APPARATUS FOR DETECTING A GAS IN A HEADSPACE OF A CONTAINER

Abstract

A transmitter-receiver arrangement for measuring concentration of gas and/or for measuring pressure in a container headspace, wherein the transmitter-receiver arrangement defines a measuring zone accommodating the headspace, and the transmitter-receiver arrangement includes a transmitter to emit electromagnetic radiation covering a wavelength range including an absorption line of gas, a receiver of electromagnetic radiation in the wavelength range, the receiver and transmitter positioned respective to each other defining a path for the electromagnetic radiation from the transmitter to the receiver, a fixating element for fixating the transmitter-receiver arrangement to the apparatus or filling machine, an electrically controllable actuator arrangement causing at least one common shift of the transmitter and receiver, a shift of the transmitter relative to the receiver, a change in spatial orientation of the transmitter and receiver relative to the fixating element, and a change in spatial orientation of the transmitter relative to a spatial orientation of the receiver.

Claims

1. A transmitter-receiver arrangement for an apparatus for measuring a concentration of a first gas and/or for measuring a pressure in a headspace of a container, wherein the transmitter-receiver arrangement defines a measuring zone for accommodating the headspace, and wherein the transmitter-receiver arrangement comprises a transmitter configured to emit electromagnetic radiation covering a wavelength range including an absorption line of the first gas, a receiver configured to receive electromagnetic radiation in the wavelength range, the receiver and the transmitter being oriented with respect to each other such as to define a radiation path for the electromagnetic radiation from the transmitter across the measuring zone to the receiver, a fixating element for fixating the transmitter-receiver arrangement to the apparatus or to a filling and/or closing machine, and an electrically controllable actuator arrangement configured to cause at least one of a common translatory and/or rotational displacement of the transmitter and of the receiver relative to the fixating element, a mutual relative translatory and/or rotational displacement of the transmitter relative to the receiver.

2. The transmitter-receiver arrangement according to claim 1, wherein the first gas is a non-inert gas.

3. The transmitter-receiver arrangement according to claim 2, wherein the first gas is oxygen and wherein the wavelength range includes the wavelength 760 nm.

4. The transmitter-receiver arrangement according to claim 1, wherein the transmitter comprises a tuneable diode laser adapted to emit electromagnetic radiation in the wavelength range.

5. The transmitter-receiver arrangement according to claim 1, the transmitter-receiver arrangement further comprising a casing defining an interior space and having an outer surface towards an exterior space, wherein the exterior space includes the measuring zone, and wherein the electrically controllable actuator arrangement is located in the interior space.

6. The transmitter-receiver arrangement according to claim 5, wherein the transmitter is arranged in the interior space and is separated from the measuring zone by a window, which is transparent in the wavelength range and which forms at least a part of the outer surface, and wherein the receiver is arranged in the interior space and is separated from the measuring zone by the window or by a further window, which is transparent in the wavelength range and which forms a part of the outer surface.

7. The transmitter-receiver arrangement according to claim 5, wherein at least a predominant part of the outer surface is formed by materials being resistant to hydrogen peroxide and/or wherein the outer surface has an arithmetic average roughness below or equal to 1.6 micrometers and/or the outer surface has no indentation and/or the outer surface has a geometry, for which an orientation avoiding horizontal faces exists.

8. The transmitter-receiver arrangement according to claim 5, wherein the casing is gas-tight.

9. The transmitter-receiver arrangement according to claim 1, further comprising a source of a second gas configured to flood a region along the radiation path for the electromagnetic radiation with the second gas.

10. An apparatus for measuring a concentration of a first gas and/or for measuring a pressure in a headspace of a container, the apparatus comprising a transmitter-receiver arrangement according to claim 1, and an evaluation unit operably connected to the receiver and configured to generate, based on the electromagnetic radiation received by the receiver, a numerical value indicative for the concentration of the first gas and/or for the pressure in the headspace.

11. A filling and/or closing machine for filling containers, comprising a filling station for filling liquid or solid contents into containers, an apparatus according to claim 10 and a conveyor system configured to transport the containers from the filling station to the measuring zone of the apparatus.

12. A method of determining a gas concentration of a first gas and/or for measuring a pressure in a headspace of a container, the method using an apparatus according to claim 10, and the method comprising the step of adjusting a position or a spatial orientation of the transmitter and/or receiver by means of the electrically controllable actuator arrangement.

13. A method of producing a tested closed container containing a gaseous phase in a headspace above a liquid or solid content, wherein the gaseous phase has a gas concentration of a first gas being below a predetermined test limit, the method comprising the steps: filling the content into the container, thereby establishing the headspace being free of the content, displacing a previous gaseous phase from the interior of the container by guiding a second gas into the container, closing the filled container by a closing means, determining a gas concentration of the first gas in the headspace of the filled and closed container by using an apparatus according to claim 10, and rejecting the filled and closed container if the determined gas concentration of the first gas is above the test limit or else accept the filled and closed container as tested closed container.

14. The method according to claim 12, wherein the first gas is oxygen.

15. The method according to claim 12, wherein a further step of bringing the measuring zone to overlap with the headspace of the container by shifting or rotating the transmitter or receiver by means of the electrically controllable actuator arrangement is performed before the step of determining a gas concentration of the first gas in the headspace of the filled container.

16. The method according to claim 12, wherein the steps of the method are performed by means of a filling and/or closing machine, comprising a filling station for filling liquid or solid contents into containers, an apparatus and a conveyor system configured to transport the containers from the filling station to the measuring zone of the apparatus, and wherein either filled containers continuously pass the measuring zone or wherein a handling system picks individual samples of filled containers and moves them to the measuring zone.

Description

[0058] The invention shall now be further exemplified with the help of figures. The figures show:

[0059] FIG. 1 a schematic view of a transmitter-receiver arrangement according to the invention;

[0060] FIG. 2 a schematic view of an embodiment of the apparatus for measuring a concentration of a first gas and/or for measuring a pressure in a headspace of a container.

[0061] FIG. 1 shows schematically and simplified, a transmitter-receiver arrangement 1 according to the invention. The transmitter-receiver arrangement is shown in operation. A transmitter 2 emits electromagnetic radiation 5 towards a measuring zone 11. The electromagnetic radiation is indicated by double lined arrows. Radiation 5′, which has passed the measuring zone, is received by a receiver 3. A fixating element 7 enables a fixating of the transmitter-receiver arrangement to elements in its environment. An electrically controllable actuator arrangement 8 is configured to shift or rotate the transmitter and the receiver with respect to the fixating element and with respect to each other. Possible movements, which may be caused by operating the actuator arrangement, are symbolically indicated by arrows. In dashed lines, a container 10, which is not part of the transmitter-receiver arrangement, is shown in a possible measuring position. The measuring zone 11 is overlapping a headspace of the container, i.e. the space above the contents of the container. The actuator arrangement shown is a multiple axis actuator arrangement. It enables e.g. to adjust the height of the measuring zone with respect to the fixating element by simultaneously shifting the position of the transmitter and the receiver up or down. The distance between the transmitter and the receiver may be adjusted, as well. A rotation or tilting movement of the transmitter may be applied to adjust a relative spatial orientation of the transmitter and the receiver, which accounts for refraction effects in the container wall, such as to assure that radiation leaving the measuring zone hits the receiver. By means of a horizontal linear axis directly attached to the fixating element, the transmitter and the receiver may be displaced as a whole in horizontal direction. An evaluation unit 4, shown in dashed lines, may be operatively connected to the receiver 3 and complement the transmitter-receiver arrangement 1 to an apparatus for measuring a concentration of a first gas and/or for measuring a pressure in a headspace of a container.

[0062] FIG. 2 shows schematically and simplified an embodiment of the apparatus for measuring a concentration of a first gas and/or for measuring a pressure in a headspace of a container. In addition to elements already discussed in the context of FIG. 1 it comprises a casing 9. The casing defines an interior space containing the transmitter 2, the receiver 3 and the actuator arrangement 8. It defines an exterior space comprising the measuring zone 11. A window 6 and a further window 6′ are transparent to the electromagnetic radiation in the wavelength range used for detecting the first gas. Radiation 5 from the transmitter passes across the window 6 to reach the measuring zone 11. Radiation 5′, which has passed the measuring zone enters through the further window 6′ into the interior space and is received by the receiver 3. The apparatus 30 may be mounted on a machine bed 21, which is indicated by dashed lines. Such a machine bed may belong to a filling machine. Furthermore, transport means 20 are indicated for transporting a container 10 to the apparatus. Such transport means may belong to a conveyor system of a filling machine. In the embodiment shown, a source 22 of a second gas is configured to flush the surrounding of the container and the interior space of the apparatus with a second gas, which is different from the first gas to be measured and which may e.g. be nitrogen in the case that the first gas is oxygen. The ceiling 9′ of the casing may have an arched shape or a shape of a saddle roof defined in the direction orthogonal to the cross-section shown in this figure, such that horizontal faces are avoided.

LIST OF REFERENCE SIGNS

[0063] 1 transmitter-receiver arrangement [0064] 2 transmitter [0065] 3 receiver [0066] 4 evaluation unit [0067] 5, 5′ radiation [0068] 6, 6′ transparent windows [0069] 7 fixating element [0070] 8 actuator arrangement [0071] 9 casing [0072] 9′ ceiling of casing [0073] 10 container [0074] 11 measuring zone [0075] 20 transport means [0076] 21 machine bed [0077] 22 source of second gas [0078] 30 apparatus for measuring a concentration of a first gas and/or for measuring a pressure in a headspace of a container