SE517191C2 - Method for measuring a volume in the form of a bread and an arrangement for measuring a volume of a bread object - Google Patents

Abstract

The present invention relates to a method and an arrangement for measuring the volume (1') of a bread object (1) placed in a defined space (2), the volume (2') of the defined space being chosen greater than the volume (1') of the bread object, wherein information representing the volume of the space when empty, and information representing the volume of the space reduced by the presence of the object constitute measurements enabling determination of the volume of the bread object. A single pressure source (4) adapted for a compressible gas or gas mixture is connected, via a common space (5), to said defined space (2) and also to a space (3) serving as reference, said spaces (2, 3) being identical. Each of said two spaces (2, 3) is connected individually to a sensor (6) for determining pressure differences, and a means (7) is utilised for evaluating the volume (1') of the bread object (1) on the basis of the information from said sensor (6).

Description

20 25 30 517 191 _2_ this information should, preferably directly, be able to constitute measuring quantities in order to be able to determine the volume of the object therefrom.

The invention is based on the known principle that when a delimited space, with a selected volume and a selected pressure, is supplied for a time a certain amount of compressible gas or gas mixture, such as air, the gas pressure within the space increases over time and if the amount of gas supplied is the same but the volume in the space chosen is smaller, such as due to the presence of an object, so over time the gas pressure within the later space rises faster.

Furthermore, it should be noted that the method has been developed primarily in order to be able to measure the volume of a ready-baked or baked product or an object in the form of bread in a non-destructive manner. It should be noted that even if the following description includes a measurement of a volume, the density of an object can of course be determined, by using a weighing device and thereby determining the weight of the object.

PRIOR ART OF THE ART Methods, which are based on the above-mentioned known principle, for being able to measure the volume of a loaf are previously known.

If the application is to have the volume measured for one or more breads, it can be mentioned that through the Swedish patent publication SE-C2-504 557 a method and a device are previously known for being able to measure the volume of a ready-baked bread.

Here, the possibility of having an ultrasonic transducer is used for a plurality of distance measurements during the entire measurement process and oriented in order to be able to evaluate a fixed distance to a known reference point (R) in the bread.

A relative movement is created between the bread (2) and the ultrasonic sensor (10) so that substantially the entire surface of the bread (2) successively during the relative movement is hit by a measuring signal from the ultrasonic sensor (10). During the relative motion, the distance from the ultrasonic sensor (10) to the bread (2) is measured several times.

Because the distance between the ultrasonic sensor (10) and the reference point (R) is known, the distance from the reference point (R) to a number of measuring points on the surface of the bread can be calculated by means of the distances measured with the ultrasonic sensor (10).

L For each measured distance from the reference point (R) to the surface of the bread, a sub-volume of the bread is determined and the total volume of the bread is determined by summing all sub-volumes.

In addition to the method and device specified above, other methods have been used to have the volume of a pre-baked bread measured.

In every industrial bread baking process, the current quality of the raw materials used, in particular the quality of the flour, and the used baking process are absolutely decisive for the baking result.

A common way to have the current quality of utilized flour measured is to have bread baked according to a standardized baking test, for example a test authorized by the American Association of Cereal Chemists or by the International Association for Science and Technology, and then to have measure the volume of the pre-baked bread. í VIIEE * ll! It is often the case that the volume of bread is determined by placing the bread in a container with a known volume, after which the container is filled with a calibrated amount of rapeseed or poppy seeds, which may be enclosed. The bread volume is then read on a shell on the container, which is graded as a function of the volume of the container and the calibrated amount of seed.

It is obvious that this method, for a measurement of the actual bread volume, has a number of disadvantages. The measurement is performed completely manually. It is time consuming and cumbersome.

The amount of seeds must be calibrated at regular intervals, as seeds often get stuck in small cavities in the outer structure of the bread and accompany the bread from the container. The method also has a lack of accuracy.

If, for example, the container is shaken during the measurement, rapeseed is packed more tightly and then the volume decreases. In addition, the volume of the container must be adapted to the size of the bread in order to achieve good accuracy. You may thereby be forced to work with a number of different bread volume meters.

Patent publication FR-A-2 544 072 discloses an alternative way of having the volume of bread measured, according to which a bread is placed on a rotating table and illuminated from behind.

A camera registers a silhouette image of the bread from a place diametrically opposite the place from which the bread is illuminated. Then the bread is rotated and the measurement is repeated for a number of different rotation angles. The volume of the bread is determined by a computer processing of the silhouette images, each silhouette being divided into a number of segments, where the length and height of the segment are used to have the volume of the segment determined according to a particular formula 5.

H Y HM 'líE T Ti 10 15 20 25 30 517 191 _ 5 _ This method has the disadvantage that certain cavities in the surface of the finished bread are not visible in the silhouette image.

As the bread often has a number of larger and smaller such cavities, this leads to the method not being as accurate as one would like.

The prior art also includes the following patent publications: GB-A1-2 218 513.

Here, an apparatus is shown and described for being able to measure the external shape of an object in three dimensions, and where a special adaptation has taken place in order to be able to evaluate the external shape of a piece of bread, or a loaf, with laser technology.

The apparatus shown here relates to the technical field to which the present invention also relates.

The apparatus is based on the use of a laser technology-based, distance measuring equipment and requires; means for mounting the object within the range of the distance measuring equipment, means for rotating the object, means for moving said equipment linearly relative to the object and a computer unit for processing the measured distances in order to be able to calculate and give desired information about the object's shape and volume.

The device is further based on the distance to selected points on the object's surface being evaluated in relation to a number of pre-selected positions.

WO-A1-95 / 22744. Here, too, a method and a device are indicated for being able to measure the actual volume of a loaf of bread in the form of a loaf. i Vlíßlïï EE I fl iíïšl 'ÉTE i x 10 15 20 25 30 517 191 _ 6 _ An ultrasonic transmitting unit (10) is used here, which is located at a certain distance from a reference point (R) related to the lobe during the entire measurement procedure. Here, too, it is a question of creating a relative movement between the loaf (2) and the transmitting unit (10) and having each point on the surface of the loaf sensed.

The current distance or distance is thus read several times during the relative movement.

This device requires that the distance between the transmitter (10) and the reference point is known. For each measurement, a volume fraction corresponding to the measuring point can be evaluated and a summation of all volume proportions valid for all measuring points will be able to give a measure of the total volume of the loaf.

GB-A1-2 327 760.

Here, a measuring device based on gas displacement is shown and described and which comprises a sensor (3) which operates by a differential pressure.

A first chamber (1) for the measuring device is connected to a first input of the sensor (3) and this chamber is intended to be able to accommodate the object (13) intended for the measurement.

This is about measuring the volume of a hard object (13).

A second chamber (4) for the device is connected to a second input for the sensor (3).

Furthermore, there are means for simultaneously being able to modify the volume of the first (1) and the second chamber (4) by preselected values by means of a compression. l ITIITZÉT HI ílï fl išïïfï llï? 11% 10 15 20 25 30 517 191 _ 7 _ The device is specially adapted to measure the volume of grains or other hard and non-compressible kernels.

Thus, a single core (13) is placed in one of the chambers, such as the first chamber (1), and a piston (14) is placed in separate chambers (1,4).

The pistons are interconnected so that they can be displaced simultaneously and uniformly into their respective chambers and thus allow the volume of each chamber to be reduced in time and uniformly in the same way. The pressure difference caused by the decreasing volumes is sensed and read.

The volume of the grain or core (13) in the first chamber (1) decreases the volume compressible by the piston (14) and consequently different degrees of compression and different pressure variations for the two chambers result in a common and uniform displacement of the two pistons.

US-A-4 184 371.

Here is shown an apparatus for being able to measure the density of a body and which for this purpose uses a measuring chamber and a reference chamber as well as a unit generating sound waves.

A unit shall supply both chambers simultaneously and in a phase-correct pressure variations and where pressure differences between the two chambers are evaluated in order to obtain a value for the object's volume.

The object is illustrated here as a human being.

WO-A1-92 / 00700.

Here, a method and apparatus for measuring the volume of an object, such as a human, are shown and described. t) rfwn | mmnw fl ~: “l 10 15 20 25 30 517 191 _ 8 _ Here again two chambers are used, a first, serving as a test chamber, chamber (2) but a door (9) or similar closing means by which the person can enter and a second, as a reference, chamber (3)) and means for cyclically changing the volumes of the two chambers in an exactly complementary manner.

Shown here is an oscillating diaphragm (18) oriented between the chambers (2 and 3, respectively) in order thereby to be able to produce a counter-oscillating change in the volumes of the two chambers.

This diaphragm (18) may be in the form of a loudspeaker.

In particular, a frequency of about 3Hz is indicated here for the oscillating change in volumes.

US-A-5,824,892.

Here, an embodiment of an acoustic device is shown and described in order to be able to measure volume differences.

For this purpose, a container (1) serving as a reference and a container (2) adapted for the measurement are used.

These containers (1,2) are separated from each other by a partition wall (4) and where the partition wall carries a loudspeaker (6).

Instantaneous pressure values are sensed and recorded via microphones (ll, l2).

Through this arrangement, complementary variations of the volumes in the two chambers (1,2) are created here via a vibrating part (7).

Furthermore, means are provided for being able to evaluate the current pressure in each chamber, means for being able to control the volume changes in real time and means for being able to analyze detected pressure values. .

US-A-4,369,652 Here is shown and described a method and a measuring chamber for being able to evaluate the volume of a body and where the volume of the measuring chamber is changed by means of a piston (8) placed in a cylinder (7). A reference chamber (5) can also be used and where the volume is changed by means of an actuated piston (II) located within a cylinder (10).

The pistons (8, 11) and associated cylinders (7, 10) are assigned different cross-sectional areas and are simultaneously actuated by one and the same piston rod (9).

DESCRIPTION OF THE PRESENT INVENTION TECHNICAL PROBLEM Considering the fact that the technical considerations that a person skilled in the relevant technical field must make in order to offer a solution to one or more technical problems posed is initially an insight into the measures and / or the sequence. which is to be taken partly a choice of the means or means required, in view of this the subsequent technical problems should be relevant in the production of the present invention object.

Taking into account the prior art, as described above, it should be seen as a technical problem to be able to assign a method and an arrangement to be able to measure a volume for an object with simple means and with good accuracy, and which is based on the principle to place the object in a closed delimited space and to this utrwmtrwmnwiv ~: 10 15 20 25 30 517 191 _10 .. space to have a gas mixture added and to evaluate the increasing pressure of the gas mixture within the space and to determine the volume of the object on this basis.

There is also a technical problem in being able to realize the significance of and the advantages associated with having the object placed in the delimited space, where the volume of the delimited space is adapted to be chosen slightly larger than the volume of the object, whereby a first information representative of an empty space of a first space and a second information, representative of a second space, reduced by the presence of the object, volume, few constitute measuring quantities, in order to be able to determine the volume of the object in a computer unit in a simple manner.

There is then a technical problem in being able to realize the significance of and the advantages associated with allowing a pressure source to be adapted for a compressible gas or gas mixture and where this pressure source must during a selected measuring period be partly connected to the said, as measuring chambers serving delimited space, partly be connected to a space serving as a reference, where both spaces should advantageously be chosen equally large.

There is then a technical problem in being able to realize the significance of and the benefits associated with allowing the said spaces to be identical.

There is also a technical problem in being able to realize the importance of allowing said two spaces, each, to be connected to a sensor determining a pressure difference, and to allow the sensor to be connected to means used to from the information from said sensor have the volume of the object evaluated.

There is also a technical problem in being able to realize the significance of allowing said pressure source to be arranged to emit current pressure waves as a loudspeaker.

There is also a technical problem in being able to realize the significance of and the advantages associated with allowing the pressure source to be arranged to emit pressure waves of a distinct character, such as a sine character.

There is also a technical problem in being able to realize the significance of and the advantages associated with allowing the pressure source to be adapted to emit pressure waves with a frequency selected below 20 Hz, especially within a range above 5 Hz.

There is also a technical problem in being able to realize the importance of allowing said sensor to be connected to each of said spaces and to be selected sensitive enough to be able to register relatively small pressure differences, occurring during a selected measuring period.

There is also a technical problem in being able to realize the significance of choosing the measurement period so that it is within a range of less than 10 seconds, such as between 1.0 and 5.0 seconds.

There is also a technical problem in being able to realize the significance of allowing the said means to be adapted to convert sensor-delivered information into digital information and thereby evaluate momentary differences between occurring pressure variations between the spaces.

There is also a technical problem in being able to realize the importance of allowing the said evaluated pressure variations during a measurement period to be comparable with stored information, in å 'Iflfñlš? lïí ”'[1llTE'L" f 1 "' 10 15 20 25 30 517 191 _12- referring to a number of reference volumes m.m. from previous measurements and in a corresponding comparison generate a signal, representative of a volume value corresponding to a designated reference volume.

There is also a technical problem in being able to realize the significance of allowing said pressure waves to be selected with a maximized pressure change caused by an alternating voltage of 10V amplitude connected to a loudspeaker.

Considering the previous state of the art, it should be seen as a technical problem to be able to realize the significance of and the advantages associated with allowing two spaces, one serving as a reference space and one serving as a measuring chamber, to be so interconnected that in said two spaces, the same basic pressure occurs during the beginning of the measurement period and also during the measurement period.

There is also a technical problem in being able to realize the significance of and the benefits associated with allowing a sound source to transmit sound waves to a space close to the sound source, which via channels, such as equally shaped channels, are connected to each other. space, a reference chamber and a measuring chamber.

In addition, there is a technical problem in being able to realize the significance of and the advantages associated with having the volume of the measuring chamber selected in dependence on the object's size and structure, in order to create conditions for an accurate measurement result.

It thus becomes a technical problem to be able to realize the significance of and the benefits associated with having the number of wave motions selected during the current measurement period and make a comparison at each wave motion. .

THE SOLUTION The present invention is thus based on a method and an arrangement for being able to measure a volume of an object in the form of bread, placed in a delimited space, where the volume of the delimited space is selected slightly larger than the volume of the object, whereby a first information , representative of an empty volume of a space, and a second information, representative of a space, reduced by the presence of the object, volume few constitute measuring quantities in order to be able to determine the volume of the object therefrom.

In order to be able to solve one or more of the above-mentioned technical problems, the present invention now teaches that a single pressure source, adapted for a compressible gas or gas mixture, is partly connected to said delimited, space serving as a measuring chamber, partly connected to a space serving as a reference, wherein said spaces are advantageously selected identically equally.

Furthermore, it is instructed that said two spaces shall each be connected to a sensor determining a pressure difference and that means be used to be able to evaluate the volume of the object from the information from said sensor.

As proposed embodiments, falling within the scope of the inventive idea, it is indicated that said pressure source is arranged to emit sound-related pressure waves from a loudspeaker equipment.

The pressure source is further arranged to emit pressure waves of a pronounced character, such as a sine character.

Ii! H l llíl fi fí? llšïili fl lílí "fi I 10 15 20 25 30 517 191- _ 14 _ The pressure source is further adapted to emit pressure waves with a frequency selected below 20 Hz.

Furthermore, the invention indicates that the pressure source should be adapted to emit pressure waves with a frequency above 5 Hz.

Furthermore, the invention proposes that said sensor should be connected to each of said spaces and selected sensitive enough to register small pressure differences occurring during a measuring period.

The invention also indicates that the measuring period should be selected to between 1.0 and 5.0 seconds.

Said means is further adapted to convert sensor-delivered information into digital information and thereby evaluate instantaneous differences between occurring pressure variations between the spaces.

The invention also indicates that evaluated pressure variations during a measuring period must be comparable with stored information, relating to a number of reference volumes, etc. for previous measurements, and in a corresponding comparison, a signal corresponding to a volume value valid against a designated reference volume is generated.

Furthermore, the invention provides instructions for allowing said pressure waves to be selected with the maximized pressure change obtained by a voltage variation to the speaker of about 10V.

BENEFITS The benefits that can mainly be considered as characteristic of in IÜMÉÉ ll? WHEN i 'i 15 15 20 25 30 517 191 _15 .. a method and an arrangement, in accordance with the present invention, is that they could be used in an advantageous manner to be able to quickly determine the volume of a bread object with a pronounced accuracy, also if the object is of a porous nature.

Furthermore, the method and arrangement can be used in a production line, in order to be able to determine the current volume for a bread object at different stages.

This is especially true in the production of bread where different properties of the bread must be able to be controlled during the production process.

What can primarily be considered as characteristic of a method, in accordance with the present invention, is stated in the characterizing part of the appended claim 1 and what can primarily be considered as characteristic of an arrangement is stated in the characterizing part of the following claim 14.

BRIEF DESCRIPTION OF THE DRAWINGS A presently proposed embodiment of a plant, adapted to be able to work according to the method, in order to be able to measure a volume of a bread object placed in a delimited space, will now be described in more detail with reference to the accompanying drawing, in which ; Figure 1 schematically shows a plant adapted to be able to work according to the proposed method; i í IÜWEÉ llêíí flfi š Imfšï 10 15 20 Figure 2 Figure 3 517 191 _ 16 _ den, shows a simplified example of pressure path-related sine curves, which in a sensor unit can be compiled into a signal, representative of an object's volume and shows a diagram-related example of a practical measurement of a porous bread object with different sizes to be able to determine the volume of the bread object.

DESCRIPTION OF THE NOW PROPOSED EMBODIMENT The method indicated according to the invention, and a plant for this, is used to be able to measure a volume of a bread object 1, placed in an object 1 delimiting space 2, where the volume 2 'of the delimited space 2 is suitably selected. slightly larger than the object l 'volume l'.

The ratio of the volume 1 'of the object 1 to the volume 2' of the measuring chamber 2 shall normally exceed 50% of the material structure of the object.

Fundamental to this invention is that the ratio between the volume 1 'of the object 1 and the volume 2' of the space 2 should advantageously be chosen depending on the nature of the object, so that in the case of a highly elastic and porous object they, such as 80 to 95%, are suitable while in other less porous objects the ratio can be chosen lower, such as 75-90%.

In the case of firmer objects, it can be predicted that too small a difference in the volumes (space 1 / space 2) can give too large pressure differences and too large differences in volume such as up to 95% and can be due to a large ratio in IMIIEE * HE WH? '' 'Il 10 15 20 25 30 517 191 _ 17 _ mer can give too small pressure differences for optimal conditions to apply for an accurate measurement.

The invention is based on the availability of a first information, representative of the empty volume of the space 2 and / or the space 3, such as the empty volume 3 'of the space 3, and a second information, representative of the space 2, reduced by the presence of the object 1, volume 2 " , which shall constitute measuring quantities, detectable via measuring channels 2a, 3a, in order to be able to determine the volume 1 'of the object 1 by a difference measurement.

The mentioned information primarily applies to the time-increasing pressure change that applies in spaces 2, 3 in the case of a simultaneous supply of a pressure surge through each of the inlet ducts.

The information may also apply to the time-reduced pressure change that applies in the space when an overpressure due to the pressure surge is present within the space and this overpressure must be equalized via the inlets to an adjacent space 5.

Thus, the use of a pressure source 4, which is adapted for an influence of a compressible gas or gas mixture 5 ', is indicated.

The compression and decompression via the pressure source 4 of the gas 5 'within the space 5 must take place with a well-definable shape, such as a pronounced sinusoidal shape or the like, for the time-related pressure changes with as little contribution from harmonics as is practically possible.

This requires an adjustment of the shape and size of each space, especially for a space 5, which for a pressure equalization of the basic pressure in each of the spaces 2, 3 via channels 2b, 3b is connected to these. ï ilflli fi ï Il IEEMIÉ ”Ål? 10 15 20 25 30 517 191 _ 13 _ Furthermore, the space 5 must be shaped so that the pressure waves generated by the pressure source 4 can be distributed equally to the two spaces 2, 3 or at least predictably distributed to the two spaces. Although the spaces 2, 3 are shown as identically shaped spaces in Figure 1, it should be taken into account that the spaces could be shaped differently, however, information on the present differences is required.

The pressure source 4 is thus during a selected measuring period via the space 5 and the gas mixture 5 'partly acoustically connected to said delimiting space or measuring chamber 2, via a channel 2b, partly acoustically connected to a reference space 3 serving, via a channel 3b .

Said spaces 2, 3 should advantageously be identical in shape and volume, but in addition connections and dimensioning of these via the channels 2b and 3b should be identical. So do channels 2a, 3a.

By the term "identically similar" is of course meant to also include substantially equal in terms of the acoustic and pneumatic properties in question.

Said two spaces 2, 3 are each connected, via their respective channels 2a, 3a, to a sensor 6 determining a pressure difference.

The said sensor must then be so sensitive that it can evaluate small pressure variations between the spaces 2, 3 during the current measuring period. It must thus be able to evaluate a number of measured values during a measuring period in order to be able to determine a difference curve and an average value formation of a number of measured values.

Iï 1 rm: m mmm: vr 10 15 20 25 30 517 191 _19_ The pressure difference sensor or sensor 6 can normally be adapted for a measurement within the pressure differences +/- 5 cm water column.

There is nothing to prevent the amplifier sensor 6 from having an amplifier and a low-pass filter connected.

A data-equipped means 7 can be used to have the volume of the object evaluated from difference-related information from said sensor 6.

In particular, it is instructed that said pressure source 4 shall be arranged to have the required pressure waves emitted from a loudspeaker 4a. These pressure waves should advantageously be adapted to a simple and pure waveform, such as a distinctly simple sinusoidal character or other simple waveform. L This means that the temporal pressure change, generated by the loudspeaker 4a, must have positive and negative values corresponding to a sinusoidal shape and superimposed a basic pressure valid for spaces 2, 3 and 5.

The loudspeaker 4a is driven by circuits not shown in the figure, containing amplifiers, wave-forming generators, etc.

Furthermore, the pressure source or loudspeaker 4 is adapted so that it can emit, during the measurement period, pressure waves with a frequency below 20 Hz.

A circuit required for this is not shown in more detail in Figure 1.

The pressure source or loudspeaker 4 is furthermore adapted and controlled so that they can generate and emit pressure waves with a frequency above 5 Hz, such as between 5 and 15 Hz, alternatively 10 and íïl i; i Ifllííïæ HI Hill 'I? 10 15 20 25 30 517 191 _ 20 _ 18 Hz, depending on the structure of the object material.

Said sensor 6 is connected to each of said spaces 2, 3 and selected sensitive enough to be able to register even small pressure differences occurring during a measuring period.

The measurement period in the present case should be selected to between 1.0 and 5.0 seconds.

The invention also comprises the embodiment that the frequency of the pressure waves, during a selected measuring period, must be able to be varied, such as increasing and / or decreasing.

Thus, during the measurement period, the waveform can be selected to increase from 5 Hz to 10 Hz or decrease from 20 Hz to 10 Hz or vice versa. L There is nothing to prevent both increasing and decreasing frequency during one and the same measurement period or vice versa.

Said means 7 is adapted to be able to convert sensor-emitted information in a unit 7a into a digital information and thereby evaluate instantaneous differences between occurring pressure variations within the spaces 2, 3.

The unit 7a is now connected to two memories, designated 7b and 7c.

In a first memory 7b a number of reference values can be stored. Thus, values derived from one and the same object with different volumes l 'can be stored. Values derived from one and the same object with different shapes and structures can also be stored. According to the invention, it is thus indicated that evaluated pressure variations during a selected measuring period should be comparable to one or more combinations of one or more stored information in the memory 7b. , relating to a number of previous measurements and / or reference volumes IILITI.

Each measured value during a measuring period can be temporarily stored in a memory 7c.

These measured values can also be entered as reference values in memory 7b.

Via a circuit 7d, the measured values 7c which occur during a selected measuring period can be compared with stored measured values within the memory 7b, where one or more lists of measured values and their equivalent in an evaluated volume for the object 1 are stored, and thereby designate and generate a signal representative of a volume corresponding to current measured values.

In a corresponding comparison, a signal representative of a volume value corresponding to a designated reference volume is generated and this is shown on a display 7e.

The pressure wave is selected with a maximum pressure change adapted to the volumes and shape of the spaces.

Figure 1 shows an arrangement where the same basic pressure will occur in spaces 2, 3 at the beginning of and during the entire measurement period and thus an otherwise required calibration can be avoided.

Figure 2 schematically illustrates, below A, a sinusoidal wave motion generated by the sound cellar 4 and in the space 5.

'J: ï “Hïxlišï lä IWIIII' 10 15 20 25 30 517 191 _22 ..

When this wave motion, an increasing and decreasing of the basic pressure in the gas 5 ', is allowed to pass into the measuring chamber 2, the amplitude rises, below B, due to the volume 2 "limited by the object.

When the corresponding wave motion is allowed to pass into the reference chamber 3, the amplitude rises, below C, less because the volume 3 'has a larger value than the volume 2 ".

The sensor 6 can now sense the differential pressure, below D, in the chambers 2 and 3 and signal process this in the computer equipment 7.

A reference to Figure 3 should illustrate the measurement result from a practical application with a porous object.

In such objects it is important to allow the basic pressure to be adapted to the current atmospheric pressure and that the generated pressure waves should have small amplitude values so that the object does not undergo a deformation during the negative pressure phase and / or overpressure phase, ie. bread) is not affected by the measurement.

Figure 3 intends to illustrate three different measurements with three different sized objects with the same structure.

The object 1 is subjected to pressure changes for a period of 5 seconds and with five measuring points within the measuring time. The object here is relatively small in relation to the measuring chamber's 2 volume, say about 50%.

A slightly larger object la (1.5 x object 1 above), is measured in the same way as above and with a measured curve shape in the middle of the graph.

EHWEIZ 'fïÉ šÉl ^ z arfmærf í I 10 15 20 25 30 517 191 _ 23 _ A large object lb (2 x object 1 above), is measured in the same way and this then has a degree of filling of about 95% and with a measured curve shape to the right in Figure 3.

From this it can be stated that at a 50% degree of filling corresponding to the size of the object 1, measured measuring points become quite equal and with an increasing degree of filling, the measured values become more scattered.

The invention is of course not limited to the above-mentioned exemplary embodiment, but may undergo modifications within the scope of the inventive concept illustrated in the following claims. 1_ ~ «» mnmwnrwr

Claims (26)

10 15 20 25 30 517 191 _ 24 _ Patent claim A method for measuring a volume of an object, in the form of a loaf, placed in a first delimited space, where the volume of the delimited space is selected greater than the volume of the bread object, wherein an information, representative of the empty volume of the space, and a information representative of the volume of the space, reduced by the presence of the object, constitutes measuring quantities in order to be able to determine the volume of the bread object therefrom, characterized in that a single pressure source (4), adapted for a compressible gas or gas mixture (5 '), is via a common space (5) partly connected to said delimited space (2) partly connected to a space (3) serving as a reference, said two spaces being chosen identically equal, that for said two spaces each is connected in a known manner to a pressure difference determining sensor (6) and that a means is used for having the volume of the bread object evaluated from the information from said sensor. 2. A method according to claim 1, characterized in that said pressure source is in the form of a loudspeaker which emits said pressure waves to the common space. 3. A method according to claim 2, characterized in that the pressure source is arranged to transmit pressure waves of a pronounced character, such as a sine character, to the common space. 4. A method according to claim 1, 2 or 3, characterized in that the pressure source is adapted to emit pressure waves with a frequency of less than 20 Hz. 5. A method according to claim 1 or 2, characterized in that the pressure source is adapted to emit pressure waves with a frequency of more than 5 Hz. 6. A method according to claim 1, characterized in that said sensor is connected to each of said spaces and selected sensitive enough to register small pressure differences occurring during a measuring period. 7. A method according to claim 1 or 6, characterized in that a measuring period is selected to be between 1.0 and 5.0 seconds. Method according to claim 1, characterized in that said means is adapted to convert sensor-emitted information into digital information and thereby evaluate instantaneous differences between occurring pressure variations between the spaces. Method according to claim 8, characterized in that evaluated pressure variations during a measuring period are comparable with stored information, relating to a number of reference volumes, etc. for previous measurements, and in a corresponding comparison, a volume value corresponding to a designated reference volume is generated. 10. A method according to claim 2, characterized in that said pressure waves are selected with a maximized pressure change corresponding to the object. 11. A method according to claim 1, characterized in that a space serving as a reference and a space serving as a measuring chamber are interconnected so that the same basic pressure is present in the two. i 'IHM? lll ím fl l "å '10 15 20 25 30 517 191 _26_ 12. A method according to claim 1, characterized in that the pressure source is adapted to operate within a space which is serially connected to said two parallel spaces. 13. A method according to claim 1, characterized in that the volume of the measuring chamber is selected depending on the shape and structure of the object. Arrangement for being able to measure a volume for a bread object placed in a first delimited space, where the volume of the delimited space is selected larger than the volume of the bread object, wherein an information, representative of the empty volume of the space, and an information, representative of the space , volume reduced by the presence of the object, constitute measuring quantities in order to be able to determine the volume of the bread object therefrom, characterized in that a single pressure source, adapted for a compression of a gas or gas mixture, is arranged in a space (5) which via each channel (2b, 3b) is connected to said delimiting space (2) and connected to a space (3) serving as a reference, said spaces (2,3) being adapted to be identical from a measurement point of view, that said two spaces (2,3) are connected in a known manner via their respective channels (2a, 3a) to a sensor (6) determining pressure differences, and that a computer-equipped means is used for transmitting from the information from said sensor (6) evaluate the volume of the bread object. 15. An arrangement according to claim 14, characterized in that said pressure source is arranged and adapted to have said pressure waves transmitted from a loudspeaker to said channel-provided space (5). 1 :. ITÅWE 'EUMM? II '10 15 20 25 30 517 191 _ 27 _ Arrangement according to claim 15, characterized in that the pressure source is arranged and adapted to emit pressure waves of a pronounced character, such as a sinusoidal character. Arrangement according to claim 14 or 15, characterized in that the pressure source is arranged and adapted to emit pressure waves with a frequency below 20 Hz. Arrangement according to claim 14 or 15, characterized in that the pressure source is adapted to emit pressure waves with a frequency above 5 Hz. Arrangement according to claim 14, characterized in that said sensor is connected via channels to each of said spaces and selected sensitive enough to be able to register small pressure differences, occurring during a selected measuring period. Arrangement according to claim 19, characterized in that one or more measurement periods are selected to between 1.0 and 5.0 seconds. Arrangement according to claim 14, characterized in that said means is adapted to convert sensor-delivered information into digital information and thereby evaluate instantaneous differences between occurring pressure variations between the spaces. Arrangement according to claim 21, characterized in that evaluated pressure variations during a measurement period are comparable with one or more stored information, relating to a number of reference volumes, etc. for in i I? Iäí Élïflšifl '10 15 20 25 30 517 191 äëišf - - = _28- previous measurements, and in a corresponding comparison let generate a volume value corresponding to a designated reference volume. Arrangement according to claim 15, characterized in that said pressure waves are selected with a maximum pressure change dependent on the object. Arrangement according to claim 14, characterized in that a space serving as a reference and a space serving as a measuring chamber are interconnected so that the same basic pressure will be present in the two. Arrangement according to claim 14, characterized in that the pressure source operates within a space which is serially connected to said two spaces connected in parallel. Arrangement according to claim 14, characterized in that the volume of the measuring chamber is selected depending on the shape and structure of the object. wwnz 'š ï-H'