SE433075B - DEVICE FOR INDICATING THE NERVARON OF ONE OR MULTIPLE GLASS ITEMS IN A GLASS PRODUCT MAKING MACHINE - Google Patents

Description

8006985-9 '10 15 20 25 30 35 In the two sections, the prior art has synchronized the section rate control with the rate control of the mail feeder and the mail distributor. The sections were operated not only at relative phase differences for receiving the items in order, but the phase differences must be preset with respect to differences in the operating time of the items to the individual sections, which are typically located in line along the conveyor, with no more than two sections can be at the same given distance from the postfeeder.

The present invention relates to a device for indicating the presence of a post of molten glass, when it enters a mold in a glassware forming machine. The hot post emits radiation in the visible or infrared spectrum, which radiation is sensed by a phototransistor.

The phototransistor responds by generating an electrical signal, which is compared with the magnitude of a threshold voltage for generating a detection signal. The detection signal can then be used to adjust the rate control of the individual section in accordance with the actual arrival of the post in the form rather than in accordance with the time of the post's formation plus the estimated movement time to the shape, as was done in the prior art. When the mold comprises two or more cavities, the detection signals from a separate detector for each cavity may be subjected to a NAND operation to indicate when the last entry has arrived.

An object of the present invention is to increase the efficiency of a glassware forming machine by pacing the glassware forming cycle based on the actual arrival of the molten glass item in the mold.

Another object of the present invention is to increase the efficiency of a glassware forming machine by pacing the glassware forming cycle based on the detection of the last entry of molten glass entering a multi-cavity mold.

A further object of the present invention is to increase the efficiency of an individual sections exhibiting glassware forming machine by adjusting the phase differences between the sections' rate control cycles with respect to the actual arrival of the molten glass items. to the molds.

The invention will be described in more detail in the following with reference to the accompanying drawings. Fig. 1 is a block diagram of a two-section machine incorporating mail detectors according to the present invention.

Fig. 2 is a plan view of one of the mail sensors of Fig. 1. Fig. 3 is a schematic view of the mail detector according to the present invention. Fig. 4 is a schematic view of a multi-cavity mail detector circuit according to the present invention. Fig. 5 is a block diagram of an alternative form of two-section machine incorporating mail detectors in accordance with the present invention.

Fig. 1 is a block diagram of a two-section glassware forming machine incorporating mail detectors in accordance with the present invention. A first single section l1 and a second single section l2 each receive items of molten glass from a mail distributor 13, which in turn receives the items from a mail feeder (not shown).

The mail distributor 13 is mechanically driven by a drive motor 14, which is connected to a source of current of variable frequency, which current is generated by an inverter 15. The mail feeder is driven in a similar manner. The drive frequency of the inverter is controlled to determine the rate at which items are formed and distributed to the individual sections 11 and 12.

The individual sections 11 and 12 belong to separate valve blocks 16 and 17, respectively. Each valve block has valves connected for actuating a plurality of glassware forming means in the associated individual section. The valves in the valve blocks are actuated by solenoids, which are controlled by a machine control circuit 18, which determines the rate control of the forming steps in accordance with a predetermined sequence of those steps. The control circuit 18 receives information regarding the sequence of the steps and the times between the steps from a source (not shown), such as a control switch or a computer program. A position sensor 19 is mechanically coupled to the drive motor 14 and generates signals representing the relative position of the mail distributor 13. A similar position sensor (not shown) is set up for the mail feeder. Since the formation of the 8006985-9 10 15 20 25 30 35 4 record is related to the rotational position of the mail feeder drive motor and the distribution of any record is related to the rotational position of the mail distributor drive motor, generates and position sensors signals indicating when a record is formed and to which section it is distributed.

The machine control circuit also receives a clock signal from a source 21, which signal forms a reference for clock control of the machine cycle and the sequence of steps. The machine speed control is typically expressed in degrees and a machine cycle is 3so ° long. the cycle for each section is also 36o °, but the cycles of the sections will be shifted from the beginning of the machine cycle by different degrees to compensate for the difference in mail distribution time to each section. A glassware forming device such as that shown in Fig. 1 is more fully described in U.S. Patent No. 4,007,028.

Fig. 1 also shows a mail sensor 22 and an associated mail detector circuit 23 according to the present invention.

The mail sensor 22 is located next to the path of movement between the mail distributor 13 and the first individual section and close to the opening of the mold (not shown). When a record reaches the mold, the sensor 22 responds to the presence of the record by generating a sensor signal to the record detector circuit 23. The detector circuit compares the size of the sensor signal with the size of a threshold signal for generating a detection signal to the machine control circuit 18 when a record is sensed. The control circuit 18 can then set the start of the first individual section glassware forming cycle relative to the machine cycle, based on the arrival of the post in the mold. A mail detector 24 and a mail detector circuit 25 are provided for the second individual section for setting the start of the glassware forming cycle for that section in a similar manner.

Fig. 2 shows a plan view of the mail sensor 22 in Fig. 1 partially cut away to expose a phototransistor. The post sensor 22 comprises a housing 31 with a first longitudinal opening 32, which is formed in the housing and connects one end thereof to a central cavity 33. A phototransistor 34 is mounted in the cavity 33 next to the inner end of the opening 32.

A second longitudinal opening 35 is formed in the housing 31 and connects the cavity 33 to the other end of the housing 31. An ordinary BNC female connector 36 is locked to the housing 31 at the outer end of the opening 35 which has a central pin 37 extending into the opening 35. The phototransistor 34 has a pair of conductors, a collector conductor and an emitter conductor, which are connected to the BNC connector 36, the collector conductor being connected to the pin 37 and the emitter conductor being connected to a sleeve 38. the opening 35 has a larger diameter than the opening 32 and the cavity 33 for easy connection of the conductors to the BNC connector 36, before the connector is attached to the housing 3l.

The housing 31 is typically formed of a non-conductive material, such as a phenolic material. The photosensitive base of the phototransistor 34 is positioned to face the longitudinal axis of the aperture 32 so that the aperture forms a "window" through which the phototransistor "sees" the passing hot melted glass post. the aperture 32 typically has a diameter of 3.2 mm and a length of 12.7 mm to limit the field of view and thus make the phototransistor more sensitive, so that the leading edge of the post is sharply detected and some protection is provided for airborne, foreign particles, which are generated by glass the product shaping process. However, since a source of compressed air for operating the pneumatic motors of the machine is available, this source could be used to provide an air flow for cleaning the opening 32.

Fig. 3 shows a circuit diagram of the post sensor 22 and the post detector circuit 23 in Fig. 1. The collector of the phototransistor 34 is connected to the pin 37 of the BNC connector, which in turn is connected to an input 41-1 of a comparator 41 via a capacitor 42. The emitter of the phototransistor is connected to the sleeve 38, which in turn is connected to the ground potential of the system. A resistor 43 is connected between the positive polarity source (not shown) and the pin 37 to restrict the current flow through the phototransistor 34. A resistor 44 is connected between the current source and the input 41-1.

A second input 41-2 of the comparator 41 is connected to the connection point between two resistors 45 and 46 via a current-limiting resistor 47. The resistors 45 and 46 are connected between the current source and the ground potential. An output 41-3 of the comparator 41 is connected to a post-detection signal output line 48, to the current source via a resistor 49 and to the input 41-2 via a resistor 51.

When no post is present, the phototransistor 34 is turned off and both sides of the capacitor 42 will be on the voltage of the current source, which is also applied to the input 41-1. Resistors 45 and 46 act as a voltage divider for generating a threshold voltage at input 41-2.

If the input 41-1 is the inverting input and the input 41-2 is the non-inverting input, the comparator 41 will generate a signal at or near the ground potential of the system, since the magnitude of the current source voltage at the input 41-1 is greater than the magnitude. of the threshold voltage at input 41-1. When the record is detected, the phototransistor 34 will be turned on to bring its collector close to the ground potential of the system. Since the voltage across a capacitor cannot change instantaneously, input 41-1 will also be close to the earth's ground potential of the system. The comparator 41 will thus change its output signal to the voltage of the power source and the resistor 49 will provide a current path for driving circuits which are connected to the output line 48 at the voltage of the power source.

As the station passes the sensor 22, the capacitor 42 will be charged against the voltage of the current source via the resistor 44 to ensure that the comparator will switch back to the signal at or near the ground potential of the system. However, the length of time during which the post passes the detector is typically less than the charge time constant of the capacitor 42. The phototransistor 34 Therefore, switch off at the trailing edge of the post and the magnitude of the signal at input 41-l again exceeds the magnitude of the threshold voltage for switching the comparator output signal. The post-detection signal generated on line 48 is thus in the form of a square wave pulse with a magnitude equal to or almost equal to the voltage of the current source, and a length determined by the required time. 9 7 the one for the post to pass the "window" of the sensor. The resistor 47 and the resistor 51 provide positive feedback to the input 41-2 and create a dead band between the voltage levels, at which the comparator 41 switches output signal states. This dead band or hysteresis prevents any oscillation that could develop during a transition between the output states.

In the circuit of Fig. 3, the phototransistor 34 may be of the TI-L66 type, available from Texas Instruments, and the comparator 41 may be of the LM 339 type, available from National Semiconductor. Typical values for the circuit components are 120 kohm for resistor 43, 220 kohm for resistors 44 and 47, 3.3 Mohm for resistors 45 and 49, 13 kohm for resistor 46, 3.3 Mohm for resistor 51 and 5 uF for capacitor 42. The positive polarity of the current source is typically 15 V.

Fig. 4 shows a circuit diagram of a multi-cavity post detector circuit according to the present invention. A detector A 61 represents a mail detector and the mail detector circuit, as shown in Fig. 3. The post-detection square pulse generated by the detector A is an input signal to a monostable multivibrator 62. The multivibrator 62 responds to a signal transition from "1" to "0", such as the trailing edge of the post-detection pulse, by generating a square pulse of a predetermined length of an input 63-1 to an OR gate 63. The OR gate 63 will generate an "0" on an output 63-3, if both of two inputs 63-1 and 63-2 have the level "0", and will generate an "1" at output 63-3, if one or both inputs have level "1." Input 63-2 is connected to a selector line 64 and output 63-3 is connected to an input 65- l to a NAND gate 65. The NAND gate 65 will generate an "0" if all of its inputs have the level "1", and will generate an "1" for all other input signal combinations. 4 is connected to an input of a monostable multivibrator 66, the output of which is connected to a signal output line 67 for the detected last entry.

A detector B 68, similar to the detector A, has an output 8006985-9 10 15 20 25 30 35 8 connected to an input of a monostable multivibrator 69, the output of which is connected to an input 71-1 of an OR gate 71. OR gate 71 has an input 71-2 connected to a selector line 72 and an output 71-3 connected to an input 65-2 of the NAND gate 65. A detector C 73, also similar to the detector A, has an output connected to an input to a monostable multivibrator 74, the output of which is connected to an input 65-3 of the NAND gate 65.

The circuit of Fig. 4 is suitable for use with a one-, two- or three-cavity form. It will be appreciated that this circuit may be expanded if the mold had more than three cavities. If the mold has three cavities, a selector signal "0" is applied to each of the selector lines 64 and 72 for actuation of the OR gates 63 and 71, respectively. The selector signals "0" can be generated by any suitable means, such as switches, which are connected to the ground potential of the system, or a computer. If no record has been detected, all the detector outputs will be at level "0" as well as the outputs of associated monostable multivibrators, so that an "0" will appear at the inputs of NAND gate 65. NAND gate 65 is thus in the state "1" and the monostable multivibrator 66 generate a "0" on the output line 67.

As each item enters a cavity in the mold, the associated detector generates a square wave detection signal. The associated monostable multivibrator is triggered on the trailing edge of the station and all the inputs to the NAND gate 65 will have the level "1" to change the signal at output 65-4 from "1" to "0" if the length of the multivibrator pulse exceeds the time between detection. of the trailing edge of the first entry entering the mold and the trailing edge of the last entry entering the mold. When the pulse time of the multivibrator belonging to the first record to be detected expires, the associated of the inputs to the NAND gate 65 will return to "0" and the output 65-4 will return to "1". to form a square wave pulse "0" .The multivibrator 66 responds to the leading edge of the pulse "0" by generating a signal "1", which indicates that the trailing edge of the last record to be get into the mold has been sensed and that all three items are in the mold.

If one of the mold cavities is not active or if the mold has only two cavities, the associated selector line can be applied to a signal "1" to generate a "1" at the associated input of the NAND gate 65 and actuate the NAND gate 65. for the detection of incoming entries in two cavities. If two of the mold cavities are not active or the mold has only one cavity, both selector lines 64 and 72 may be pressed a signal "1" to activate the NAND gate 65 to detect the entry entering the single cavity. The selector signals "1" can be selected by any suitable means, such as switches or a computer connected to a power source of positive polarity.

Fig. 5 shows a block diagram of an alternative form of a two-section machine, comprising mail detectors according to the present invention. The elements, denoted by the same reference numerals as in Fig. 1, are similar to the corresponding elements in Fig. 1. However, the position sensor 19 in Fig. 1 has been eliminated and the clock 21 has been replaced by a clock control circuit 81. The clock control circuit 81 may be the the timing control circuit described in U.S. Pat. No. 4,145,204 or the timing control circuit described in U.S. Patent No. 4,145,214. The timing control circuit 81 therefore responds to the frequency of the inverter-generated current for generating a timing control signal to the machine. control circuit 18 for synchronizing the individual sections having the machine cycle of the machine with the mail distributor 13. For the example of a machine with two sections, the section cycles can be set with a phase difference of 1800 in the machine cycle of 3600 and the beginning of each section cycle can is set to the actual arrival of an entry to the form.

In summary, the present invention relates to a record detecting means for generating a detection signal in response to the presence of a post of molten glass at the forming means in a glassware forming machine. The machine comprises means for distributing molten glass items at a predetermined rate from a source of items, means for forming glassware items in a rate-controlled, predetermined sequence of steps of items received from dispensers. gans, and control means for cyclically controlling the influence of the forming means in cycles of the rate-regulated, predetermined sequence of steps in response to the post-distribution rate. The control means are arranged to start the next cycle of the clock-regulated, predetermined sequence of steps in response to the detection signal. When the forming means comprises a multi-cavity shape, a record detecting means associated with each cavity and means sensitive to the simultaneous generation of all the detection signals generates a signal for the last record detected to the control means for starting the next cycle.

Claims (9)

A device for indicating the presence of one or more items of molten glass in a glassware forming machine, characterized by a mail detector (22, 23; 61, 68, 73) for the post or each post for generating a detection signal in response to the presence of a post in a corresponding form cavity, which post detector at least when indicating the presence of a post comprises a post sensing means (22), which is arranged to in response to the light emitted by the station generates a sensor signal indicating the presence of the station, and a mail detector circuit (23) with a source (45, 46) for a threshold signal, with a comparator means (41), which is arranged to in response to the sensor signal and the threshold signal generates a signal which characterizes the presence of the record when the magnitude of the sensor signal exceeds the magnitude of the threshold signal, and with means for terminating the comparator signal; and means for indicating the presence of several records (63 * 67, 71, 72) for generating a signal in response to the generation of detection signals from all record detectors (61, 68, 73) indicating the presence of records in all records. the mold cavities. 2. Device according to claim 1, characterized in that the mail sensor means (22) comprises a phototransistor (34), which is sensitive to the light emitted from the mail, for generating the sensor signal. Device according to claim 2, characterized in that the post-sensing means (22) also comprises a housing (31), in which a central cavity (33) is formed and an opening (32) connects the central cavity to the outer of the housing. , and that the phototransistor (34) is mounted in the central cavity, the opening forming a window for limiting the field of view in such a way that the leading edge of the post is sharply detected. Device according to claim 3, characterized in that the opening has a diameter of approximately 3.2 mm and a length of approximately 12.7 mm. 10 15 20 25 30 35 8096985-9 - 12 Device according to one of Claims 1 to 4, characterized in that the means (63 ~ 67, 71, 72) for generating the presence-indicating signal comprise means (64 or 72) for generating a selector signal as a replacement for a detection signal. from a mail detector for an unused mold cavity. Device according to one of Claims 1 to 5, characterized in that the means for generating the presence-indicating signal comprise a monostable multivibrator (for example 62) for each mail detector (for example 61), which multivibrators are arranged in response to the trailing edge of each detection signal generates a square wave pulse of a predetermined length, and means (65, 66) for generating the presence signal in response to the coincidence of at least a part of all square wave pulses. Device according to claim 6, characterized by at least one OR gate (71), which has an input connected to receive one of said square wave pulses and another input (72) connected to a source for a selector signal, which is generated as a "0", when the corresponding cavity is active and as a "1", when the corresponding cavity is inactive, the OR gate being arranged to, in response to the simultaneous generation of the square wave pulse and the selector signal "0", generate the square wave pulse which an output signal and is arranged to generate in response to the selector signal "1" an output signal "1", and NAND means (65), which are arranged to generate the presence signal in response to the simultaneous generation of the square wave pulses or of one or more of these together with additional selector signal or * signals "l". Device according to any one of claims 1-7, characterized by means (51) for increasing the size of the threshold signal in response to the comparator signal, so that the comparator terminates the comparator signal when the magnitude of the sensor signal in the opposite direction passes the increased magnitude of the threshold signal. 8006985-9 13 Device according to any one of claims 1 ~ 8, characterized by means (42) for terminating the comparator signal after a predetermined period of time.