be implemented.

2 shows the components from FIG . rest on it, so that a force F acting centrally on the load cell is introduced into the measuring body 3 via the front body 1 and is introduced from the flange 7 into the receiving body 16 via the transmission sleeve in the direction of the front body 1. If you now create a correspondingly stepped bore, the support surface 12 of which for the flange 7 of the transmission sleeve is essentially as deep as the sum of the thicknesses of the edge region of the front body 1 and the flange 7 of the transmission sleeve 2, you can easily create one An almost flat or flat load cell can be provided. This makes cleaning such a load cell considerably easier, since no elements projecting or recessed from the outside of the front body 1 are provided.

If the inner diameter of the bore 18 is matched to the outer diameter of the transmission sleeve in an area spaced from the flange, but which has not yet undergone a cross-sectional reduction, this area serves to center and fasten the interconnected components front body 1 transmission sleeve 2 and measuring body 3. This fastening and centering area 8 of the transmission sleeve essentially contacts an inner wall of the bore 18, so that insertion into the bore 18 also has a fixing and sealing effect against the measuring space 13. Pressing in can also lead to a sealing connection in which the measuring space 13 is sealingly separated from the attachment location of the force measuring device.

[0042] It can also be seen that on the outside of the measuring body 3 facing away from the front body 1, a connection board 14 is arranged, which is axially connected to the outside of the measuring body 3 by sintering or pressing. This connection board 14, which can preferably be made of high-temperature-resistant circuit board material or a ceramic, enables the axial introduction of electrical connections for the force measuring device. This makes it possible to create a very compact structure viewed in the radial direction, which also allows the load cell to be inserted into a hole. The connection board can therefore be wired particularly easily from a side opposite the measuring room 13.

The strain gauges 9 to be provided in the force measuring device can be applied to the measuring body 3 using thin-film technology. The arrangement position opposite the measuring room 13 provides optimal protection against damage emanating from the measuring room 13. Furthermore, a temperature-dependent resistance can also be provided on the external device of the measuring body 3, which calculates out or compensates for the expansion and contraction of the measuring body 3, which only occurs due to a temperature fluctuation and has nothing to do with a force measurement.

3 shows a circuit diagram of a Wheatstone bridge, each of which has four strain gauges. A strain gauge 9 is a resistance that is dependent on an expansion or compression of the measuring body 3, so that with a corresponding bridge connection, as shown in FIG. 3, the output voltage UAB depending on the input voltage U0 provides a conclusion about the current expansion or Compression state of the measuring body 3 allows. This means that one strain gauge can be loaded for compression and one for expansion per half bridge, which can be seen in FIG. 3 by the different arrow directions of the arrows shown to the left of the strain gauge. This enables improved sensitivity to the force applied by the measuring body 3. In addition, the strain gauges 9 with the same type of load are arranged diagonally opposite one another in the two half bridges. This results in a maximum sensitivity to the introduction of force where k is the amplification coefficient of the strain gauges 9.

According to an optional modification of the invention, it can also be provided that not only the strain gauges 9 are applied to the outside of the measuring body 3 using a generative method, for example thin-film technology, but that both the front body 1, the transmission sleeve 2 and the measuring body 3 was also produced using a generative manufacturing process.

4 is a top view of the outside of the measuring body 3, so that the several strain gauges 9, the contact surfaces 11 and the temperature-dependent resistor 10 can be clearly seen. You can also see the transmission sleeve 2, which increases in cross-section, and the outwardly extending flange section 7, which is flush with the front body 1.

Claims (14)

1. Load cell for determining point and/or surface forces, comprising: an elastically deformable front body (1) for contacting a force to be determined on an outside of the front body (1), a transmission sleeve (2), which, with an end face facing the front body (1), contacts a circumferential area on an inside of the front body (1) opposite the outside, preferably a circumferential edge area on the inside of the front body (1), an elastically deformable measuring body (3), which is arranged on an end face of the transmission sleeve (2) facing away from the front body (1), wherein the inside of the front body (1) and/or the inside of the measuring body (3) facing the front body (1) is/are designed such that the two inside sides of the front and measuring body (3) touch each other, and with a force measuring device comprising a plurality of strain measuring sensors (9), the strain measuring sensors (9) being arranged on the outside of the measuring body (3) facing away from the front body (1), characterized in that the transmission sleeve (2) has a cross section that tapers from the front body (1) towards the measuring body (3). 2. Load cell according to claim 1, wherein the transmission sleeve (2) has a radially outwardly projecting flange (7) on its end portion facing the front body (1), which is preferably formed continuously in the circumferential direction. 3. Load cell according to one of the preceding claims, wherein the transmission sleeve (2) has a radially inwardly extending transition region between its two front end sections, which is preferably formed continuously in the circumferential direction. 4. Load cell according to one of the preceding claims, wherein the strain measuring sensors (9) are strain gauges which have a high k-factor of 4.5 to 5.5 and / or consist of titanium oxynitride. 5. Load cell according to claim 4, further with a temperature-dependent resistor (10) on the outside of the measuring body (3) to compensate for a temperature influence of the measurement carried out by the force measuring device. 6. Load cell according to one of the preceding claims, wherein the front body (1), transmission sleeve (2) and measuring body (3) are rotationally symmetrical to a common axis (19), preferably each being arranged coaxially to this axis (19). 7. Load cell according to one of the preceding claims, wherein the outside of the front body and / or the outside of the measuring body (3) is / are flat. 8. Load cell according to one of the preceding claims, wherein the inside of the front body (1) rises towards its center towards the measuring body (3) and / or the inside of the measuring body (3) rises towards its center towards the front body (1) rises, with a radially extending space (5) remaining between the transmission sleeve (2) and the mutually contacting insides, preferably with the inside of the measuring body (3) penetrating and/or penetrating a central recess in the front body (1). 9. Load cell according to one of the preceding claims, wherein at least one electrical connection to the force measuring device can be made axially, preferably via contacting surfaces (11) arranged on the outside of the measuring body (3). 10. Load cell according to one of the preceding claims, wherein the front body (1), the transmission sleeve (2) and / or the measuring body (3) is made of a metal, preferably martensitic steel 1.4542 or 1.4548 or the nickel-based alloy Inconel 718, the chemical thereof Composition of 50.0 - 55.0% Ni, 17.0 - 21.0% Cr, 4.75 - 5.50% Ta + Nb, 2.80 - 3.30% Mo, 0.65 - 1, 15% Ti, 0.20 - 0.80% Al, <~>0.3% Cu, <~>0.08% C, <~>0.35% Si and <~>1.0% Co . 11. Load cell according to one of the preceding claims, wherein the thermal expansion coefficient of the front body (1), transmission sleeve (2) and measuring body (3) is identical or deviates by less than 5% from the nominally largest expansion coefficient. 12. Load cell according to one of the preceding claims, further with a connection board (14) which is arranged on the outside of the measuring body (3), preferably wherein the connection board (14) is cohesively connected to the outside of the measuring body (3). 13. Load cell according to one of the preceding claims, wherein the strain measuring sensors (9) have been applied to the measuring body (3) using thin-film technology. 14. Load cell according to one of claims 5 to 12, wherein the temperature-dependent resistor (10) has been applied to the measuring body using thin-film technology.