DE1423586B2 - Device for testing hollow containers - Google Patents

Description

1 2

The invention relates to a device for An embodiment of the invention is according to

Testing of hollow containers, in particular from standing explained in more detail with reference to the drawing. In

Glass vessels, using one showing the surface of the drawing

of the container scanning measuring element, whose loading F i g. 1 shows a partial view, partly in section

movement is transferred to a differential transformer 5, a scanning device for scanning

will carry, on the output side of which a change of the upper edge of a container,

voltage is generated, the phase and amplitude of which F i g. Figure 2 is a perspective view of a part

depends on the position of the measuring element. the in F i g. 1 scanning device shown,

In the case of containers, for example in the case of glass bottles or Fig. 3 a circuit diagram of a signal amplifier crucible, it is essential for high-speed filling and ver io as well as a phase and amplitude discriminator, closing devices that certain outputs. 4 a circuit diagram of the arrangement for measurements, in particular with regard to the container detection of unevenness in the container edge and edge, are adhered to. This applies in particular to FIG. 5 shows a circuit diagram of the arrangement for the detection of distortions in the container edge in a tightly sealed manner in the case of the container contents.
Draw conclusions. It is known (United States patent specification 15, the device shown in FIGS. 1 and 2 is 2,338,868), for this purpose to use measuring rollers to measure the container edge formed by the opening for checking hollow containers such as glass /, thought to have an open, upper end with buttons. If certain tolerances are exceeded, have a container edge and a contact is actuated on a vertical position and the container 27, which is quite movable, moves into the area of the measuring probe. This means that only containers can be detected.
the whose container edge upwards or downwards In F i g. 1, the measuring device 28 indicates a hub exceeds a certain value. 29, on the underside of which to circulate horizontally

Furthermore, a device for monitoring right axes is parallel to the .Oberseite of the movable the diameter of containers known (German plate 27 and for the execution of a vertical patent specification 1010 746), in which the uppermost and 25 movement rollers 30 are mounted. Each role is 30 lowest limit value, which leads to an ejection of the rotatable in two spaced-apart arms 32 Container leads, stored by a differential transformer of a carrier 31. Each carrier 31 is means is obtained, the one movable, with the measuring shaft 35 mounted in supports 34 for rolling out connected core. In comparison to the execution of a limited rotary movement in lowering The voltage supplied to the differential transformer is arranged in the right direction opposite the hub 29, The supports 34 extend from the underside of the upper and lower limit value one receives a signal hub 29 downwards. Each role 30 as well as her zuzur Disposal of a defective container. associated carrier 31 are by an arrangement

In the case of containers, however, errors also occur in the form of elastically pressed downwards that result from a

of bumps and warps, the 35 of which each carrier 31 is arranged above the shaft 35

Size is within the permitted tolerances between rod 36, which extends through an opening 37 in

see the upper and the lower limit of the hub 29 extends upwards. Between the

which are nevertheless inadmissible. top of each rod 36 and a fixed one

The invention is therefore based on the object of extending the bolt 39 on the upper side of the hub 29

Unevenness and warping of the container edge 4 ° a tension spring 38. The rod 36 touches the

determine by the steepness of a change in side of the opening 37 in the hub 29 to the after

the surface to be scanned of a container downward rotary movement of the carrier and the

will measure. Limit role. The surface of the plate 27 is

According to the invention, this object is thereby achieved exactly perpendicular to the axis of the measuring device 28

solves that a con-45 is arranged on the differential transformer.

The capacitor is connected to the amplitude The movement of one of the rotatably driven the charging voltage proportional to the alternating voltage rolls 30 when the container edge F is scanned of the capacitor two symmetrical, each transferred from one to a test device, the fixed capacitor and an opposing set of projections and warpage of the BeDiode is supplied to existing networks and serves 50 container edge. The other two roles 30 that those on the capacitors of the networks are used as guide rollers to establish a fixed any stresses occurring on a pre-storage of the vessel / on the plate 27 are to be provided, voltage difference lying at a certain value as shown in FIG. 1 is the measuring device speaking triggering device for discarding 28 rotatably mounted on a plate 26, wherein a a container are supplied. 55 shaft 41 carries the measuring device 28. The wave 41

This results in a substantial refinement being rotatable by being kept at a distance from one another

the measurement method. It is now possible to suddenly mount bearings 43, 44 in a housing 42. That

or gradually occurring discontinuities and the upper end of the shaft is supported by a collar 45

to eradications in the surface to be scanned and a nut 46 held in place. On the

know that although within the tolerances at an upper end of the shaft 41 is a pulley 47

Pure measurement of the absolute values lie, so with attached, those of a motor, not shown

the known devices is not yet driven to one with the help of a drive belt.

Rejection of the container would lead, which nevertheless. The shaft 41 is provided with an axial bore 54

should be eliminated, however, because see with them, in which a spindle 55 is arranged, the pre-

the proper sealing of a 65 to be attached, preferably made of plastic or another, does not

Cover is no longer guaranteed. magnetic material is made. The lower

Further advantageous embodiments of the invention end of the spindle 55 is through a bearing 56 with a

are characterized in the subclaims. of the rollers 30 connected. The top of the

The spindle 55 is guided in a plate 58 and is secured against falling by a nut 59. The spindle 55 carries the core 60 of a differential transformer 61 which is of known type and has a primary winding and two secondary windings connected in series in opposite directions. If the core moves to one end of the differential transformer, the voltage induced in the secondary winding arranged at this end increases and the voltage induced in the opposite secondary winding decreases. The signal appearing at the output of the secondary windings is thus proportional to the distance of the core from the electrical neutral position, the signal almost assuming the value zero when the core is in the neutral position. The phase position of the signal is the same as that of the phase position of the alternating voltage feeding the primary winding when the core is shifted in one direction, and is phase shifted by 180 ° when the core is shifted in the opposite direction. The position of the core 60 follows the height of the container edge when it is scanned, with the occurrence of excessive distortions of the container edge, the deflection of the core 60 when scanning a certain circumferential section of the container edge is greater than a certain amount, while when too large unevenness occurs in the container edge a deflection of the core 61 takes place which exceeds a certain value between the lowest and highest point.

If a container is found with excessive warps or protrusions, it will separated via an ejector device, not shown.

In Fig. 3 shows a circuit diagram in which the signal from the differential transformer 61 is amplified in an amplifier and then passed on to a phase and amplitude discriminator. The output of the secondary windings of the differential transformer 61 is connected in parallel to a potentiometer 115 , whose tap 116 with the control grid of one half 117 of a double triode is connected. The amplifier also consists of a second triode 123, a coupling capacitor 122 and the resistors 118, 119, 124 and 126. The amplifier is connected in the manner shown to a transformer 125 , the primary winding of which on the one hand with the positive pole of a DC voltage source and on the other hand with the anode of the Triode 123 is connected.

According to FIG. 3, the signal from the transformer 125 is converted at a capacitor 127 into a direct voltage which is proportional to the amplitude of the alternating voltage. The polarity of the direct voltage on the capacitor 127 is determined by the phase position of the alternating voltage received from the secondary winding of the transformer 125 by comparison with the phase position of the alternating voltage applied to the primary winding of the differential transformer. This reaches the control grid of a triode 130 via a line 129 and the coupling capacitor 128. Resistors 131 and 132 connect the triode 130 to ground. The primary winding of a transformer 133 is parallel to a phase shift capacitor 134 and to the positive pole of a DC voltage source and the anode of the triode 130.

The triode 130 with its associated circuit forms a known amplifier. One connection of the secondary winding of the transformer 133 is connected to the cathodes of two triodes 135, 136 and to the anodes of the diodes of a rectifier tube 137. The other connection of the secondary winding of the transformer 133 connects two resistors 138, 139 and two capacitors 140, 141 . Resistor 138 and capacitor 140 are connected in parallel to the control grid of triode 135 . Resistor 139 and capacitor 141 are connected in parallel to the control grid of triode 136 .

The alternating voltage amplified by the triode 130 results in a current through the triode 135 through a rectifier circuit which consists of the cathode for controlling the grid resistance of the triode 135, the resistor 138, the capacitor 140 and the secondary winding of the transformer 133 . The capacitor 140 is thus charged to a direct voltage which is approximately equal to the peak voltage on the secondary winding of the transformer 133 . The plate of capacitor 140 connected to the grid of triode 135 is negative. Since the capacitor 140 discharges slowly through the resistor 138, the DC voltage on the capacitor 140 remains substantially constant. The voltage appearing between the cathode and the grid of the triode 135 is the sum of the voltage on the capacitor 140 and the respective voltage on the secondary winding of the transformer 133, so that the grid of the triode 135 with respect to the cathode of the triode 135 on a negative Voltage is maintained except for the time that capacitor 140 is charged. The negative voltage on the grid of triode 135 prevents any anode current in triode 135 for most of the testing process. When capacitor 140 is charged by transformer 133 , the grid of triode 135 is non-negative with respect to its cathode, and the anode current can flow through triode 135 provided that the anode of triode 135 is positive with respect to its cathode, which is the case when the voltage of the lower plate of capacitor 127 with respect to that at the upper terminal of the secondary winding of the Transformer 125 existing voltage has a negative potential. The triode 135 is thereby operated as the gate, by the reference voltage of the circuit of the triode 130. The current flowing through the triode 135 anode current flows through the triode 135, the secondary winding of the transformer 125, the left-side diode of the rectifier 137 and the capacitor 127 .

Similarly, triode 136 acts as a gate to charge the lower plate of capacitor 127 in a negative sense. The grid control circuit for the triode 136 is composed of the grid and the cathode of the triode 136, the resistor 139, the capacitor 141 and the secondary winding of the transformer 133 . The capacitor 127 causes a charge in the negative sense through the triode 136, the diode 137 and the secondary winding of the transformer 125 when the triode in the grid circuit is switched "on"

and the lower plate of the capacitor 127 with respect to the upper terminal of the secondary winding of transformer 126 is positive. The top plate of the capacitor 127 is provided with a DC voltage biased.

The fluctuating voltage appearing on capacitor 127 is proportional to the magnitude of the Roller that scans the upper edge of the container. The F i g. 4 shows a cathode amplifier triode 150 λ, the control grid of which with the lower plate of the capacitor 127 is connected and, within certain limits, a signal at its cathode reproduces which is quite proportional to the charge voltage of the capacitor 127.

The triode 150 charges through silicon diodes 151 and

152 two capacitors 153 and 154.

-The anode of the triode 150 is connected to a positive DC voltage. The cathode of the triode 150 forms a connection to earth via a cathode charging resistor 159. The diode 151 is over its anode to the cathode of the triode 150 and via its cathode to a plate of the capacitor

153 connected. The other plates of the capacitors 153, 154 are at a positive DC voltage which is also connected to the capacitor 127. When the cathode of the triode 150 with reference to the right plate of the capacitor

153 is positive, then the capacitor 153 charges via the diode 151 to a greater positive potential on. If the, cathode of triode 150 with respect to the right plate of capacitor 153 is not is positive, then a negligibly small current flows through the diode 151. The capacitor 154 is also charged by the triode 150, in addition to charging the capacitor

154 is changed by the diode 152 when the cathode of the triode 150 with respect to the left Plate of capacitor 154 is negative. Therefore, the capacitor 153 is charged to a voltage 'die corresponds to the highest point of the container edge, and the capacitor 154 is on a Voltage charged, which corresponds to the lowest point of the container edge during a measuring process. If these voltages exceed a certain difference, then the following is determined Circuit causes the container to be sorted out.

The triodes 162 and 163 of a double triode are connected so that the voltages at the cathodes are proportional to the voltages on the capacitors 153, 154. The release mechanism for finding of voltage differences between the cathodes of the triodes 162, 163 accordingly large unevenness of the container edge consists of a Thyratron 169, a voltage transformer 170, a rectifier 171, a current limiting resistor 172, a filter capacitor 173, a filter resistor 174, a discharge resistor 175, a filter capacitor 176, a grid current limiting resistor 177, a thyratron load resistor 178, a capacitor 179, a gas incandescent lamp 180, a resistor 181, a capacitor 182 and an output coupling capacitor 183. The primary winding 184 of transformer 170 is connected to the main line. A first secondary winding 185 of the Transformer 170 is connected to the heating wire of thyratron 169, and a second secondary winding 186 of transformer 170 supplies voltage to a known rectifier-filter circuit, the output of which is connected to the anode of the thyratron 169. The thyratron charging resistor 178, which is connected in parallel with the capacitor 179, provides a connection between the Cathode of thyratron 169 and the negative plate of capacitor 176 and holds the cathode of the Thyratrons 169 normally at the same potential as the negative plate of capacitor 176. When the thyratron 169 ignites, then the capacitor 179 suddenly charges, with its Plate connected to the cathode of thyratron 169, positive with respect to its other plate will. The resistance of resistor 178 is large so that sufficient current is not passed through it to maintain the ionization of the gas in the thyratron 169. As a result, ended the thyratron 169 soon becomes conductive, whereupon the capacitor 179 moves through the Resistor 178 discharges, bringing the cathode of thyratron 169 to the potential of the negative plate of capacitor 176 can return. The positive voltage spike appearing on the capacitor

179 appears, is used to ignite a removal thyratron. The gas light bulb 180, which is connected in series with the capacitor 182, is so between the cathode of the Thyratrons 169 and the negative plate of the capacitor 176 switched that when the Thyratrons 169 the lamp 180 glows. The capacitor 182 is discharged in the normal manner. When the thyratron 169 ignites, then the voltage difference passes between the cathode of the thyratron 169 and the negative plate of the capacitor 176 to the lamp 180, which then glows and the Capacitor 182 is discharging. When the thyratron 169 goes out, the lamp 180 stops glowing, and the capacitor 182 discharges through the resistors 178 and 181. By the glow of the lamp

180 it is visibly indicated that a discard is taking place.

The control grid of the thyratron 169 is through the resistor 177 with the tap of the potentiometer 166 and is normally held negative with respect to the cathode of thyratron 169 and thus prevents ignition of the thyratron 169. If a smooth container rim is checked, then the charging voltage on the capacitors 153, 154 is low, and since the triodes 162 and 163 and their cathode charging resistances are almost the same, is the voltage difference between their cathodes roughly the same as that on capacitors 153,154. The zener diodes 165 receive on the potentiometer 166 maintains a constant voltage drop, the lower end of the potentiometer is negative with respect to its end connected to the cathode. The tap of the Potentiometer is set to such a point that the control grid of the thyratron 169 with respect to the cathode of thyratron 169 and triode '163 is held quite negative when a smooth container edge is checked. A larger voltage difference occurs across capacitors 153,154 when an uneven container edge is tested becomes, resulting in an inequality of those appearing on the cathodes of triodes 162 and 163 Voltages, the cathode of the triode 162 with respect to the cathode of the triode 163 pro-

proportional to the voltage difference across the capacitors 153,154 becomes positive and this effect the negative potential due to the connection of the thyratron 169 with the adjustable tap of the potentiometer 166 overcomes and causes the thyratron to ignite, whereby in turn the Lamp 180 glows and generates a positive pulse on capacitor 183. If on the capacitors 153, 154 a sufficient voltage difference is maintained, then that will Thyratron 169 alternately ignited and extinguished. However, one ignition is sufficient, the lamp to glow and to discard the defective container. One with the capacitors 153,154 connected switch 191 which operates in synchronism with the container feeder (not shown) , puts the thyratron 169 out of operation if no measurement is made by the diodes 151 and

152 are short-circuited.

In Fig. 5 shows the circuit for detecting warpage of the container edge. Same Circuit parts are provided with the same reference numerals. There is only a difference insofar as that Diodes 151,152 each have a resistor 155,156 connected in parallel. This can cause the capacitor

153 through resistor 155 and the capacitor

154 discharged through resistor 156.

The time constants of the combination of capacitors 153,154 and resistors 155 and 156 are such that a short vertical movement during a short orbital movement of the measuring roller at resistor 155, which is connected in series with resistor 156, one causes considerable voltage drop. A longer vertical movement over a longer distance on one revolution creates a similar voltage.

When the measuring roller 30 rises when it touches the container rim, the capacitor follows 153 'the voltage rise at the cathode of the triode 150 in that it is charged via the diode 151.

The capacitor 154 also follows the rising voltage, but at a slower rate, by charging through resistor 156. If the measuring roller slowly rises, then it is charging capacitor 154 rises substantially as fast as capacitor 153, so the difference between their tensions is low. However, if the measuring roller is a certain distance increases at a very rapid rate, then capacitor 153 charges significantly faster than capacitor 154 and the voltages across the capacitors become unbalanced. If the measuring roller rises fast enough or the lift continues long enough, then ignites the thyratron 169.

In a similar manner, capacitor 154 also follows the decreasing voltage at the cathode of FIG Triode 150, when the measuring roller descends by charging through diode 152, and the capacitor 153 follows the falling voltage by charging through resistor 155. If the Voltages at the cathode of the triode 150 drop quickly enough or the drop lasts long enough, then the voltages on the capacitors 153,154 get out of balance. Between A voltage difference occurs at the outputs of the triodes 162, 163, and the thyratron 169 ignites, thereby generating a reject signal on capacitor 183. This signal is on Eject thyratron transmitted, which in the ignited state a magnet 67 to eject the container excited.

A similar circuit is used for prospecting

ίο used by faults that are at proportionate short sections of the circumference of the container rim occur, the width of the capacitors 153,154 and resistors 155,156 can be changed. Preferably combinations with smaller Time constant related, so that errors that cause a larger voltage rise within a shorter one Generate route, can be found.

Claims (1)

Patent claims: 1. Device for testing hollow containers, in particular glass vessels, using one of the surface of the container scanning measuring member, the movement of which on a Differential transformer is transmitted, on the output side of which an alternating voltage is generated is, the phase and amplitude of which depends on the position of the measuring element, characterized in that, that a capacitor (127) is connected to the differential transformer (61) is that the charging voltage of the capacitor is proportional to the amplitude of the alternating voltage two symmetrical ones, each consisting of a capacitor (153, 154) and one connected in opposite directions Diode (151, 152) is fed to existing networks and that the capacitors the voltages occurring in the networks to a value above a predetermined value Voltage difference responsive triggering device supplied for discarding a container 4.0 become. 2. Device according to claim 1, characterized in that for each diode (151, 152) a Resistor (155, 156) is connected in parallel. 3. Device according to claim 1 or 2, characterized in that the capacitor (127) to the differential transformer (61) via a phase and amplitude discriminator (130, 135, 136,137) is connected and that between the capacitor (127) and the connection point of the two diodes (151, 152) of the networks, a triode (150) is connected as an amplifier. 4. Device according to one of claims 1 to 3, characterized in that the connection points the diodes (151, 152) and capacitors (153, 154) of each network, respectively connected to the control grid of a triode (162, 163) in its anode-cathode circuit a thyratron (169) serving as a triggering device is arranged. 5. Device according to claim 4, characterized in that the thyratron (169) has two Has control grids which are each connected to the triodes (162, 163), the one connection a potentiometer (166), the total voltage drop over at least one Zener diode (165) is kept constant. For this purpose 2 sheets of drawings noo cot / Co