RU2346253C2 - Method of insulated vessel production, method of vessel leak proofness control and device for its implementation - Google Patents

Abstract

FIELD: physics, tests.

SUBSTANCE: invention relates to test engineering and is designed for leak proofness testing of packages or containers with at least one flexible wall section. The result is achieved due to the following steps taken: pressure difference is provided at the wall of the tested vessel and pressure alteration inside or outside the vessel allows to determine absence or presence of leakage in it. As soon as one of the pressures is equal to the specified value or exceeds maximal value it is saved as a control value. The control value is compared to the value of one of the pressures for a certain time. Sensor output signal is at least one of the pressure values.

EFFECT: simplifying the test with recording minimal leakages or deviations of the vessel volume from its specified volume.

49 cl, 6 dwg

Description

The present invention relates to a method for manufacturing sealed containers, in which a container is made and the difference between the pressure inside the container and the pressure around it is created and, by changing one of the pressures, it is judged whether the container satisfies the specified tightness conditions or not, and those that are sealed are selected containers that satisfy the given conditions, and for this, the electrical output signal of the pressure sensor is stored, and then this electrical output signal of the sensor is compared with pomnennym signal value in the comparator. The invention also relates to a method for monitoring the tightness of such containers and to a device for its implementation.

A method of monitoring the tightness of containers is known from US patent No. 5029464 and European applications No. 0313678 and 0432143.

It is known from these publications that in order to control the tightness of containers, a difference is created between the pressure inside the container and the pressure surrounding it, and one characterizes one of the pressures to determine whether the container in the control process meets the requirements for tightness or volume or not.

In this case, the container to be monitored is placed in a sealing chamber connected to a source of compressed medium or a source of suction, by means of which the aforementioned pressure difference is created. After its creation, as an initial condition, the values of the pressure surrounding the pressure vessel are stored in the reference pressure chamber, which is connected in front of the differential pressure sensor, and compared with the subsequent values of the pressure surrounding the pressure vessel.

A disadvantage of the known methods is that a differential pressure sensor must be provided with control valves operating as precisely as possible in order to guarantee registration of even minimal leaks or deviations of the tank volume from a predetermined volume.

The present invention aims to significantly simplify the method of manufacturing sealed containers and possibly earlier detection of containers with a large leak.

The task in the method of manufacturing sealed containers, in which a container is made and the difference between the pressure inside the container and the pressure around it is created and by changing one of the pressures, it is judged whether the container meets the specified tightness conditions or not, and those containers are selected as sealed containers which satisfy the given conditions, and for this, the electric output signal of the pressure sensor is stored, and then this electric output signal of the sensor is compared with the stored Achen signal in the comparator according to the invention is achieved in that the stored signal and the sensor output signal is outputted at the time of memorization, is fed to the inputs of the comparator and thus providing a zero reference signal.

The claimed method no longer requires a differential pressure sensor, as well as pneumatic storage chambers, and the controlled pressure is recorded by a relative pressure sensor, converted into an electrical signal, stored at a predetermined time when monitoring leaks, and compared with at least one subsequent value recorded by the same sensor . When controlling the volume, the pressure value is set as a comparison base and stored. Due to this, there is no need for complex units of known devices, namely a differential pressure sensor and, in particular, shut-off valves with a high control characteristic.

The creation of the pressure difference can occur in various ways, well known to the specialist also on the basis of the mentioned publications. So, for example, using the power of supply or suction for a specified time, you can create a pressure difference, and then process the achieved pressure value and its characteristic. In the same way, it is possible to supply up to a given pressure difference, and then observe the characteristic of the controlled pressure value.

The supply of pressure, as is known from the mentioned publications, can occur by preloading the prechamber to a predetermined pressure, and then unloading said chamber into a container or into its environment formed by a hermetically sealed chamber.

When controlling the volume, a predetermined amount of compressed medium is supplied to a volume dependent on the volume of the container, whether its internal volume or the difference of volumes with the control chamber, or a predetermined amount of gas is taken from this volume. According to the resulting pressure, a conclusion is made about the volume of the tank.

The measured values are compared with predetermined values or predetermined characteristics, which is also known from the mentioned publications.

The preferred way of remembering is performed so that the control device at a given point in time include an analog-to-digital converter (ADC) to convert the output signal of the sensor, and then the steady-state output signal of this converter is used as a reference value for subsequent processing of the output signal of the sensor. In this case, you can either connect an additional ADC to the sensor output, and then compare its output signal with the output signal of the storage ADC in digital form, or directly connect the digital-to-analog converter (DAC) to the storage ADC, with the help of which the stored, inverted signal is fed to as an analog reference signal to an analog comparator, to which the sensor output signal is also directly supplied.

The formation of the reference value is undertaken at time t ₁ , only after in the growing branch, i.e. when the pressure difference increases, the pressure will reach a certain set value, in particular, after the pressure value "1" is reached.

Due to this, preliminary recognition of containers with a large leak and quick rejection of them is provided, since the pressure value "1" is never reached at all in them.

In another embodiment of the invention, the storage of values is carried out only at time t ₁ , after the pressure value passes the maximum value, which, for example, does not occur in the presence of a large leak.

Further, in a preferred manner, the balancing is performed due to the fact that mainly during storage, the values on the comparator determine whether at least approximately the output signal of the device reaches a zero value; when a signal other than a zero value or a predetermined minimum value appears, it is used as a zero balancing signal.

The invention is illustrated below by way of example using the figures in which:

figure 1: in a schematic form, the device according to the invention, in which the source for supplying pressure or suction and the pressure sensor are connected to the space surrounding the tank,

figure 2: also in schematic form, as in figure 1, a fragment of the device of figure 1, in another embodiment,

figure 3: similar to figure 2 fragment in the third embodiment,

figure 4: similar to figure 2 fragment in another preferred embodiment,

5: functional block diagram of a preferred device according to the invention for implementing the control method according to the invention,

6: purely in a schematic form, the characteristic curve of the measurement.

Figure 2 shows a closed container 1, subjected to control for leaks or volume control. The container 1 can, for example, be already filled and located in the control chamber 3, hermetically sealed, for example, by means of an overlay cap 5. Through the controlled valve 7, the control volume, here the difference between the volumes of the chamber 3 and the tank 1, is loaded by means of a pressure or suction source 9 so that a pressure differential is formed on the wall of the container 1. Source 9 in this embodiment communicates with camera 3.

A relative pressure sensor 11 is provided on the chamber 3 or in it, which converts the pressure value at the input to the electrical output signal. This signal el of the sensor 11 is stored by means of a control memory circuit S in response to a control signal S supplied by a time control unit (not shown) in the memory unit 13. As a reference pressure value, the output signal el _{o of the} memory unit 13 is supplied to the comparator 15. At its second input has a direct output signal el of the sensor 11. After storing the reference value el _{o, the} comparator 15 monitors the pressure characteristic in the chamber 3.

Leak control is carried out as follows. If the container 1 is tight and storage in the storage unit 13 occurs only when the possible ones, due to the pressure difference of the forming of the container 1, have ended, the output signal el of the sensor will store the stored value el _o . At the output of the comparator 15, a comparison result of at least approximately zero indicates that the container 1 is sealed.

In the presence of leaks after the memorization of the reference value _{o o, the} signal el, depending on the direction of the differential pressure on the vessel wall, will change to a greater extent, the larger the leak.

Comparison of the output signal of the comparator 15 with the set values (not shown) gives, on the one hand, information on whether there is a leak, and, on the other hand, also information on how large it is. Depending on the containers being monitored, tolerances for small leaks may be assigned.

If the leakage is large, then the pressure difference does not occur at all on the wall of the vessel 1: the pressure inside the vessel and the pressure surrounding it are quickly balanced due to the leakage. Then, however, a zero signal occurs at the output of the comparator 15, i.e. as in the case of a sealed container, which will lead to control errors.

Therefore, as shown by the dashed line, it is preferable after storing the value of el _o in the storage unit 13 to compare this stored value in the comparator 17 with the reference value ref. The output signal of the comparator 17 indicates whether there is a large leak or not. In the event that a predetermined amount of compressed medium is introduced into the chamber 3 or a predetermined amount of gas is removed from it, with a large leak, the pressure indicated by the reference value ref is not reached, and the result of monitoring the tank 1 is indicated by the output signal of the comparator 17.

To control the volume in the chamber 3 serves a predetermined amount of compressed medium or remove a predetermined amount of gas. The storage unit 13, as depicted by the dashed line ref ₁ , is used here as a storage unit for reference values in which they are pre-stored in accordance with predetermined volumes of the capacities being monitored. By comparing the mentioned reference values ref _{1 of the} volume and the actually established pressure value el in the volume of the chamber 3 depending on the internal volume of the container 1, i.e. the output signal of the comparator 15 determines whether the tank has a given volume or not, or how large the difference between the actual and given volumes.

In the embodiment of FIG. 2, in which the same parts are indicated by the numbers in FIG. 1, only the source 9 flows into the chamber 3. By means of a hermetic shutter 19, the input of the sensor 11 is connected to the internal volume of the container 1 provided here. Processing electronics connected to the sensor 11 is the same as in FIG.

In Fig. 3, similarly to Fig. 2, another embodiment is shown in which, in comparison with Fig. 2, the source 9 and the sensor 11 are interchanged.

In the device of FIG. 4, the source 9 communicates via a sealing connection 19 with the inner part of the container 1, the input of the current sensor 11 is connected to the internal volume of the container 1. Also here is provided the processing electronics shown in FIG. 1, to which the sensor 11 is connected. It is preferably used the embodiment of figure 1 or 4.

Figure 5 in the form of a block diagram shows a preferred embodiment of the processing unit 1, partially framed by a dashed line in figure 1. The output signal of the sensor 11 is supplied, in the preferred embodiment, to a converter stage 21 comprising, from the input side of the ADC 21a, to which the DAC 21b is directly connected. The output signal of the DAC 21b is supplied to a differential amplifier 23 of known design, as is the output signal of the sensor 11. The output of the amplifier 23 in accordance with the comparator 15 in FIG. 1 is connected to an additional amplifier stage 25, the output signal of which is superimposed through the drive 27 on the input signal to the amplifier 25 at point 28.

The Converter 21, as well as the storage unit 27, controls the timing unit 29. This device operates as follows.

To store the value of el _o in figure 1, block 29 includes a conversion cycle on the converter 21, after which a signal el1 _o appears on one input of the amplifier 23. Preferably, the unit 29 simultaneously controls the storage unit 27, whereby the output signal of the amplifier 25 is returned as a zero balancing signal to its input. If the output signal of the amplifier 25 when storing the value of el _o was non-zero, then this value through the drive 27 is used as a compensating signal.

The determination of large leaks, as was described using FIG. 1, can be carried out in various ways due to, for example, the output signal of the converter 21 being supplied to an additional comparator (not shown), after which it is compared with the reference signal ref in FIG. or, as shown by the dashed line S _1, due to the fact that immediately before or after starting the storage unit 27, preferably after launch, coupled to the differential amplifier input sensor 11 is switched to the reference potential, e.g., weight, and then with a Oron output of the amplifier 25 directly after this check, whether the value has reached el _o reference value ref by 1 or not.

In contrast to the depicted preferred embodiment, it is possible to omit the second converter stage, namely, the DAC 21c, and instead provide the ADC 22c and continue to process then digitally both signals, i.e. el _o and el.

The formation of the reference value is undertaken at time t ₁ , only after in the growing branch, i.e. with an increase in the pressure difference, the pressure will reach a predetermined value, in particular, after the pressure value "1" is reached (see Fig.6).

Due to this, preliminary recognition of containers with a large leak and quick rejection of them is provided, since the pressure value "1" is never reached at all in them.

In another embodiment of the invention, the storage of values is carried out only at time t ₁ after the pressure value passes the maximum value, which, for example, does not occur in the presence of a large leak.

To control the volume, either the volume reference values are preliminarily set on the provided converter 21, as shown by the dashed line ref ₁ , or an additional digital storage unit is directly connected to the DAC 21b to convert the entered digital volume reference values to the corresponding analog signals and then using the device shown also measure volume.

The device is very well suited for the operational monitoring of containers, for example glass, plastic bottles, etc., for example, on a carousel.

In principle, it is still possible to achieve a predetermined control pressure to compare the electrical output of the sensor with one or more preset values, which can, for example, be carried out using a VM, into which the output of the sensor is input. The difference with the set control pressure, i.e. the pressure drop is determined using the VM (by comparing with the limit value entered in the VM or with the value obtained through the reference leak).

Claims (49)

1. A method of monitoring containers, in which a difference is created between the pressure inside the container and the pressure around it and by changing one of the pressures, it is judged whether the container satisfies the specified monitoring conditions or not, while one of the pressure values after it reaches the specified value when creating the pressure difference or after exceeding the maximum value is remembered as a control value and for a specified period of time it is once again compared with at least one of the following pressure values, distinguishing ysya in that the comparison is carried out after one of the pressure value reaches the maximum value, and this value is memorized. 2. The method according to claim 1, characterized in that the predetermined pressure value is stored as a control value only when the pressure reaches this predetermined value again. 3. The method according to claim 1 or 2, characterized in that the control pressure value is stored electronically, for example, in a computer. 4. The method according to claim 1, characterized in that the values of the compared pressures are determined by the output signals of the pressure sensors. 5. The method according to one of claims 1 to 4, characterized in that the output signal of the pressure sensor is compared with one or more pressure values entered, for example, in a computer, to which the output of the pressure sensor is connected. 6. The method according to one of claims 1 to 5, characterized in that they increase or decrease the pressure inside the vessel and measure the pressure inside the vessel. 7. The method according to one of claims 1 to 5, characterized in that increase or decrease the pressure inside the tank and measure the pressure around the tank. 8. The method according to one of claims 1 to 5, characterized in that they increase or decrease the pressure around the vessel and measure the pressure inside the vessel. 9. The method according to one of claims 1 to 5, characterized in that they increase or decrease the pressure around the vessel and measure the pressure around the vessel. 10. The method according to one of claims 1 to 9, characterized in that the storage is carried out by means of an analog-to-digital converter included at a given point in time for conversion, mainly using a digital-to-analog converter connected to it. 11. The method according to one of claims 1 to 10, characterized in that an amplifier element is connected to the pressure sensor, the output signal of which is used as a zero compensation signal before comparison. 12. The method according to one of claims 1 to 11, characterized in that it is used to control the tightness of the containers. 13. The method according to one of claims 1 to 11, characterized in that it is used to control the volume of containers. 14. A device for monitoring containers, containing a source (9) of pressure or suction, installed with the possibility of interaction with a controlled container (1) in relation to its internal and external pressures, at least one pressure sensor (11) and a unit (13, 21 , 17) storing the pressure values, in which the pressure sensor is made in the form of a converter of the pressure value at the input to the electrical signal at the output, and the sensor output on the one hand and the output of the pressure memory electronic unit are output to a comparator (15, 23), different in that it comprises a control unit to start the process of storing in the memory unit after passing through a maximum value on the pressure sensor signal output. 15. The device according to 14, characterized in that the control unit causes memorization after re-reaching the set pressure value. 16. The device according to one of paragraphs.14 or 15, characterized in that for monitoring leaks, the output of the sensor is additionally connected to the input of the electronic unit for storing pressure values. 17. The device according to one of paragraphs.14-16, characterized in that it provides for the connection (19) of the tank with the input of the sensor (11) and the connection of the source (9), installed tightly on the opening of the tank (1). 18. The device according to one of paragraphs.14-16, characterized in that it provides for the connection (19) of the tank with the input of the sensor (11), hermetically mounted on the opening of the tank (1), and a hermetically sealed chamber (3) for accommodating the tank (1 ) to which the source (9) is connected. 19. The device according to one of paragraphs.14-16, characterized in that the connection (19) of the container with the connection of the source (9) is provided, hermetically mounted on the opening of the container (1), and a hermetically sealed chamber (3) to accommodate the container (1 ) on which or in which the sensor input is provided (11). 20. The device according to one of paragraphs.14-16, characterized in that it contains a hermetically sealed chamber (3) for placing a container (1) on which or in which a sensor input (11) is provided and a source (9) is connected. 21. The device according to one of paragraphs.14-20, characterized in that the pressure storage device contains an analog-to-digital converter, mainly a pair of directly connected in series analog-to-digital and digital-to-analog converters. 22. The device according to one of paragraphs.14-21, characterized in that the amplifier is connected to the output of the sensor with controlled storing of its output signal, which, after storing, acts on the output signal of the amplifier as a zero compensation signal. 23. The device according to one of paragraphs.14-22, characterized in that it is suitable for monitoring leakage of containers or to control their volume. 24. A method of manufacturing sealed containers, in which a container is made and the difference between the pressure inside the container and the pressure around it is created and, by changing one of the pressures, it is judged whether the container meets the specified tightness conditions or not, and those containers are selected as hermetic containers, which satisfy the given conditions, and for this, the electric output signal of the pressure sensor (11) is stored and after that this electric output signal of the sensor is compared with the stored value of the signal in the comparator (15), characterized in that the stored signal and the sensor output signal issued at the time of memorization are fed to the inputs of the comparator (15) and thereby create a zero reference signal. 25. The method according to paragraph 24, wherein the electrical output signal of the sensor (11) is compared with one or more predetermined values. 26. The method according to paragraph 24 or 25, characterized in that to create a pressure difference increase or decrease the pressure inside the vessel and measure the pressure inside the vessel with a sensor. 27. The method according to paragraph 24 or 25, characterized in that to create a pressure difference increase or decrease the pressure inside the tank and measure the pressure sensor around the tank. 28. The method according to paragraph 24 or 25, characterized in that to create a pressure difference, increase or decrease the pressure around the vessel and measure the pressure inside the vessel with a sensor. 29. The method according to paragraph 24 or 25, characterized in that to create a pressure difference increase or decrease the pressure around the tank and measure the pressure sensor around the tank. 30. The method according to one of paragraphs.24-29, characterized in that the storage is carried out by means of an analog-to-digital converter (21a) connected in series to the sensor (11), which is released at a given point in time for this conversion. 31. The method according to claim 30, characterized in that a digital-to-analog converter (21b) is connected in series to the analog-to-digital converter (21a), and the signals are sent in analog form to the comparator. 32. The method according to one of paragraphs.24-31, characterized in that when applying the stored value of the signal and the instantaneous value of the output signal of the sensor to the comparator, the output signal of the comparator is measured and stored as a zero compensation signal. 33. The method according to p, characterized in that the stored zero compensation signal by returning through at least one amplifier stage (25) is taken into account for subsequent signal comparison. 34. The method according to one of paragraphs.24-33, characterized in that after setting the pressure difference, memorization is made after a predetermined period of time. 35. The method according to clause 34, wherein the output signal of the sensor for this period of time passes the maximum value. 36. The method according to clause 35, wherein the passed maximum value is detected by re-reaching the pressure value, which was already set when creating the pressure difference. 37. A device for monitoring containers, containing a source (9) of pressure or suction, installed with the possibility of interaction with a controlled container (1) in relation to its internal and / or external pressures, at least one pressure sensor (11) generating an electrical output a signal connected in series to the output of the pressure sensor storage unit (13,21,17) and a comparator (15), to which the output signal of the pressure sensor and the output signal of the storage unit are supplied, characterized in that when storing these output signals fishing in block storing its output signal and the pressure sensor output interact with comparator. 38. The device according to clause 37, characterized in that a shutter (19) of the container is provided with an input of the pressure sensor (11) and a connection to a pressure or suction source (9), moreover, this shutter (19) is sealed to be installed on the opening of the container (one). 39. The device according to clause 37, characterized in that the shutter (19) of the container with the input of the pressure sensor (11) is provided, is configured to be sealed on the opening of the container (1), the device comprising a hermetically sealed chamber (3) for accommodating the container (1), and a pressure or suction source (9) exits into this chamber. 40. The device according to clause 37, characterized in that a shutter (19) of the container is provided with a sensor input (11) and a source connection (9) installed tightly on the container opening (1), as well as a hermetically sealed chamber (3) for placement capacity (1) in which or on which the input of the pressure sensor (11) is provided. 41. The device according to clause 37, wherein a hermetically sealed chamber (3) is provided for accommodating a container (1) on which or in which both the sensor input (11) and the source connection (9) are provided. 42. The device according to one of paragraphs 37-41, characterized in that the storage unit contains an analog-to-digital converter, with an analog input of which a sensor output is connected. 43. The device according to § 42, characterized in that a digital-to-analog converter, the output of which is connected to the comparator, is connected in series to the analog-to-digital converter. 44. The device according to one of paragraphs.37-43, characterized in that the comparator has at least one amplifier stage, the output of which is connected to the input of the next storage unit. 45. The device according to item 44, wherein the storage unit and the next storage unit are essentially simultaneously turned on to store their respective input signal. 46. The device according to item 45, wherein the output of the next storage unit is fed back to the input of the amplifier stage on the comparator. 47. The application of the method according to one of paragraphs.24-36 and the device according to one of paragraphs.37-46 for monitoring the tightness of the container. 48. The use of claim 47 for monitoring the tightness of a clogged container. 49. A method of manufacturing sealed containers, in which the container is manufactured, by means of a sensor, a signal is obtained indicating the presence of a leak in the container, and the nature of the sensor output signal determines whether this container meets the specified monitoring conditions or not, and select it as a sealed container if it meets these conditions, and the output signal of the sensor is stored and then compared on a comparator with a stored value of the signal, characterized in that the stored signal issued by the sensor at the time of storage yhodnogo signal fed to the inputs of the comparator and thereby form a zero reference signal for the sensor output signal.

Images