WO2011035818A1 - Method and apparatus for carrying out hardness tests on tablets - Google Patents

Abstract

A method for determining the hardness of solid samples and an apparatus for carrying out said method are described. In the method, a solid sample (6) is conveyed on a support (3) between breaking jaws (1) and a stop (2). The method is distinguished by the fact that a light emitter (4) emits parallel light in the direction of the solid sample (6) and a line sensor (5) detects the parallel light and/or the absence of the parallel light. The orientation of the solid sample (6) is then determined on the basis of the parallel light detected by the line sensor (5) and/or on the basis of the absence of the parallel light detected by the line sensor. The breaking jaws (1) and the stop (2) and/or the support (3) are then rotated about an axis, which runs through the support (3) and is arranged perpendicular thereto, until the breaking jaws (1) and the stop (2) have reached the position intended for measurement with respect to the solid sample (6). Finally, the hardness of the solid sample (6) is determined by moving the breaking jaws (1) towards the stop (2) and measuring the force required for this purpose.

Description

 Method and device for carrying out hardness tests on tablets

The present invention relates to a method and apparatus for performing a hardness test on solid substance samples such as tablets. It is in particular the necessary for carrying out the hardness test alignment of the solid substance sample on a support. Devices for testing the physical properties of objects, for example, of shaped substance samples, such as tablets, for quality control and characterization are known in a great variety of designs. In the vast majority of cases an always constant orientation of the object in relation to the test or measuring device is indispensable because of the reproducibility of the test result. In the pharmaceutical industry, such devices are used, for example, in the quality control of solid drug forms. The determination of dimensioning, hardness and other parameters is of great importance for the quality assurance due to the strict quality requirements in the pharmaceutical sector.

In the hardness testing of tablets is usually a load cell is used, which consists essentially of a break jaws and a stop. For the fracture test, the tablet is moved onto a test bench between the jaw and the stop, whereby it is important for a reproducible measurement that the force be applied along a defined tablet axis. Therefore, not only the position but also the orientation of the tablet during the fracture test is important. In most tablet forms, the orientation of the tablet longitudinal axis is aimed at at right angles to the pressure surfaces of the breaking jaws and stop, ie the surfaces which come into contact with the tablet, for the fracture test. In order to avoid that the tablet must be pushed from the break jaw to the stop, which can lead to a rotation of the same, the tablet te preferably positioned at the stop, or the stopper is moved up to the tablet before the test. If the tablet is correctly positioned and aligned, the break jaw is moved against the stop, thereby measuring the force required to break.

From the prior art a variety of means for positioning and alignment of tablets are known. These include, for example, slide or rake. For aligning elongated tablets, parallel, counter-rotating rollers are also used. However, these agents are not able to reliably align all tablet forms.

From the patent US 5,555,768 a device is known in which a slider conveys the tablet to be tested on the test table, which is designed as a hub. Before the fracture test, the position and orientation of the tablet is determined by means of a camera arranged above the test table. Subsequently, the turntable is rotated until the tablet axis along which the force is to take place during the fracture test has reached the desired orientation. Then the stopper is moved up to the tablet and finally the fracture test is carried out by contact with the breaker jaw.

The patent EP 0 983 495 B1 likewise discloses a device for carrying out hardness tests, in which, in a first step, the tablet is transported onto the test table and then the spatial position of the tablet is determined, for example, by means of a camera. Subsequently, the jaws and stop are moved relative to the (unchanged in its position on the test table) specimen that the direction of movement of the jaw with the preferred axis of the tablet matches. Under preferential axis is to be understood that axis along which the hardness test is to be performed. The stop is then placed in the immediate vicinity of the specimen, before finally driven the break jaw against the stop and measured the force used to break. While agents which move the tablet relative to the support, are usually not able to reliably align all tablet forms, the latter inventions (US 5,555,768, EP 0 983 495 B1) are unnecessarily complex. The cameras used to determine the orientation of the tablet produce a large amount of data that must first be processed by a computer before the positioning of the load cell can occur. The computer must identify an object (tablet) in an area of pixels, ie it must be able to distinguish the object from the background and determine its physical limits. This places quite high demands on the software used and the hardware used to carry out the calculation. Subsequently, it must be determined where the tablet axis lies, along which the force is to be applied during the fracture test. The high cost associated with these steps has a negative impact on throughput. In particular, in the hardness testing of tablets, the speed at which the test can take place is a decisive factor, since the number of substance samples to be tested is high.

It is therefore an object of the present invention to provide an apparatus and a method which allow to perform hardness tests on solid substance samples with high accuracy and speed. Other objects and advantages of the subject invention will be apparent from the description.

This object is achieved by a method according to claim 1 and an apparatus according to claim 6.

This is in particular a method, preferably an automatic method, for determining the hardness of solid substance samples, wherein

a solid substance sample is conveyed onto a support between a breaking jaw and a stop, and

- The hardness of the solid substance sample is determined by the break jaw moved towards the stop and the necessary force is measured, the method is characterized in that additionally at least sending out parallel light in the direction of the solid substance sample from one or more light emitters,

 the parallel light and / or the absence of the parallel light (i.e., preferably the shadow cast by the substance sample on the line sensor) is detected by one or more line sensors,

 the orientation of the solid substance sample is determined on the basis of the parallel light detected by at least one line sensor and / or on the basis of the absence of the parallel light detected by at least one line sensor,

- The break jaw and the stopper and / or the support are rotated about an axis which passes through the support and is arranged perpendicular to this until the breaking jaw and the stop against the solid substance sample have reached the position intended for measurement, before finally the Hardness of the solid substance sample is determined.

In contrast to methods known from the prior art and in which an image of the tablet has to be created, in the simplest case only one cell-shaped section (one dimension) of the tablet is scanned in the method according to the invention for determining the orientation of a tablet. As a result, the possible measuring speed compared to the use of a camera and thus the processing of an area (two dimensions) of pixels is substantially increased by means of evaluation electronics. Furthermore, a device according to the invention is considerably cheaper to operate and to manufacture. Contributing to the price of the sensor, as well as the price of the transmitter and the operating costs, ie. et al the costs for the evaluation of the sensor data.

In addition, the use of parallel light eliminates the need to focus, which also results in a substantial time savings. This means that the line sensor only needs one measurement at a time, whereas a camera - depending on the distance of the tablet - first focuses and only then can sharply image or measure the tablet. Will the Border areas of the tablet, namely blurred, suffers the measurement accuracy.

The light sensor part of a line sensor, i. the line-shaped arrangements of light sensors (hereinafter: "sensor line") is preferably less than 100 μm, and in particular less than 10 μm or less than 5 μm wide The line sensor measures with its sensor line preferably no gray levels, but performs only a light / dark rating Compared to a camera that provides analog data, this means a huge reduction in the amount of data and thus a substantial acceleration of the measurement process If no focusing takes place, ie, in contrast to the camera, no test images have to be produced and evaluated and no readjustment is necessary, the amount of data is further reduced.

Of particular importance is a method called, when both the break jaw and the stopper and the support are rotated about an axis which passes through the support and is arranged perpendicular to this. The rotation of the support has the advantage that it is easier to accomplish apparatus. However, it has the disadvantage that the solid substance sample can change its position due to the low friction and the inertia during the movement. It may therefore be advantageous to first rotate the overlay to approximate the position of the break jaw and abutment of the position intended for measurement (in relation to the solid substance sample). Subsequently, the break jaw and the stopper can be rotated to bring them to the position intended for measurement. It is preferred if the angle of rotation of the support is greater than the angle of rotation of the break jaw and the stop.

As described, the hardness of the solid substance sample is determined by the break jaw moved towards the stop and the necessary force is measured. The term "force" is preferably used to describe the force itself or Guided sizes are understood. However, it may also be preferred if the term "force" is understood to mean other quantities which allow a conclusion to be drawn about the hardness of the solid substance sample; in particular, these quantities are proportional to the force.

The orientation of the solid substance sample is determined, as mentioned above, on the basis of the light detected by the line sensor and / or on the basis of the absence of the parallel light detected by the line sensor. It is not an object of the present invention to set out in detail which type of evaluation is used for this purpose. The person skilled in the art knows how to determine the orientation of the substance sample from data produced by a line sensor. For example, he will use a computer to do this. The person skilled in the art is also able to determine correction data from data on the position of the break jaw and the stop and / or the overlay as well as from the data mentioned for the orientation of the solid substance sample. By means of this correction data, a control of the device can then take place in order to bring the breaking jaw and the stop against the substance sample in the position provided for the measurement. The stop can be fixed. However, it is preferred if the stop - as well as the break jaws - is mobile, so that it can be approached before the endurance test of the solid substance sample.

The object (method / device) according to the invention is particularly preferred if it has one or more of the following features / method steps:

It is preferred that in the method also the dimensions of the solid substance sample are determined on the basis of the light detected by a line sensor. Of particular interest is the height and / or length and / or width of the solid substance sample. Of particular importance is the inventive method, if it is characterized in that at least one line sensor is moved perpendicular to the support and / or that the support is moved vertically, wherein the line sensor is preferably aligned horizontally. In this case, the line sensor passes through the horizontal plane in which the highest point of the substance sample lies, and the height of the solid substance sample is determined on the basis of the parallel light detected by the line sensor and / or on the basis of the absence of parallel light detected by the line sensor. It may also be preferred that the line sensor and / or the support is moved over a distance which corresponds at least to the height of the solid substance sample.

According to a further advantageous embodiment of the invention, it is provided that at least one line sensor and / or the support is rotated about an axis which passes through the support and is arranged perpendicular to this and that the length and / or width and / or height and or orientation of the solid substance sample is determined on the basis of the parallel light detected by the line sensor and / or on the basis of the absence of parallel light detected by the line sensor. It is advantageous if during the rotation per 0.1 -1 degrees, preferably per 0.3-0.7 degrees, a detection of parallel light or a measurement by the line sensor takes place.

The above method is of particular importance when the line sensor is oriented horizontally and, during rotation, is located in a horizontal plane located between the overlay and the highest point of the compound sample, it being preferred that the line sensor be rotated during the scan Rotation is arranged in a horizontal plane, which is located in the middle between the support and the highest point of the substance sample. It can also be advantageous if the line sensor is arranged during the rotation in a horizontal plane, which forms a sectional area of maximum area with the substance sample. Methods as described are preferred when the line sensor is horizontally aligned and there is at least one other line sensor that is vertically aligned. According to one embodiment of the invention, at least the height of the solid substance sample can be determined on the basis of the parallel light detected by the vertically arranged line sensor and / or on the basis of the absence of the parallel light detected by the vertically arranged line sensor. This represents an alternative to the method variant described above, according to which the determination of the height of the solid substance sample is carried out by means of a vertical movement of the line sensor.

Of particular importance is the inventive method, when first the height of the solid substance sample is determined and then the line sensor (either by movement of the line sensor itself or by movement of the support) is moved to that height in which the interface between the solid substance sample and a horizontal plane is maximum. For most tablets or comparable pharmaceutical substance samples, this is half the height, i. the position between the point of contact with the overlay and the highest point of the compound sample. Half the height is therefore also preferred in the context of the present invention. Subsequently, the length and width and / or the orientation of the solid substance sample can be determined as described above.

According to a further preferred embodiment of the method, the solid substance sample is positioned by means of a positioning unit (eg slide) on the support and / or transported on the support. It may be preferred if the positioning unit strips off the support and / or the break jaw and the stop after the measurement. For this purpose, the positioning unit is preferably movable horizontally and vertically. According to one embodiment of the invention, the positioning unit is designed as a ring. This cleans the two jaws after the measurement by a horizontal movement over the support and thereby removes the remainder of the tablet from the support (see exemplary embodiment). The tablet can also be weighed on the pad. It may therefore be preferred if the support is designed as a balance for this purpose.

The invention also includes an apparatus for determining the hardness of solid substance samples, which has at least the following features:

 - an edition,

 - at least one breaking jaw,

 - at least one stop,

wherein the breaking jaw and the stop and / or the support are rotatable about an axis which runs through the support and is arranged perpendicular to the latter,

 one or more light emitters emitting parallel light, and

 - One or more line sensors. The article (method / device) according to the invention is particularly preferred if it has one or more of the following features:

The light emitters are preferably punctiform light sources such as laser diodes.

Said light emitter and / or the line sensor is preferably arranged laterally of the support and preferably aligned horizontally. The light emitter is preferably located opposite the line sensor, and it is preferred that the light emitter and the line sensor be on opposite sides of the overlay. In particular, it may be advantageous if the light emitter and the line sensor are mounted so that the parallel light of the light emitter can pass directly to the line sensor. However, it is also possible that the light emitted by the light emitter light is deflected by optical elements, before it is detected by the line sensor.

The number of line sensors is preferably 1, 2, 3, 4 or 5. If in this application of "line sensor" is mentioned, then this is the line sensor or its associated sensor line to understand. In an advantageous embodiment of the invention, each sensor line has at least 50%, in particular at least 80%, of its length a distance from the optional additional sensor lines. This distance is preferably greater than the width of the sensor line or it is at least 0.1 mm or at least 0.2 mm or at least 0.5 mm or at least 1 mm.

The device can be characterized in that at least one line sensor is movable perpendicular to the support and / or that the support is vertically movable, wherein the line sensor is preferably aligned horizontally. The line sensor and / or the support is preferably movable vertically over a distance which corresponds at least to the height of the solid substance sample. According to a further embodiment, the device can be characterized in that at least one line sensor and / or at least one light emitter and / or the support is rotatable about an axis which extends through the support and is arranged perpendicular to this. Preferably, break jaws, stop, light emitter and line sensors are arranged so that they are movable together.

At least one light emitter and / or at least one line sensor can be movable. In particular, it is preferred if at least one side of the support arranged light emitter and / or line sensor is designed to be vertically movable and if at least one side of the support arranged light emitter and / or line sensor is rotatable about an axis which extends through the support and arranged perpendicular to this is. This makes it possible first to determine the height of the solid substance sample (see method above) before the light emitter or the light sensor is moved to half the height of the substance sample and then the substance sample is orbited to determine the orientation and the length or Width of the same to determine. Of importance for the present invention may be an above-mentioned device even if the line sensor is oriented horizontally, preferably at least one further line sensor is vertically aligned. It is preferred if the device has a positioning unit for positioning the solid substance sample on the support and / or for transporting the solid substance sample onto the support, wherein the positioning unit is preferably arranged and configured such that it supports the support and / or the break jaw and can strip off the stopper and / or so that it can remove the solid substance sample or parts thereof from the pad.

The device may have a balance. In particular, the support may be a weighing plate.

According to a preferred embodiment, the device has at least one evaluation electronics (for example a computer or a microcontroller) or at least one interface for connection to an evaluation electronics. To evaluate the data produced by the line sensors, calculations are necessary that can be performed by this evaluation. From the data of the line sensors and data on the position of the break jaw and the stop, the evaluation electronics can determine correction data. By means of this correction data, it is then possible for the evaluation electronics to control the rotation of the breaking jaw and of the abutment and / or the rotation of the support, so that the breaking jaw and the abutment with respect to the solid substance sample reach the position intended for the measurement.

The position of the break jaw and the stop provided for the measurement depends on the axis along which the force is to be applied to the solid substance sample. This in turn depends on the shape of the substance sample. This is usually the longitudinal axis of the substance sample. The jaw and stop must be aligned parallel to the axis of the substance sample before the measurement. The solid substance sample is preferably a compressed substance sample and / or a pharmaceutical substance sample and / or a drug formulation and / or a tablet or a capsule or a suppository or a dragee. However, the solid substance sample may, for example, also be a detergent tablet or a fertilizer tablet.

The subject matter according to the invention is explained below with reference to drawings and an example, whereby the invention is of course not limited to the embodiments shown or described there.

1 to 7 show a device according to the invention in various stages of carrying out a hardness test on a solid substance sample (here: tablet). The illustrated process of hardness testing also includes the prior determination of the orientation of the tablet and its measurement. Figs. 1, 4, 5, and 7 are shown in plan view, while Figs. 2, 3 and 6 represent the side view of a device according to the invention.

example 1

1, 2, 3, 4, 5, 6 and 7 show the performance of a hardness test on a solid substance sample (here: tablet) with prior determination of the orientation and measurement of tablet dimensions. The measuring station (see Fig.1, top view) with break jaws (1), stop (2), support (3), light emitter (4) and line sensor (5) is placed in the test device below the pan (not shown), so that After weighing, the tablets can fall into the measuring station. After the tablet has been weighed in the weighing station, the positioning unit (7) is moved down. The weighing pan is opened and the tablet (6) falls into the positioning unit (7). As shown in Figure 2 (side view), the positioning unit (7) then moves to the upper position. The measuring unit with the line sensor (5) and the light emitter (4) is moved upward to detect the highest point of the tablet (6) and thus also to measure the thickness (ie height) of the tablet (6). Then the measuring unit moves to the middle (half height) of the tablet (6) (Figure 3, side view). 4 shows how the complete unit with break jaws (1), stop (2), light emitter (4) and line sensor (5) 360 ° around the support (3) is rotated. During this rotation, the width and the length of the tablet (6) are measured and the position / orientation of the tablet (6) on the support (3) is detected. As shown in Fig. 5, the break jaw (1) and the stopper (2) are positioned in the longitudinal direction of the tablet (6). The stop (2) is first moved up to the tablet (6) before the break jaw (1) presses the tablet (6) against the stop (2) and breaks them. Finally, FIGS. 6 and 7 respectively show, in side view and top view, how the broken tablet (6) is removed from the support by means of the positioning unit (7), thus making the device ready for a new measurement. This also means that the positioning unit (7) is shut down. This then pushes the tablet fragments into a waste container (not shown) and simultaneously strips the break jaw (1), the stop (2) and the support (3), or cleans them.

LIST OF REFERENCE NUMBERS

1 baking jaws

 2 stop

 3. Edition

 4 light emitters

 5 line sensor

 6 solid substance sample

7 positioning unit

Claims

claims

1 . Method for determining the hardness of solid substance samples, wherein

a solid substance sample (6) is conveyed onto a support (3) between a breaker (1) and a stop (2), and

 the hardness of the solid substance sample (6) is determined by moving the breaking jaw (1) towards the stop (2) and measuring the force required for this,

characterized in that additionally at least

emitted by one or more light emitters (4) parallel light in the direction of the solid substance sample (6),

 by one or more line sensors (5) the parallel light and / or the absence of the parallel light is detected,

 the orientation of the solid substance sample (6) is determined on the basis of the parallel light detected by at least one line sensor (5) and / or on the basis of the absence of the parallel light detected by at least one line sensor,

 - The break jaw (1) and the stop (2) and / or the support (3) are rotated about an axis which passes through the support (3) and is arranged perpendicular to the latter until the break jaw (1) and the stop (2) with respect to the solid substance sample (6) have reached the intended position for measurement.

2. The method according to claim 1, characterized

- That at least one line sensor is moved perpendicular to the support, wherein the line sensor is preferably aligned horizontally, and

 - That the line sensor thereby passes the horizontal plane in which the highest point of the substance sample is and

in that the height of the solid substance sample is determined on the basis of the parallel light detected by the line sensor and / or on the basis of the absence of the parallel light detected by the line sensor.

3. The method according to any one of claims 1 to 2, characterized

- That at least one line sensor and / or the support is rotated about an axis which passes through the support and is arranged perpendicular to this and

in that the length and / or width and / or height and / or orientation of the solid substance sample is determined on the basis of the parallel light detected by the line sensor and / or on the basis of the absence of the parallel light detected by the line sensor.

4. The method according to claim 3, characterized

 - That the line sensor is aligned horizontally and

 - That the line sensor is disposed during the rotation in a horizontal plane which is located between the support and the highest point of the substance sample, wherein it is preferred that the line sensor is disposed during the rotation in a horizontal plane extending in the middle between the Edition and the highest point of the substance sample is located.

5. The method according to claim 3, characterized

 - That the line sensor is aligned horizontally and

- That at least one further line sensor is vertically aligned and

 in that at least the height of the solid substance sample is determined on the basis of the parallel light detected by the vertically arranged line sensor and / or on the basis of the absence of the parallel light detected by the vertically arranged line sensor.

6. Device for determining the hardness of solid substance samples, characterized in that the device has at least the following features:

- an edition (3),

 - at least one breaking jaw (1),

at least one stop (2),

the breaking jaw (1) and the stop (2) and / or the support (3) being rotatable about an axis which runs through the support (3) and is arranged perpendicular thereto, one or more light emitters (4) emitting parallel light, and

- One or more line sensors (5).

7. The device according to claim 6, characterized in that at least one line sensor is movable perpendicular to the support, wherein the line sensor is preferably aligned horizontally.

8. Device according to one of claims 6 to 7, characterized in that at least one line sensor and / or the support is rotatable about an axis which extends through the support and is arranged perpendicular to this.

9. Apparatus according to claim 8, characterized in that the line sensor is oriented horizontally, wherein preferably at least one further line sensor is vertically aligned.