DE2261963C2 - Device for displaying changes in the thickness of objects which can be advanced on a path - Google Patents

Description

Measure. These changes are measured and evaluated

Proceeding from this, the object of the invention is to design a capacitive device of the type mentioned at the beginning so that changes in the thickness of objects can be measured independently of their own weight or their weight per unit length. The solution to this object is achieved in a device of the initially mentioned ^{| n} Gattupg according to the invention characterized in that the is arranged on one side of a fixed path of the articles scanning electrodes comprises of flexible material and a pressing device is arranged on the other side of the web ·

Such a design of the device results in a very high measurement accuracy, regardless of Due to their shape and weight, the objects to be measured are straight on the fixed path and not about rubbing on the electrodes They are by the pressing device on one side of the web against the one on the electrodes located on the other side, whereby these are flexible. This is a constant position of the to measuring objects directly in contact with the ^ electrodes. The one between them The field is thus only determined by the thickness of the objects to be measured and not by their position influenced relative to the electrodes, whereby the measuring result '·. would be falsified. »

Appropriate refinements form the subject of the subclaims.

The invention will now be described further using the example of the embodiment shown in the drawing. Thereby λι

F i g. I a partial side view of the device according to the invention,

F i g. 2 a plan view of the device,

F i g. 3 a cross section along the line 3-3 of FIG. «Ο

F i g. 4 is a partial side view showing part of the scanning device of the device according to FIGS Fig.) To 3 illustrated in effective contact with a container to be tested.

Fig. 5 is a schematic Diagra nm of an electrical view Circuit included in the device according to the invention.

F i g. 6 is a schematic view showing part the mode of operation dt "device according to the Invention illustrates, and

F i g. 7 A partial side view, soft one modified embodiment of the scanning device of the device according to the invention illustrated.

The device according to the invention is intended in particular for displaying changes in the wall thickness of a container made of glass or similar dielectric material, which is denoted by 10 in FIGS. A conveyor belt 12 or other equivalent means is provided to move a series of containers 10 to an inspection station in the vicinity of the apparatus. Of course, the device could also be moved along a series of stationary containers 10 for the purpose of successive action on the same, if this is desirable and practicable. The apparatus includes a scanning device ⁵ *, which consists of a plurality of electrodes 14 made of flexible conductive material. In the embodiment shown, two scanning devices 13a and 136 are provided, which are arranged at a perpendicular distance from one another, or in other words, at an axial distance relative to the axis of the container 10. Each of the electrodes 14 preferably consists of a strip of elastic or resilient metal, such as the Example spring steel In addition, the electrodes 14 are attached to the test station by devices consisting of bracket units 16a and 166, which in turn are slidably and adjustably connected to a post 17 which is attached to the test station or otherwise fixedly arranged this connection consists of bolts 18a and 186 which extend through corresponding contactors 19a and 196 in brackets 16a and 166, respectively, and are screwed into post 17. When bolts 18a and 186 are tightened so that their heads or washers carried by them contact brackets 16fr and 166, they are held in a fixed position relative to post 17. When the bolts 18a and 186 were loosened; this position can be set and the new position determined by tightening the bolts again, as can be easily seen

Like i i g. Figure 4 shows more clearly, each electrode 14 is arranged in a manner which enables it to form the same bends and conforms to the shape of the surface of the container 10 when it is in frictional contact with electrodes 14. In the preferred embodiment, each bracket includes 16 a part 22, which is spaced apart pointed projections 23 has the tips of the Strip 14 touching, creating a space between strip 14 and the main part of the bracket

16 is formed. The strips 14 are on the opposite ends thereof by appropriate fasteners such as screws 24. attached, which also allow a connection of electrical lines to the electrodes 14, such as will be described in more detail below.

The device according to the invention also has devices at the test station which the container 10 bring into frictional contact with the electrode K and which the container 10 about its vertical axis turn. In the preferred embodiment, a yoke-like arrangement is provided which consists of a There is a pair of wheels 25 which are rotatably arranged on a plate 27 or an arm, which in turn is on Post 17 is attached in close proximity to the surface of the conveyor belt 12. The wheels 25 are in the Spaced apart so that they hold the container 10 near the lower end of the same be.ühieti. The yoke-like arrangement also includes a Pair of wheels 29, which are rotatably arranged on a plate 30 or an arm, which is also on the post

17 and is attached at a vertical distance from the arm 27. The wheels 29 are at a smaller distance arranged from each other than the wheels 25, so that they the container 10 in the vicinity of the relatively narrow Touch part of the neck. A fast rotating wheel or disc 32 is arranged so that they the When in the yoke arrangement of wheels 25 and 29, container 10 contacts the wheel 32 is by a white! λ 33 with a (not shown) Drive device connected, which rotates the same. It can be seen that as the wheel rotates 32 the container 10 is also rotated about its vertical axis. The peripheral edge of the wheel 32 can be made from

consist of a material which increases the frictional engagement between the wheel 32 and the container 10, but which does not scratch or damage the surface of the container. The device is also with a corresponding device is provided which the yoke arrangement of the wheels 25, 29 together with the Scanning device 13 moved away from the container 10, so that the container leave the test station and the the next container can be arranged in the same. The post 17 can, for example, on the <o Be attached to the rod of a hydraulic cylinder. However, such mechanical arrangements are the Known to those skilled in the art, so that a detailed description thereof does not appear necessary.

The scanning device 13a is connected to a display device 39a by a coaxial cable 40a. The display device 39a consists of an electrical circuit for generating a signal corresponding to changes in the wall thickness of the container 10 which exceed a predetermined value. In a similar manner, the scanning device 13i is connected by a coaxial cable 406 to a corresponding display device 396, which consists of a circuit for generating similar signals. The outer conductor of each coaxial cable, such as cable 40a, is connected to each of the outer electrodes 14, the connection being made by the corresponding screws 24. The inner conductor of the cable 40a is connected to the central electrode 14 of the scanning device 13a. An identical Jo connection is provided between the cable 40b and the corresponding electrodes 14 of the scanning device 136.

F i g. Figure 5 shows in more detail a preferred embodiment of one in the device according to the invention contained electrical circuit for generating a signal when the wall thickness of the container 10 deviates from a predetermined standard beyond the tolerances. I and 2 shown coaxial cable is denoted by 40. Of course, a circuit similar to that of FIG. 5 is similar in each scanner, as will be described in more detail below. As above described, the cable 40 has an inner conductor 41 connected to the central electrode 14 and an outer conductor 42 connected to each of the outer electrodes 14 in the preferred one Embodiment is the cable 40 of the Belden-type 8254. which has a length of approximately 400 mm The cable 40 terminates in a normal connector part 45 which mates with a connector part 46 of the type described When the connection is made, the strips or electrodes are in one together with the cable 40 Feedback bridge portion 50 of the circuit of FIG. 5 included.

The bridge 50 further comprises a feedback transformer which includes a pair of series-connected windings 52 and 53. A capacitor 54 is connected in parallel with the windings 52,53. One terminal of the capacitor 54 is connected through another capacitor 55 to the cathode of a diode 56 and the anode of the diode 56 is connected to the other terminal of the capacitor 54 through a resistor 57. A fixed capacitor 58 is connected in parallel to the diode 56 and a variable capacitors ^ω gate 59 is to the capacitor 58 connected in parallel with the center terminal of the connector part 46, which is connected when engaged with the connector part 45 to the inner conductor 41 of the cable 40, is connected by a line 61 to the capacitors 58 and 59 at the junction point thereof which is connected to the anode of the diode 56. The outer terminal of the connector 46, which is conductively connected when engaged with the connector 45 to the outer conductor 42 of the cable 40, is connected to a line 62 which is at a reference or ground potential for the circuit.

The signal generated by the feedback bridge 50 is through a capacitor 64, of which one terminal is connected to line 61, coupled to the input of a two-stage /.C oscillator, the in Fi g. 5 is designated very generally with 65. Of the Oscillator 65 contains a field effect transistor 66, which has a blocking terminal 67 and charging and discharging terminals 68 and 69, respectively. The blocking terminal 67 is connected to the capacitor 64 of the feedback bridge 50 and connected through a resistor 70 to the connection point of the transformer windings 52 and 53. The charging terminal 68 is through the parallel connection of a charging resistor 72 and a Capacitor 73 connected to a line 74 for the purpose of connection to another circuit stage, and by a line 75 having a point which is the resistor 70 and the connection point of the transformer windings 52.53 is common

The oscillator 65 further comprises a transistor 78, whose base terminal is connected by a line 79 to the discharge terminal 69 of the transistor 66. the The collector terminal of the transistor 78 is through a line 80 to the ground or reference potential line 62 tied together. The emitter terminal of the transistor 78 is through the parallel connection of a resistor 82 and a capacitor 83 is connected to one terminal of a resistor 84 and to a line 85 for connection to another circuit stage. The other terminal of resistor 84 is connected to the Discharge terminal 69 of transistor 66 connected.

The oscillator 65 is connected by the line 85 to a circuit section 90, which in turn Connected by a line 91 to a power supply line is generally indicated at 92 in FIG is designated. Power supply 92 also provides a source of synchronizing pulses for synchronizing the mode of operation of various sections of the circuit of Fig. 5, as would be appreciated by those skilled in the art is easy to understand. Circuit 90 acts as a decoupled power source and includes a first Transistor 94, the base terminal of which is connected to the line 91 and the emitter terminal of which is connected by a Resistance% is connected to ground potential line 62. The collector terminal of transistor 94 is switched off The circuit 90 also contains a second transistor 98, the base terminal of which with the Emitter terminal of transistor 94 is connected. The collector terminal of transistor 98 is connected to the line 85 and its emitter terminal is connected to line 91 through a resistor 99 tied together.

The circuit of Figure 5 also includes a Transistor 102, the base terminal of which is connected to line 85 from oscillator 65 by a line 103 The collector terminal of transistor 102 is off and the emitter terminal is on line 74 tied together. The transistor 102 therefore acts in a manner similar to a zener diode to a DC coupling to effect.

The circuit of FIG. 5 also contains a Darlington circuit which consists of a first transistor 105, which forms the transistor output stage, and a second transistor 106, which forms the amplifier stage. The base terminal of the transistor 105 is connected by a line 107 to the line 74 and to the emitter of the transistor 102. The collector terminal of the transistor 105 is connected through a resistor 108 to the line 91 from the power supply 92. The emitter terminal of the transistor 105 is connected to the ground potential line 62 by a capacitor C9 and to the base terminal of the transistor 106 by a line 110. The collector terminal of transistor 106 is connected through resistor 112 and line 113 to power supply 92 and the source of the synchronizing pulses. The emitter terminal of the transistor 106 is connected through a resistor 115 to a line HS, which is sui reference or ground potential. A capacitor 117 is connected between the base terminal of the transistor 106 and the ground potential line 116.

The output of the amplifier transistor 106 is connected to an isolating stage, which consists of a transistor 120 and the series connection of the resistors 121 and 122. The base terminal of the transistor 120 is connected to the collector terminal of the transistor 106 and the collector terminal of the transistor 120 is connected to the line 113 connected. The emitter terminal of transistor 120 is connected to line 116 through resistors 121 and \ i2.

The circuit of FIG. 5 finally contains a control section for actuating a very generally with 125 designated exclusion device in a regulated manner. A solenoid 126 is with the device

125 operatively connected as indicated by broken line 127 to one terminal of the solenoid

126 is by line 128 to power supply 92 and the source of the synchronizing pulses while the other terminal is connected to the anode of a controlled rectifier 130 Control or blocking terminal of the controlled rectifier 130 is through a line 131 to the Connection point of resistors 121 and 122 connected. A capacitor 133 is between the Locking clamp and the cathode of the controlled rectifier 130 switched on. The cathode of the Rectifier 130 is through a Zener diode 135 to the ground potential line 116 and through a resistor 137 connected to line 113. A resistor 139 is connected in parallel with the solenoid 126

A network consisting of fixed resistors 140, 141, 142 and variable resistors 143, 144 exists, is between the line 113 from the power supply 92 and the ground or reference potential line 62 turned on. The switching arm of the variable resistor 144 is connected by a line 146 and a resistor 147 to the cathode of diode 56 in the feedback bridge 50 connected so that a remote voltage tuning of the bridge 50 is performed as will be described in more detail below.

The method according to the invention is d. By Operation of the device carried out in the following manner A container 10 is carried by the conveyor belt 12 moved into a position for testing, whereby the wheels 25 the outer surface of the container 10 in the Near the base or the bottom of the same

while the wheels 29 contact the neck of the container 10. The wheel 32 is in contact with the Container 10 is moved, preferably at a point approximately midway between the top and bottom s end lies. The wheels 25,29 and 32 are arranged so that the outer surface of the container 10 in There is frictional contact with the strip 14 which form the electrodes of the scanning device 13. As in Fig. 4 clearly shown, the strips 14, which are usually straight, will turn around during the test depressed approximately 3.125 mm. This bending of the electrodes 14, which thereby forms part of the container surface include, protects against false readings resulting from the out-of-round shape or from seams on the Surface of the container 10, as will be explained in more detail below.

The scanning device 13, which contains the electrodes 14 which are arranged in frictional contact with the surface as: container 10, forms a capacitive resistance together with the wall of the container 10 and the surrounding air. When the circuit of Figure 5 is energized and the connectors 45 and 46 are engaged, a spreading electric field enters the side wall of the container 10. According to FIG. 6. which shows a portion of the wall of container 10 abutting against strips 14, the outer strip is at one potential and the inner strip is at another potential. The field lines shown roughly indicate the flow that emanates from the plates. The strongest field is of course indicated by the shortest flux lines, which are those in the air gap between the edges of the strips 14. The spreading electric field passes through the wall of the container 10 along the entire circumference of the same when the container is rotated about its axis. Since part of the field passes through air at any time, there are changes in the electrical current through the capacitor

♦ o just from a change in the thickness of the glass. this can be expressed mathematically by the following equation:

t _c = (Vc) {2p>) feA / Ü
* 5 in which means:

I _c the current through the capacitor,
Vc is the voltage across the capacitor,
2 p is a constant,
_M f is the frequency of the voltage,

e is the dielectric constant of the dielectric

Material, such as glass,
A The area of the plates of the capacitor and
D the distance between the plates.

In the device according to the invention the only variables in this equation are the dielectric constant and the current. The dielectric constant of glass is of course about seven times the dielectric constant of air
Changes in the wall thickness of the container 10 produce a change in the capacitive resistance when the container 10 is rotated about its axis, which is detected by the circuit of Fig. 5: to generate an electrical display or a signal,

if the changes exceed predetermined tolerances. The capacitive resistance created by the formed in frictional contact with the wall of the container 10 standing strips 14 and the surrounding air is, represents one leg of the feedback bridge 50 of the circuit of Fig.5. The other Legs of the bridge are connected to windings 52 and 53 by the feedback transformer formed with the other capacitors in circuit section 50. The bridge circuit 50 acts in such that as soon as the through the strips 14, the wall of the container 10 and the surrounding air changes formed capacitive resistance, that is, when the wall thickness of the The container changed, the voltage fed back to the field effect transistor 66 in the oscillator 65 from the positive feedback is changed to negative feedback. Once this feedback voltage from the negative to the positive feedback is changed by the oscillator 65 oscillating signal generated The oscillating voltage appearing on line 74 is generated by the Action of transistor 102 demodulated and then amplified by the darlington circuit and vice versa, which consists of transistors 105 and 106. This signal becomes the controlled rectifier 130 blocked or switched off whereby the solenoid 126 is de-energized and the exclusion device 125 is rendered ineffective. As long as the wall thickness of the container 10 is accordingly not more than one predetermined norm changed, which is determined by the tuned state of the bridge 50, the circuit of Fig.5 generates an oscillating voltage from the oscillator 65, so that the particular tested container 10 is not excluded.

The feedback bridge section 50 is tuned or adjusted so that a change in the capacitive resistance, which results from a change in the wall thickness of the container 10 stops the oscillating signal usually generated by the oscillator section 65, from which an actuation of the exclusion device 125 results. The capacitive resistance caused by the in Frictional contact with the wall of the container 10 standing strips 14 and the surrounding air is formed appears in the feedback bridge section 50 between the terminal labeled 150 in FIG or point and the terminal or point designated by 151. In other words, this capacitive resistance is connected in parallel to the resistor 57. A relatively thick wall part of the glass container 10 increases the capacitive resistance in parallel with the terminals 150, 151 and a relatively thin wall part of the glass container 10 reduces the capacitive resistance parallel to terminals 150,151. The feedback bridge 50 is matched or adjusted so that when the capacitive resistance is parallel to terminals 150, 151 reaches either a maximum or a minimum value which causes oscillator 65 to fail longer to generate an oscillating output signal. When the capacitive resistance increases parallel to the points indicated by 151 and 152 in FIG either by adjusting the size of the capacitor 59 or by changing the size of the point 153 supplied voltage, for example by setting the potentiometer 144, the oscillator section 65 interrupt the oscillation when a high capacitive resistance in parallel with the terminals 150, 151 If, on the other hand, the capacitive resistance between points 151 and 152 is reduced, either by adjusting the capacitor 39 or by changing the acting on the point 153 Voltage, the oscillator section 65 will stop oscillating when it is relatively lower capacitive resistance appears parallel to terminals 150, 151. If the oscillator section 65 accordingly a change in the wall thickness of the container comes to a standstill, is on the control or Locking terminal of the controlled rectifier 130 a voltage of a magnitude and polarity to act on brought which makes the rectifier 130 conductive. The current flows through the solenoid 126, whereby a conventional lockout device 125 is actuated. The particular container 10 under test therefore becomes locked out.

In accordance with a preferred embodiment of the invention, the capacitor 59 has a range of sizes. ί to! 20 picofarads: .ui. The capacitor 54 has a size of 620 picofarads, the capacitor 55 has a size of 0.01 μμ (ατΛά. The capacitor 58 has a size of 270 picofarads and the capacitor 64 has a size of 56 picofarads. The resistor 57 has a size of 1 Transistor 66 is of the 2N 4302 type, resistor 84 is approximately 12K in size, and resistor 72 is sized to provide a bias current of 125 microamps through resistor 84.

An advantage of the device according to the invention is that a container 10 only because of the Change in wall thickness beyond the tolerances is excluded and not just because of the presence of seams or the non-circular shape of the outer surface of the container. This is upon it due to the fact that the strips or electrodes 14 are in frictional contact with the outer surface of the Container 10, thereby preventing the occurrence of any false signals from the Seams or the out-of-round shape. The greater the degree of bending of the electrodes 14 and the greater the resulting envelope n / "d around the surface of the container 10, the more effective it is Device in preventing false signals.

As shown in Figs. 1 to 3 is shown, contains the preferred embodiment of the device for Check relatively large containers 10 with two scanning devices 13a, 136, which run along the axis of the Container 10 are at a distance from each other. The scanning devices 13a, 136 are by corresponding coaxial cables 40a, 406 connected to indicators or circuits 39a, 396, respectively, each of which that of F i g. 5 is similar. In other words, for the arrangement of the FIGS. 1 to 3 shown Device, two circuit units or channels 39a, 396 are provided, which correspond to the one shown in FIG. 5 shown are similar and each of which includes a solenoid 126 that has a common exclusion device is effectively connected and has a common power supply The speed with which each container 10 is rotated by the wheel 32 is controlled by such factors as that desired speed of the test process and the response of the circuit of FIG. 5.

If the container 10 is relatively smaller, it can it may be desirable to use the device according to FIGS. Modify 1 to 3 so that the same is only one Scanning device contains which 5 electrodes or

Has strips 14, instead of two scanning devices with three strips each. The most sensitive area of each scanning device 13 below the strips 14 are the air gaps between the strips. If two Scanners, each of which contains three strips or electrodes, on a relatively smaller one Containers are used, two strips that are connected to ground or reference potential would be attached to each other adjoin. By using a single scanning device containing the five strips, the most sensitive areas can be arranged at a distance of approximately 6.25 mm from each other and can be made approximately 6.25 mm so that two areas of the container are monitored on each channel can be, which results in more symmetrical measurements and a closer coverage of the container 10.

In Fig. 7 shows a device in which the scanning device contains five strips or electrodes and in which the other components or parts of the device according to FIGS. 1 to 3 are similar. The components of the device according to FIG. 7, which corresponds to those of the FIGS. 1 to 3 are identical, are denoted by reference numerals which are provided with a prime. A container 10 'is therefore moved to a test station adjacent to the device by a conveyor belt 12'. The wheels 25 'and 29' contact the lower and neck portions, respectively, of the container 10 'and a high speed wheel 32' also contacts the container 10 'to rotate the same. Five electrodes or strips 14 'are attached to a bracket 16' by screws 24 '. The strips 14 'are preferably made of resilient metal and are arranged in frictional contact with the outer surface of the container 10' during operation. In addition, the electrodes 14 'are bent to encompass part of the surface of the container. A pair of coaxial cables 160 and 161 are provided to connect different ones of the strips 14 'to a pair of circuits or conduits, each of which corresponds to the one shown in FIG. 5 is similar to that shown. The middle strip and the two outer strips 14 'are connected by lines 162, 164 to the outer conductor or jacket of the corresponding coaxial cables 160 _: 161, the outer conductors of which are in turn grounded in a manner similar to the outer conductor 42 of the circuit shown in FIG G. 5 shown cable 40. The remaining two strips 14 'are connected by lines 166, 167 to the inner conductors of the cables 160 and 161, respectively.

For this purpose 4 sheet 2 drawings

Claims (7)

Claims: movable objects made of dielectric material with one of the objects 1. Apparatus for displaying changes which can be applied to a scanning device made of conductive material, in the thickness of that which can be advanced on a path with the object and the surrounding air Objects made of dielectric material with a 5 forms a capacitive object, with one on the electrical measurement scanning device connected to the scanning device which can be placed on one of the objects Made of conductive material with means for generating a signal in accordance with the object and the surrounding air a change in capacitive resistance and with forms a capacitive object, with one to the one of a feed device for moving the Scanning device connected electrical io objects along the scanning device. Measuring device for generating a signal after. One application of such a device is that Determination of the change in the capacitive resistance test of the wall thickness of on automatic presses Standes, and with a feed device for shaped glass bodies after their cooling, though Moving the objects along the scanning device for testing other objects as well Device, characterized in that «5 made of a similar dielectric material is used which can be verden on one side of a solid track (12). In the manufacture of glass bodies are Objects (10) arranged scanning device to separate and excrete those whose wall thickness electrodes (14) made of flexible material has ke beyond the tolerance in the case of blown and on the other side of the track (12) a glass container has been found that when it is on Pressure device (32) is arranged 20 on one side, it is relatively strong on another 2. Vonrfcwung according to claim 1, characterized marked point is correspondingly thinner If the deviation shows that the electrodes (14) are made of spring metal, the tolerance between the thickest and thinnest parts The container is unacceptable because it is parallel to the path that crosses it Objects (10) run. not or not to withstand the pressure of its contents 3. Apparatus according to claim 1 and 2, characterized in that 25 will have sufficient strength to at a characterized that the measuring device consists: filling process to remain stable. So far, specimens of glass bodies have been made after a) from a bridge circuit, the inductive cooling of its cooling mechanically checked and its wall and capacitive branches contains strength determined. Recently there are electrical b) from a device for connecting the 30 test devices that automatically detect defects Scanning device to the bridge circuit. and weed out the damaged body automatically, so that d: · .- by the scanning device and the. One problem with such devices lies in the Object formed capacitive resistance generation of false electrical signals as a result represents a branch of the bracke and of non-circular shape or of seams or bulges in c) from a device, d »- with the bridge 35 some glass bodies, but which otherwise are connected to one satisfied is to have an output signal to be provided or acceptable wall thickness, generate that by the corresponding to the known is a device of the aforementioned Thickness of the object generated capacitive type (CH-PS 3 55 628) for capacitive measurement of the Resistance is determined. Weight of textile goods per unit of length at 40 of this device are textile threads but at a distance 4. Apparatus according to claim 3 thereby marked one behind the other and alternately different draws that the polarity generating the output signal having capacitor plates pulled. In Device contains an oscillator and that de. "Depending on their weight displace the Bridge circuit a tuning device ent- textile thread a more or less large amount of air holds, so that the presence or absence of a 45 with the dielectric constant 1. In place of the The signal from the oscillator due to the change in the displaced air results in a greater dielectric thickness of the object is determined, which is the constant having test material a target value exceeds the capacitance of the capacitor to a large extent 5. Device according to claim 1 to 4 marked. In this way an electric characterized by an exclusion device, which received with 50 signal, which with appropriate training the measuring device is effectively connected to that of the measuring capacitor and the associated evaluation objects. which means a change in the thickness of the weight per unit length of the to have, under the control of the measuring device measuring textile thread is strictly equivalent. For one to be eliminated. accurate measurement, however, is not enough if that 6. Apparatus according to claim 1, characterized marked 55 test material only by its own weight against the shows that the pressing device (32) is printed on electrodes or capacitor plates, has rotating disk to the objects (10) The known device can only be used to put in rotation. if the weight of the test material per unit of length 7. Apparatus according to claim 1 to 6, is to be measured thereby and thus only in one characterized in that the longitudinal axes of the electrical 60 narrow tolerance range is variable. the (14) relative to the axis of the objects (10) in the known is also a device for displaying generally stand vertically. Changes in the thickness of glass containers in which the containers are automatically fed in and removed from the Containers deviating from the standard are sorted out (US-PS «33 93 799). To do this, the glass containers are through a electromagnetic field carried out. At under- The invention relates to a device for displaying the different wall thicknesses carried out by it Due to changes in the thickness of glass containers on a web, it changes in different ways