Abstract: The fluid tightness of containers having a first deformable section and a second deformable section spaced from the first deformable section is checked by changing the pressure applied to the first deformable section, preferably without causing fluid to flow through the first deformable section out of the container, and without changing the pressure applied to the second deformable section, thereby causing a deformation of the first deformable section and a change in pressure within the container; and thereafter monitoring a predetermined characteristic, preferably the position, of the second deformable section. This process can be used to check the fluid tightness of the containers with relatively fragile seals, for example, a foil lid of a food container without mechanical contact. Automated apparatus for carrying out this process is described.

Abstract: Apparatus and process for non-destructively testing a fluid-filled container for leaktightness, the process comprising: (a) subjecting the fluid-filled container to a vacuum or near vacuum environment; (b) utilizing electrical equipment to form an electrical discharge in the vacuum or near vacuum environment sufficient to stimulate spectral light emissions from volatile fluid-filled container contents present in the vacuum or near vacuum environment; (c) detecting the spectral light emissions from the volatile fluid-filled container contents produced in step (b); and (d) evaluating the spectral light emissions detected in step (c) to determine the amount of volatile fluid-filled container contents present in the vacuum or near vacuum environment by comparing: (i) the measured brightness level of the spectral light emissions obtained from step (c), to (ii) a base brightness level obtained by measuring the brightness level of the spectral emissions due to the presence of residual gas or air molecules in the

Abstract: A leak detection system for testing a sealed product for leaks includes a test chamber, a pressure system that is operable to maintain a substantially constant pressure during a test period, and a leak sensor coupled to the test chamber via a first conduit and the pressure system via a second conduit. The test chamber of the leak detection system includes a receptacle dimensioned to receive the sealed product. Moreover, the test chamber includes a cover dimensioned to operably seal the receptacle at an initial internal pressure when placed into position with the receptacle. The leak sensor of the leak detection system is operable to permit gas flow between the test chamber and the pressure system via the first conduit and the second conduit. The leak sensor is also operable to obtain a value representative of total mass of the gas flow between the sealed test chamber and the pressure system during the test period.

Abstract: For leak testing closed containers (9) which are filled with a filling product containing at least one liquid component the container is introduced in a test cavity (1) which is evacuated at least down to vapor pressure of that liquid component. The pressure in the surrounding of the container (9) and thus within test cavity (1) is monitored. Monitoring is performed by a vacuum pressure sensor (7), whereas lowering pressure surrounding the container (9) is performed by a vacuum pump (5). Leakage is detected by monitoring a pressure change in the surrounding of the container which is due to evaporation of liquid emerging from a leak and being evaporated in the low pressure surrounding.

Abstract: A method and apparatus for examining internal components of a sealed container is disclosed. In one embodiment, the method includes the steps of attaching an acoustic sensor to an outer surface of the sealed container and moving the sealed container about at least one axis of the sealed container. An audio signal is received from the acoustic sensor, where the audio signal is generated by a component within the sealed container that is put into motion as a result of the step of moving the sealed container about the at least one axis. The audio signal is analyzed to determine the frequency of the signal. In an embodiment for an apparatus of the present invention, an acoustic sensor is attached to the sealed container. An amplifier is coupled to the acoustic sensor and receives an audio signal from the acoustic sensor. The audio signal is generated by a component within the sealed container that is put into motion as a result of movement of the sealed container.

Abstract: For leak testing closed containers (9) which are filled with a filling product containing at least one liquid component the container is introduced in a test cavity (1) which is evacuated at least down to vapor pressure of that liquid component. The pressure in the surrounding of the container (9) and thus within test cavity (1) is monitored. Monitoring is performed by a vacuum pressure sensor (7), whereas lowering pressure surrounding the container (9) is performed by a vacuum pump (5). Leakage is detected by monitoring a pressure change in the surrounding of the container which is due to evaporation of liquid emerging from a leak and being evaporated in the low pressure surrounding.

Abstract: Apparatus for detecting a defect during the formation of a container end having a stay-on-tab secured thereto, particularly when the defect is associated with a mis-located tab, in which a portion of the apparatus will be moved by the defect which movement is sensed and a signal is generated.

Abstract: To test the features of containers (10) which are sealed by means of a closure (12), such as central fit of the closure (12) on the container opening, tightness of the fitting of the closure (12) or the residual air volume in containers (10) in which the liquid is foamed up before closure, in order to expel the residual air volume, mechanical vibrations are excited in the closure (10) and the mechanical vibrations are analysed. The mechanical vibrations are analysed directly after the closure (12) has been fitted, before major change in the pressure takes place in the container.

Abstract: Apparatus for testing non-rotationally symmetrical hollow bodies for defects includes a conveyor for continuously conveying the hollow body through a test region past a detector for producing measurement values characterising the nature of the respective hollow bodies being tested, in dependence on the angle of rotation of the hollow body. An evaluator device compares the measurement values to predetermined values to decide whether the respective hollow body being tested suffers from defects. The conveyor has a receiving device which is fitted over the respective hollow body to embrace it. The receiving device with the hollow body is rotated through a predetermined angular amount while the hollow body is being transported past the detector device. The receiving device is removed from the hollow body again in the region where the conveyor conveys the hollow bodies out of the test region.

Abstract: A system for collecting outgassed compounds from a disc drive includes the following structure into which the disc drive fits during such an outgassing test a base portion and a top plate connected to the base portion to move between a first and second positions to clamp a pair of valves to an outer cover of the disc drive. The two valves each include a needle plunger that may be extended from the valve to penetrate the outer cover of the disc drive and create a flow path for on inert gas sweeping between the two valves through the interior of the disc drive. An inflow line connects a source of inert gas to one valve to mix the inert gas with the outgassed compounds within the interior of the disc drive. An outflow line connects the second valve to a trap containing absorbents to separate substantially all of the outgassed compounds from the inert gas. A power supply and a disc controller operate the disc drive in a realistic manner during the course of the test.

Abstract: For leak testing closed containers (9) which are filled with a filling product containing at least one liquid component the container is introduced in a test cavity (1) which is evacuated at least down to vapour pressure of that liquid component. The pressure in the surrounding of the container (9) and thus within test cavity (1) is monitored. Monitoring is performed by a vacuum pressure sensor (7), whereas lowering pressure surrounding the container (9) is performed by a vacuum pump (5). Leakage is detected by monitoring a pressure change in the surrounding of the container which is due to evaporation of liquid emerging from a leak and being evaporated in the low pressure surrounding.

Abstract: A device and method provide improved measurement of flow through an enclosed channel, such as a pipe. A flow measurement device, such as a differential pressure sensing pitot tube, includes a pressure sensing probe that is inserted into the pipe for measuring the rate of fluid flow therein. A compressible or elastic barrier is attached to the distal end of the sensing probe to fill the space between the tip end of the sensing probe and the nearby portion of the inside wall of the fluid carrying pipe. The resilient barrier prevents undesirable fluid flow between the tip end of the sensing probe and the inside wall of the pipe.

Abstract: For leak testing closed containers (9) which are filled with a filling product containing at least one liquid component the container is introduced in a test cavity (1) which is evacuated at least down to vapor pressure of that liquid component. The pressure in the surrounding of the container (9) and thus within test cavity (1) is monitored. Monitoring is performed by a vacuum pressure sensor (7), whereas lowering pressure surrounding the container (9) is performed by a vacuum pump (5).

Abstract: A fluid-sampling tool for obtaining a fluid sample from a container. When used in combination with a rotatable drill, the tool bores a hole into a container wall, withdraws a fluid sample from the container, and seals the borehole. The tool collects fluid sample without exposing the operator or the environment to the fluid or to wall shavings from the container.

Abstract: A method of carrying out quality control of a packaging container or packaging container blank comprises providing a package or blank having one or more poles (12) for interconnection with electric quality control equipment (24). The packaged product (20) will be directly or indirectly electrically accessible, whereby both the quality of the packed product and the tightness of the surrounding packaging container (1) may be determined in a rational and partly automated manner. This is of particular importance in the production of aseptic packaging containers for, for instance, ready-made, heat-treated soups or similar foods.

Abstract: A method for leak testing of a hermetic package closure comprises the steps of: creating a pocket in a lid; plating the lid; placing solder in the pocket; melting the solder in the pocket; drilling a hole through the solder and the plated lid creating an unplated area on the plated lid; testing the hermetic package closure for leaks through the hole; heating the solder reflow, wherein surface tension of the solder over the hole and the unplated area enable the solder to form a hermetic closure.

Abstract: An apparatus for analyzing a liquid product. The apparatus includes a conveyor assembly having a conveyor belt and an agitator. The conveyor belt is constructed to deliver a unit of liquid product from the agitator to an analysis position. The agitator is constructed to impart motion to a unit of liquid product. The apparatus further includes an ultrasound transmissive pad assembly having a pad defining a chamber therein. A liquid acoustical couplant is contained in the chamber. The ultrasound transmissive pad assembly further includes an ultrasonic transducer in ultrasonic contact with the liquid acoustical couplant. The pad is positioned to contact a unit of liquid product at the analysis position. The pad has an upper portion and a lower portion and is orientated such that the upper portion contacts a unit of liquid product delivered to the analysis position before the lower portion contacts the unit of liquid product delivered to the analysis position.

Abstract: For the purpose of testing deformable containers (2) for tightness, a negative pressure is generated in the container (2) and the internal pressure is then measured. The negative pressure is generated by deformation of the container (2). A sealing strip (6) is set on the container opening (8) in order to maintain the negative pressure in the container (2). In non-tight containers, the pressure increases relatively rapidly again to the ambient pressure.

Abstract: The diffusion through a membrane assaying apparatus and method facilitates rapid detection of small or larger molecular weight substances such as hazardous wastes, toxic chemicals or the like by using a semipermeable membrane having a predetermined molecular weight cutoff. The semipermeable membrane is provided as part of a container having a removable barrier which facilitates control of diffusion through the membrane. The assaying method includes the use of a reaction mechanism for detection of a predetermined substance. The reaction mechanism includes one or more reagents which are designed to either react or compete for a substance for which assaying is being performed. By selecting the proper reagents and molecular weight cutoff of the semipermeable membrane, the presence or absence of a reaction such as a color change or production of vapor provides indication whether the substance being assaying for is present in the test sample.

Abstract: A container inspection apparatus inspects sealing performance of a closure of a container such as a bottle filled with effervescent beverage. The apparatus include a plurality of support members for placing a container thereon and movable along a certain path, a plurality of ultrasonic transducers fixed to one of the support members for generating ultrasonic vibration, and a supply device for supplying liquid to an upper surface of the support member. The ultrasonic vibration of the support member caused by the ultrasonic transducer is transmitted to a bottom of the container through liquid interposed between the bottom of the container and the upper surface of the support member. After vibrating the bottom of the container, beverage in the container is imaged by an imaging unit to detect a defective container which is not sealed properly.

Abstract: An inflator for an airbag system has a target mounted in the pressurized gas contained in the inflator. An ultrasonic transducer is mounted on an external surface of the inflator in alignment with the target. The transducer generates and receives reflected ultrasonic signals from the target. The time-of-flight of the signals which are dependent on the gas pressure are used to determine the gas pressure in the inflator. Temperature compensation is provided by fabricating the target of bimetallic material which changes the spacing of the target from the transducer with temperature or providing a temperature sensitive element, e.g. a thermocouple to electrically provide temperature compensation.

Abstract: A sensor structure for use with container inspection systems utilizes a continuous-wave (CW) microwave radar to measure the curvature or the vibration characteristics of a container wall through a thick corrugated cardboard case top or on a single item container processing line. A radar antenna directs RF energy toward cans moving along a conveyor. The antenna emits a beam which, over time, illuminates a narrow region along a line from one outer edge of the can to the opposing outer edge, as the can passes the antenna. During this time, a continuous measurement of the relative change in distance from the antenna to the top of the can is generated and sampled for acquisition by a computer, and an estimate of the profile is made from changes in the distance measurement. The profile is used as a measure of the internal pressure of the can or as an indication of the presence of manufacturing defects.

Abstract: A method of monitoring the growth of microorganisms in liquid culture involving the detection of pressure change in a gas-tight container such as a blood culture bottle incorporating a flexible diaphragm (septum) by detecting displacement of the septum, is characterised by the position or conformation of the diaphragm being repeatedly sensed using a distance-measuring means, such as a laser, preferably capable of detecting a variation in the position or conformation of the diaphragm to an accuracy of 200.mu. or better, with a portion of the container adjacent the diaphragm conveniently being used as a reference to detect any relative positional or conformational change of the diaphragm. Preferably the laser repeatedly scans a plurality of containers mounted in a holder such as a flat bed or a carousel.

Abstract: A method for analyzing the internal pressure of a closed container includes inducing vibration in a surface of the container; detecting sound resulting from the vibration; deriving information representing the detecting sound; and determining whether this information corresponds to a predetermined spectral frequency condition and a predetermined spectral amplitude condition. To ensure that the test results are not affected by modulating distortion which may be present in the information, the information is tested for the presence of a modulating distortion, and if so processed to compensate for the effects of this modulating distortion, prior to being tested against the predetermined spectral conditions.

Abstract: A system for analyzing the fill characteristics of a container. A container having a filling material therein is positioned adjacent a sound generator. Sound waves from the generator are applied to the container, causing it to vibrate. A vibration detector is used to determine the amount of container vibration. A preferred vibration detector involves a laser vibrometer which applies a reference laser beam to the vibrating container. The reference beam is reflected off of the container to generate a reflected laser beam. The reflected beam experiences a Doppler frequency shift compared with the reference beam which is caused by container vibration. The Doppler shift of the reflected beam is then compared with standardized Doppler shift data from a control container. Repeated Doppler shift measurements may also be undertaken which are converted into a vibration profile that is compared with a standardized vibration profile from a control container.

Abstract: An internal pressure inspection is simply conducted for cans of types different in dimension and for assuredly removing defective cans. The inspection apparatus comprises first and second can barrel pressure detectors and a can cover pressure detector for detecting the internal pressure of a can, and a can sensor for sensing a can, which underwent the detection of the internal pressure, to output a can sense signal. In the inspection apparatus, a control unit decides the acceptance or failure in the can internal pressure and, when the failure decision is made, starts a defective can removal unit on the basis of the can sense signal from the can sensor. An apparatus body has a separation change mechanism including a width variable gauge which is placed between first and second movable frames and which can change its own width in accordance with its own rotation. The first and second movable frames and which can change its own width in accordance with its own rotation.

Abstract: Canister tester for rapid testing of the contents of a pressurized canister containing fluid or gaseous matter. Incoming canisters are placed into a dual rotary canister test bed and are revolved about the canister test bed axis to mix the canister contents prior to pretest purging and final test stations. A load mechanism loads canisters into the dual rotary canister test beds for testing. An eject mechanism ejects tested canisters from the dual rotary canister test beds into an off-load star wheel. Unsatisfactorily tested canisters are ejected prior to placement on an output conveyor.

Abstract: An apparatus for monitoring the vacuum of a vacuum switch having at least one vacuum switch tube with a switch chamber and switch contacts is provided. The apparatus has a remotely interrogatable pressure measurement sensor in the form of a piezocrystal or surface acoustic (SAW) device arranged in the interior of the vacuum switch tube and a remote interrogation device placed external to the vacuum switch for monitoring the vacuum via the sensor.

Abstract: Plastic tube sections are connected together by providing a pair of tubes each of which is inserted into the holder of a welding device in a bent condition so that each tube has a primary tube section and a secondary tube section with the primary tube sections being aligned with each other and the secondary tube sections aligned with each other. The tubes are heated by a wafer to create four separate tube sections which are then joined together in a dual weld wherein one of the welds joins the primary tube sections together and the other of the welds joins the secondary tube sections together. The welded primary tube sections are then separated from the secondary tube sections. Communication between each pair of tube sections is achieved by pressing the tube section open at the weld.

Abstract: A method of analyzing internal pressure of a closed container includes inducing vibration in a surface of a closed container; detecting sound resulting from the vibration; deriving information representing the detected sound; and determining whether the information corresponds to a predetermined spectral frequency condition and a predetermined spectral amplitude condition. The surface is at least partially conductive and inducing includes imposing a magnetic field on the surface. The predetermined spectral frequency condition and the predetermined spectral amplitude condition correspond to ranges of acceptable values. The detected sound is used to determine whether the closed container contains a pressure level within a predetermined range of pressure levels.

Abstract: An improved liquid pressure measuring system comprising a container containing a liquid at a level to be sensed, a pressure sensing chamber located within said container and having an open bottom, a pressure sensing device connected to sense the pressure in said chamber, and means for generating gas within said chamber to balance the hydrostatic pressure of said liquid.

Abstract: A pinhole inspecting apparatus is provided which can accurately and speedily inspect a pinhole on a closed container.

Abstract: A sensor system for mapping absolute acoustic noise intensity in a three-dimensional acoustic noise field. Localized noise sources within a vessel are extracted using a distant array of transducers mounted on the vessel wall. The absolute intensity can be measured even when totally masked by background noise at the transducer locations. The system includes an integrated transducer installation. Each transducer is an accelerometer which is mounted on the vessel wall using a rigid attachment rod which serves as an ultrasonic waveguide. The output of each transducer is split into low- and high-frequency components, the low-frequency component being a function of the vibrational displacement of the localized portion of the vessel wall and the high-frequency component being a function of the vibrational/ultrasonic waves propagating through the localized portion of the vessel wall.

Abstract: An ultrasonic inspection technique using a specially designed electromagnetic acoustic transducer (EMAT) launches and receives longitudinal ultrasonic waves into a thin metal wall or thin metal foil seal of a container, causing it to vibrate and launch ultrasonic compressional waves into liquid contained therein. The contents of plastic containers having a metal foil seal forming one wall are easily inspected. The EMAT establishes a magnetic field in the surface of the metal parallel to the surface. Radio frequency (RF) eddy currents are also induced by the EMAT in the surface of the metal. A Lorentz force is generated in the metal surface according the vector product of J, the current density, and H, the magnetic field, and the force generated by the interaction of the perpendicular components of the magnetic field H and the eddy currents J is directed normally to the surface of the metal.

Abstract: To measure the leakage rate in hollow bodies, the throughflow rate of the air flowing into the leaky hollow body is automatically measured and indicated numerically at a given test pressure. This is achieved by feeding fluid from a prechamber filled with fluid under measuring pressure to two measuring chambers (4,5) equipped with a testpiece and reference housing and having an identical cavity. The pressure decrease in a prechamber (1) is thereupon evaluated as a measure of the accessible volume in the two measuring chambers (4,5) and is compared with the volume given as permissible. If the measured accessible volume is higher than the volume given by the size of the chamber, the testpiece is qualified as highly leaky. If the volumes in the two chambers (4,5) correspond to one another, the chambers (4,5) are separated from the prechamber and the pressure difference between the chambers (4,5) and its trend in time are detected, in order to determine from this a measure of the tightness of the testpiece.

Abstract: A method and device for detecting a shortage or excess of an article enclosed in respective envelopes in an automatic mail enclosing and sealing machine. The method comprises the steps of receiving information relative to the number of sheets enclosed in respective envelopes, detecting a variable corresponding to the number of sheets enclosed, discriminating whether the detected variable is within or out of the allowable range corresponding to the sheet number information, and deciding whether a shortage or excess of article is enclosed.

Abstract: An apparatus (20) for sensing pressure in a stiff wall sealed vessel (30) comprises a piezoelectric transducer (200) operatively coupled to the vessel (30) for transferring energy to pressurized fluid in the vessel (30). A piezoelectric sensor (202) is operatively coupled to the vessel (30) for providing a received electrical signal having a frequency value indicative of the oscillation frequency of the pressurized fluid. A receiver circuit (224, 226, 228) is operatively connected to the sensor (202) and provides a fluid resonating signal having a frequency indicative of the fluid pressure in the vessel (30). A drive circuit (230) is operatively connected to the receiver circuit (224, 226, 228) and to the piezoelectric transducer (200). The drive circuit (230) initially drives the piezoelectric transducer (206) with noise.

Abstract: Apparatus (10) includes means (14) for exciting at least the fundamental radial circumferential mode of vibration (f.sub.1) and the first harmonic (f.sub.2) thereof, detection means (22) for detecting the vibration and analyzing means (12) for determining the internal pressure by reference to f.sub.1 and f.sub.2.

Abstract: To detect an unpressurized moving container, a fluid such as air is directed at the moving container. Thereafter, a level of deflection of the moving container resulting from the directed fluid is detected. An unpressurized container is indicated when the detected level of deflection exceeds a threshold level. Deflection may be detected by directing a pulse of air or a continuous stream of air against the container. The system is particularly useful in detecting unpressurized, thin-walled aluminum cans.

Abstract: The sealing integrity and/or the proper filling of sealed packages is determined by conveying them continuously along a path and applying loads to them. The loads have package contacting surface portions that travel in the conveying direction, e.g., provided by driven belts or arrays of free-running rollers. Preferably each package is subject to a first load and to a second load greater than the first, and two values related to the effective package thickness under the loads are derived and compared by a computer system. The difference value is indicative of package seal quality.

Abstract: A sensitive to a change in the physical dimension(s) of the exterior surface of a pressure vessel transducer and attached to the exterior surface thereof the pressure vessel may be a vacuum chamber. The transducer measures exterior dimension change, representing interior pressure change information, without intrusion. The measurements are displayed using distinctive lights or audible alarms which signal if the pressure inside the vessel is within a predetermined range. If the pressure within the vessel varies outside of the predetermined range, a more precise display device such as a meter, is provided to aid facility personnel in deciding when repairs are necessary.

Abstract: A method determines the amount of the fluid content with a smaller specific gravity in an airtightly sealed flexible container containing contents with different specific gravities that are automatically separated from each other when held to a stationary state. The amount of said content is determined by externally applying pressure to the airtightly sealed flexible container to increase the inner pressure thereof and collecting data on the fluid content with the smaller specific gravity.

Abstract: A method and apparatus for testing the seal between a container and a flexible lid by measuring the lid's deflection. In the disclosed embodiment, an actuator impacts the lid and activates an alarm if the lid is not securely attached to the container.

Abstract: An evacuator housing ( 14) of a gas tank evacuator (10) receives a gas tank (12). A valve seal of a movable seal head (34) and a puncture seal (66) of the evacuator housing are clamped onto the gas tank at opposite ends by a hollow threaded shaft (32) to form a sealed test space (58) exteriorly of the gas tank at a valve (22) and a sealed evacuation space (68) exteriorly of the gas tank at a puncture spot (24). A pressure gauge (60) coupled to the test space rides on the seal head and a valve actuator in the form of a rod (40), passes through the hollow threaded shaft into the sealed test space. A puncturing mechanism (18) punctures the gas tank at the puncture spot. The sealed evacuation space is positioned vertically below the puncture spot and communicates with a carbon filter positioned vertically above the evacuation space so as to form a U-shaped trap (90).

Abstract: A method and apparatus for leak testing a container wherein the container such as a flexible or semi-flexible package is received in a closeable test cavity. A pressure differential is installed between the inside of the container and an enclosed space within the test cavity outside of the container. A change in the pressure in the enclosed space is detected. The closeable test cavity comprises a flexible wall whose shape adapts to the shape of the container at least when the pressure differential is installed. The flexible wall advantageously compensates for variations in head space and shape of the packages, as where the contents are not uniformally distributed within the package. The flexible wall can sealingly contact a portion of the container spaced from a container seal to permit detection of seal leaks. A gas permeable, flexible screen can be employed between the container and the flexible wall to permit leak detection of leaks in the container beneath the flexible wall.

Abstract: Disclosed are a method and apparatus for testing the tightness of foil bags (10). In order to test the tightness of foil bags (10), mechanical testing members are used which act upon the foil bag (10) in the region of a cavity (15) formed above the packaged goods. Testing rams (18) are pushed against a bag wall (16, 17) with a given testing pressure. The depth of impression is indicative of the airtightness of the foil bag ( 10). The size of the cavity (15) which can be used for testing is reduced by clamping members (26) and, as a result, a residual cavity (25) is formed next to the clamping members (26). Consequently, an increased pressure is present within the residiual cavity, that is to say within the foil bag (10), which facilitates testing.

Abstract: A method and test chamber for leak testing a container with substantially flexible side wall wherein the container is introduced into a test cavity so that the flexible side wall of the container is spaced from at least first, relatively recessed portions of an inner adjacent wall of the test cavity with a gap being defined between at least the first, relatively recessed portions of the inner wall of the test cavity and the flexible side wall of the container. A pressure difference is installed as an initial value between the interior of the container and at least the gap by applying a pressure at least to the gap which is smaller than a pressure inside the container. The flexible side wall is supported from its exterior side within the test cavity on second, relatively raised portions of the adjacent inner wall of the test cavity so as to mechanically stabilize the flexible side wall with respect to the outward bending as a result of the pressure difference.

Abstract: A high frequency magnetic field exposure meter for use in an induction heat sealing operation for heat sealing metal foil elements in closures to containers to be closed by the closures. The meter has a magnetic field sensing coil, a rectifier to convert the a.c. output from the coil to a d.c. output, an integrating circuit to integrate the d.c. output over an exposure period to an h.f. magnetic field, and a display device to indicate the integrated exposure value generated by the integrating circuit. During operation, the meter generates a quantitative reading indicating exposure to the h.f. magnetic flux as an integral of the magnetic flux, which generates the induction heating currents, over the exposure period during the induction heat sealing operation, and the reading provides a useful measure of the induction heating generated in an induction heat sealable closure.

Abstract: This invention is directed to a device which measures the oxygen component of a beverage gas using a specific oxygen probe, ultrasonic degassing, a special valving technique, and microprocessor based software. The measurement is made in the gaseous state in a two chamber system. The device is controlled by an electronic console that is built around a microprocessor which sequences and times the valves, receives the data from the oxygen probe and its accompanying temperature compensation circuit, and displays the data. An alternative method is to use several chambers and one pass. Additional chambers may be used to increase the speed of the test, control interferences, or aid in identifying gases other than the oxygen component. The device may also have an interface piercing head manifold that allows CO.sub.2 and oxygen to be tested in the same container and in one preparation.

Abstract: An instrument for the measurement of vacuum within sealed packets 12, the packets 12 having a wall 14 that it can be deformed by the application of an external dynamic vacuum to an area thereof. The instrument has a detector head 18 for placement against the deformable wall 14 of the packet to apply the vacuum in a controlled manner to accomplish a limited deformation or lift of the wall 14, with this deformation or lift monitored by the application of light as via a bifurcated light pipe 20. Retro-reflected light through the light pipe is monitored with a photo detector 26. A change (e.g., a decrease) of retro-reflected light signals the wall movement such that the value of the dynamic vacuum applied through the head be to achieve this initiation of movement is equal to the vacuum within the packet 12. In a preferred embodiment a vacuum plate 44 is placed beneath the packet 12 to ensure that no deformation occurs on the reverse surface 16 of the packet.