WO2007003154A2 - Method and device for determining the quality of plant products - Google Patents

Abstract

The invention relates to the field of plant products, especially food such as fruit and vegetables and the analysis of substances thereof or the condition of said substances by measuring the physical properties of the substances with the aid of a method and a self-contained device which is suitable for general use. Said device is embodied as a measuring apparatus for assessing the quality of plant products, for which the degree of ripeness of plant products is used. The degree of ripeness can be determined by electrically measuring non-electrical quantities and can be displayed via adequate representing means. Additional functions in the measuring apparatus, such as voice recording, a barcode reader, information on offers, and a pocket calculator, facilitate shopping.

Description

 Title Method and device for determining the quality of plant products

Background of the invention

Technical area

The present invention relates in general to the field of vegetable products, in particular foods such as fruit and vegetable fruits and their examination of substances, or the state of substances, by determining their chemical or physical properties by means of a device for general use, their construction and execution with similar industrial equipment is comparable. The device is a quality assessment device for vegetable products. The main cause of loss of quality to the spoilage of plant products are

I ₅ either chemical changes or microbiological processes.

Background in the art

There are measuring devices for the quality assessment of food, as known from the prior art, in various building designs. As a rule, the quality assessment is based on weight, color, shape and degree of maturity. To determine the degree of ripeness, various measuring methods are known from the prior art. For example, from DE 33 26 245 C2 a method and a device is known, wherein the invention describes the sorting of fruits and a quality assessment of the fruits. The sorting is carried out by known sorting devices, wherein the examined objects of the vegetable products in a rank, according to a classification by weight and according to the outer dimensions, takes place. The classification of the quality of the fruits is carried out by measuring devices that are part of the sorting device. The quality of the fruit is determined by its color, ie the different degrees of color, with the help of a television camera. The sugar content, the acidity and the degree of ripeness can be determined by an IQ analyzer, the degree of ripeness being determined by measuring the chlorophyll contained in the fruit and measuring the difference in optical density.

The disadvantage of this method for determining the degree of ripeness on the one hand is that the measuring methods or the measuring devices are very complicated and expensive and can only be operated by qualified personnel and used stationary and on the other hand the fruits are damaged by the measuring method.

From the prior art are also the Penetrometertest and the associated

Measuring device known. The meter measures the penetration of the tip of a hard rubber cone into the sample. The rubber cone weighs 12 grams, has a height of 3.81 cm and at its base a diameter of 3.81 cm. The inverted cone is supported by a freestanding pole that weighs 48 grams. The disadvantage of this device is that it can only be used for frozen goods.

As part of the quality control of fresh fruit another hand penetrometer is known, which has an indentor to determine the degree of ripeness of fruits. The indenter uses a 7/16 "(1 square centimeter) or soft fruit 5/16" (0.5 square centimeter) punches. During the measurement, the fruit is damaged and it is a mechanical measuring method.

DE 102 14 780 A1 and DE 102 14 781 A1 disclose a method and a device for determining the qualitative and quantitative ingredients of fruits and vegetables. In this case, in one embodiment, a flat surface of an ATR body of a measuring unit can be placed on the fruit or vegetables or the pulp can be pressed into the measuring body. In this way, the degree of ripeness of the fruits can be determined. This method and apparatus is an infrared measurement. Again, the disadvantage is that the ATR measuring body must be brought into direct contact with the pulp or even immersed in this. The further disadvantage is that it is a laboratory meter, which is expensive and can only be operated by qualified personnel and used in a stationary manner. The invention is therefore an object of the invention to provide a method and an apparatus of the type mentioned, which avoids the aforementioned disadvantages of the known methods and arrangements and to provide a technical solution that allows a more cost-effective, with simple functional geometry and versatile

5 to develop measuring device and method, wherein the device is easy to handle, moreover, by extreme robustness even in continuous operation, e.g. under production conditions during harvesting, loading, packaging of the fruit into the packaged goods or sale to the end user, and thus can be easily used at any location for non - destructive measurement and by precision in the

I ₀ Qualitative / quantitative determination of the quality of the fruit is characterized.

According to the invention this problem is solved by the characterizing features of claim 1. Advantageous embodiments and modifications of the invention will become apparent from the following dependent claims and the following descriptions.

I ₅ Description of the invention

In order to provide a method and device equipped with these features of the present invention for determining the well-being of plant products, in particular foods, such as fruit and vegetable fruits, it is proposed according to the invention, on the one hand, to use a simple physical measuring method, which is used for detecting, evaluating and View of the state of the substance with the help of the physical properties of the herbal products is suitable, and on the other hand a device for _. To develop the method to develop, which corresponds in size and comfort which portable mobile phones and in the operation for general use is suitable without special knowledge and does not require mains power, and allows the examination of the ₅ state of the substance by a nondestructive measurement.

The nondestructive method may be a physical measuring method, wherein the physical measuring method may be formed from an electromechanical method and / or from a capacitive method.

The subject matter of the present invention is thus a non-destructive measuring method and a device for determining the state of well-being or for ascertaining the quality of plant matter Products and their individual components. That is, the biological substances of the vegetable products can be examined because of their variable physical properties. One method is based on the assessment of the vegetable products by measuring electrical non-electrical quantities and another method of measuring electrical ones

5 sizes. A characteristic for the evaluation of the vegetable products is the condition of the constituents of the substance. The condition of the constituents of the substance is a measure of the quality of the vegetable products. The quality of the vegetable products can be represented in maturity levels. The spectrum of ripeness ranges from "immature" ... to "overripe", where "unripe" represents the raw state of the vegetable products. The lo number of maturity levels between the maturity levels "immature" and "overripe" may decrease

Requirement of industry or consumers. For example, ripeness may be represented by other terms, such as "hard" pulp ... to ... "soft" pulp or ripeness "0" ... to ... "10". Advantageously, four to five ripeness levels are used to assess the state of the biological substances of the plant

15 products set. The maturity is determined by the physical

Examination of the biological substance in the vegetable products. The substance under investigation consists mainly of pulp with a more or less hard shell, which protects the pulp from drying out, the pulp containing plant cells. The shell and the pulp together form the body of the fruit. The plant cells are carriers or storage of an aqueous solution. The aqueous solution in the cell exerts hydrostatic pressure on the cell wall causing the cell wall to change over time.

In "unripe" plant products, the plant cell has a certain state, which changes with the maturity of the fruit. Ie, the state of the plant cell thus ₅ represents a certain level of maturity of the fruit, or the fruit pulp, which is ultimately a criterion for the quality of the plant product.

The vegetable products form with their outer skin (shell) a closed body. The body behaves, similar to other hollow bodies, as a resonating body, whose task is the amplification of waves. A herbal body contains many resonators. A 0 resonator is an oscillatory system (see below 1) whose substance settles to certain frequencies (natural frequency) (see below 2) when excited at this frequency. The vegetable products are hydromechanical resonators in which a delimiting mass of liquid by reflection on their Boundaries moved in the form of a standing wave. The boundary of the liquid mass (aqueous solution of the plant cell) results from the cell wall or cell membrane of the plant cell.

To 1) oscillatory system

In the case of excitation of the surface of the vegetable product, the substance of the vegetable product usually stirs. two vibrations,

a) the free vibrations, whereby the free vibrations ausfuhrt a vibrating body, which left after its deflection itself, oscillating returns to the equilibrium state and the free vibration with the natural frequency whose size depends on the excitation conditions, by the ever-present

Attenuation during the settling time,

b) the forced oscillation, the forced oscillation in the narrower sense being the excitation frequency (s) whose amplitude (s) is constant and the intensity of the excitation, the ratio between the excitation frequency (or one of the excitation frequencies) and the excitation frequency Natural frequency (or one of the natural frequencies), as well as the

Damping of the vibration system is determined.

To 2) natural frequency

A natural frequency of a plant product of a vibratory system is one of the frequencies with which the substance of the plant cells can vibrate after a single excitation. If the substance of the plant cells from outside vibrations are forced, the frequency of which coincides with one of the natural frequencies, the substance reacts with a particularly large amplitude, which is called resonance. The amplitude of the forced vibration assumes a maximum in the case of resonance. As the damping value increases, the resonance point shifts and the resonance amplitude decreases.

If the condition of the cell wall or the cell membrane changes, the resonance and thus the vibration frequency of the probe changes.

The change in the plant cell, or the change in the physical property of the substances in the plant cell, are determined by the measuring method described below according to the invention. All different physical measuring methods have in common that they measure the change in state of the substances over the ripening period or in the post-harvest storage in the vegetable products, convert the determined measured variables, compare with stored data, make a score and display them via display means. A physical measuring method is based on the fact that for starting the measuring process, to determine the state of the substance in the vegetable product, the device on the

Surface of the vegetable product (hereinafter referred to as subject) is placed. By placing the device or by the simple operation of a control element, a fully automatic measurement program is started and set a vibration exciter in motion, which abuts against the surface of the subject and generates a wave by its kinetic energy. The kinetic energy of

Vibration activator is converted when hitting the surface of the vegetable product in a pressure wave, which undergoes this due to the substance in the body as a damped vibration. The damped oscillation, or the decrease of the amplitude, is determined by the amount of attenuation. For example, the amount of attenuation depends on the amount and type of fluid in the vegetable product.

The generated wave is a pressure wave which propagates through the substance of the subject and is reflected on the inner rear wall of the subject's ¹ bowl, returns to the vibration exciter and causes it to vibrate. The vibration exciter now acts as a sensor and takes the physical quantity of the plant products from the measured variable, the sensor is a permanent magnet rod, the measured variable is converted by a transmitter into an electrical signal. On the way there and back the pressure wave passes through the plant, provided with aqueous solution memory. Depending on the state of the plant cells of the substance, the pressure wave is damped differently. In "unripe" fruits, the attenuation of the wave is relatively low, while it is relatively high in "overripe" fruits. As the ripening time increases, so do the plant cells of the plant products and the damping factor increases. The value of the damping is taken from the movement of the sensor over a certain period of time stored in the measuring program. The movement of the sensor generates an electromagnetic induction or induction voltage in a device. The device is explained in more detail in the description of the figures. The induction voltages determined here yield inductive voltage values which are a measure of the state of the substance or of the degree of ripeness of the plant cell of the test person. From the analog induction voltages in the form of a sine wave, digital signals are formed by a Schmitt trigger type. At the exit of the Schmitt triggers is then a flawless converted TTL signal for further evaluation available The supplied signals are fed to a process computer and evaluated the pulse width and pulse pause ratios in the square wave signal.

The pulse width and pulse pause ratios give an indication of the attenuation behavior of the plant cells of the substance in the plant products. In the case of "unripe" plant products, a characteristic square-wave signal with a relatively small pulse width ratio and, in the case of "overripe" plant products, analogously a relatively large pulse width ratio is produced. To determine the fruit size, the pulse pause ratio can also be used for the evaluation. From the many digital values (signals) obtained by the measurement, an index is determined by means of a computer, i. the digital signals are evaluated and the code determined by the processor, which results from a specific pattern of a square wave, is compared with the characteristic numbers stored in a table and assigned if they match. The key figures in the table correspond to certain plant products. For example, the table contains the characteristic figures of the ripeness of fruit and vegetable fruits. The fruits include, for example, apples, peaches, grapes, pears, dates, plums and tangerines, while the vegetables include tomatoes, all varieties of melons and cucurbits. The levels of ripeness used to classify plant products according to their quality are defined by the key figures stored in the table. If the key figure determined from the measurement agrees with a key figure assigned from the table, that is, if the key figures match, an order result is fixed which corresponds to a maturity level. The maturity level indicates a certain stage of maturity. There is a valuation and weighting of the vegetable products whose key figure is stored as a value in a table. That The quality assessment of the vegetable products is carried out by measuring the change in the

Value of a physical property. The value is obtained indirectly by measuring one or more variables of the same or different kind by multiplying the variables whose value the desired variable is related to. Here e.g. measuring maturity changes by measuring a resulting amplitude of a frequency.

The classification result corresponds to a specific herbal product and its degree of maturity. The value or maturity level is displayed by displaying numeric / alphanumeric digits, analogue or digital displays or reading a scale based on the combined result from the measurement. A representation of the degree of ripeness, or of the determined degree of ripeness, can also be effected without the use of numbers, for example by acoustic signals and / or optical signals such as LED's There is no indication of the absolute value, but only the display of a degree of maturity in accordance with FIG a given quantity whose value may be known or determined by empirical determination.

In order to be able to sort vegetable products, such as fruit and vegetable fruits of various shapes and types, with one and the same method and device for quality assessment according to maturity level, the device qualifies software-controlled vegetable products on the basis of the key figures stored in the table. A simple embodiment of the device has, for example, on the front surface of the device controls with which the fruit or vegetable fruit varieties whose degree of ripeness is to be determined, can be adjusted.

With the method and the device, it is thus possible to determine the degree of ripeness of various vegetable products non-destructively within a short time without expensive analyzes.

Another inventive physical measuring method for determining the health of vegetable products based on the fact that works instead of the electromechanical measurement method which by excitation of the surface of the vegetable products and generation of a damped resonance vibration in the body of the vegetable products, as well as its conversion of the measured variables from the resonator , a capacitive measuring method is used. The capacitive measuring method is also a nondestructive method for determining the ripeness of the vegetable products, the capacitive measuring method consisting of a method and a device. The capacitive measuring method is based on measuring and evaluating the physical properties of the vegetable products.

In a first method of the capacitive method according to the invention, the physical properties of the aqueous solution in the vegetable products are used. The aqueous solution in the vegetable products is about 90% and is contrary to the amorphous tap water a crystalline (anisotropic) liquid. Anisotropic refers to the directional dependence of physical properties. The properties consist of either approximately rod-shaped or scheibchenfb'rmigen molecules which are flowable. The anisotropic liquids have the characteristics of a crystal. Liquid crystals are thus substances that, although liquid, but on the other hand, similar to crystals, have directional physical properties. Therefore, the aqueous solutions in the vegetable products are also referred to as liquid crystals. The liquid crystals have a multiplicity of disordered permant dipoles.

Furthermore, the herbal products are considered as insulators to which a dimensionless dielectric constant is assigned. Based on the dimensionless dielectric constant, the system behavior, ie the state of maturity of the vegetable products can be determined by comparison. Each plant product has its own specific permittivity, which changes over the course of its storage life.

Thus, the longer the vegetable products are stored, the higher the dielectric constant of the crystalline aqueous solution becomes. These physical properties of the vegetable products are used in the capacitive measurement method, i. used in the measurement or quantitative determination of the value of the ripeness of herbal products.

The device includes an integrated air capacitor, the metal plates are spaced. A capacitor is an electrical device for storing electrical charge. The capacitor used consists of two conductive, spaced-apart surfaces. As insulator, a vegetable product, which is a dielectric, is applied to the plates. In an insulator, or the plant products, the charge carriers are not freely movable, but they are only polarized by the application of an external electric field. There are two types of polarization:

a) shift polarization, i. electric dipoles are induced in the electrical solution and are formed by charge transfer

b) orientation polarization, i. the disordered permanent dipoles already contained in the aqueous solution are aligned. Permante Dipole be through the

Characterized by dipole moment. By this is meant the product of charge and distance between the charge centers. In general, the more polar the bonds are, the greater the dipole moment. The high dipole moment of the aqueous solution shows the strong dipole nature of the H-2-O molecules. The determination of dipole moments (from the behavior of the aqueous solution of vegetable products in the electric field, i.e. by

Measurement of the dielectric constants) gives valuable information on the structures and Properties of the molecules and thus one obtains conclusion on the degree of maturity of the vegetable products. It is known from experience that the electrically insulating bodies, the so-called dielectrics, are placed in the electric field and thereby polarized. This means that a rearrangement of the dipoles takes place in the dielectric and these dipoles adjust in the directions of the lines of force and it is known that the electrical molecular dipole moment and the dielectric constant are mutually connected. This means that in order to clarify the overall condition of the pulp, one has to grasp the relative permittivity of the vegetable products.

The physical measuring method is based on the fact that at the start of the measuring process, to determine the relative permittivity or the degree of ripeness in plant products, the vegetable product is passed between the air condensers of the device, whereby a fully automatic measurement program is started. Alternatively, the measurement program can also be started by pressing a control element. Among other things, the fully automatic measuring program also contains the key figures of plant products stored in a table. The electrical quantity needed to determine the dielectric constant is taken from the electric field between the plates. For example, the more energy that can be stored in the electric field between the plates, the higher the dielectric constant. In the case of an overripe fruit, the relative permittivity or degree of ripeness is highest. "If the energy in the field decreases, however, the relative permittivity is lower and thus the degree of ripeness, ie the dielectric constant is lowest for" unripe "fruits the vegetable products are stored after harvest, the higher the dielectric constant of the crystalline liquid.

The conversion of the measured variable, the calculation and the comparison with deposited dielectric numbers, as well as the evaluation correspond approximately to the electromechanical method as described above. That With this capacitive measuring method it is also concluded with the help of a special software conclusion on the quality and the degree of maturity of the vegetable products inside the respective sample.

In a second method of the capacitive measuring method according to the invention, the capacitive device is also suitable, by utilizing the dielectric constant, or the change in the dielectric constant of the vegetable products to determine the degree of ripeness by measuring, taking advantage of the capacitive change of the capacitor. In this case, the capacitor plates are arranged at a distance from the inside of the housing wall of the device. The housing of the device consists of an insulating material housing, to which a certain dielectric constant can be assigned. If the device is placed on the vegetable product, the capacitance of the capacitor increases considerably due to the additional dielectric of the vegetable product, although green fruit and vegetable crops are 5 ("immature") poor electrical conductors. Fruits and vegetables are also ionic conductors, ie the electrical conductivity of aqueous solutions (electrolytes) increases on the one hand with the decrease in the functionality of the cells, whereby on the other hand, the aqueous solution outside the cells grows over the storage period. This change in the state of the substance causes a change in the capacitance of the capacitor, which in turn is a measure of the state of the substance in the subjects. In this capacitive method, the shape change of the aqueous solution is preferably determined. In immature fruits and vegetables, the aqueous solution is still bound in the cells, during the storage time, the cell walls or cell membranes disintegrate and the aqueous solution forms a liquid that accumulates due to gravity in the lower part of fruit and vegetables i ₅ . The measured variable of the capacity change is procedurally converted, evaluated and displayed. This means that with the help of a special software conclusions can be drawn about the quality (quality) or the degree of ripeness of the vegetable product inside the respective subject with this capacitive measuring method.

Compared to pure water, the aqueous solutions present in vegetable products contain substances such as e.g. Salts and sugars that affect and change the course of quality over time. In order to actually obtain fresh fruits and vegetables on the market, the user can be given based on the invention, a measuring device, which determines the quality of freshness.

2 ₅

Two embodiments of the invention are shown purely schematically in the drawings and will be described in more detail below. It shows

Figure 1 is a perspective view of a complete device with

Additional functions, Figure 2 is a schematic representation of the measuring method based on a block diagram according to the electromechanical method and

Figure 3 is a schematic representation of the measuring method based on a block diagram according to the capacitive method.

FIG. 1 shows an exemplary embodiment of a device according to the invention for determining the state of health of vegetable products, in particular foods, such as fruit and vegetable fruits, by detecting, evaluating and displaying the state of the vegetable products in a perspective view.

The device 1 essentially comprises an insulating housing 2, which is designed in two parts and consists of a housing part 3 and a housing cover 4, whereby the housing part 3 is closed, there; the insulating material housing 2 being shielded against electromagnetic radiation, ie towards the interior, inwardly; wherein the insulating housing 2 openings 5 for receiving control 6 and display elements 7, and for receiving external means 8, which may for example consist of a coin or a plastic disc and in the case of the electromechanical measuring device with an opening for the device 9, consisting of a vibration exciter 10 and measuring sensor 11 (see Figure 2) contains. The openings 5 for the control 6 and display elements are advantageously located on the front surface 12, and partially on the narrow longitudinal sides 13,13 'and the narrow top 14, wherein the opening for the device 9 on the narrow bottom 14 ^Λ is. The reverse side 15 is reserved for the marking of the product according to its technical mark of conformity, such as "CE", "GS", etc., stating that the product complies with EU directives, where "GS" corresponds to the safety mark of the product Equipment and Production Safety Act complies. Furthermore, the back can serve as an information surface for operating and reading the device, as well as an advertising space for information on the various fruit and vegetable fruits, the user. Marketing information can also be included there.

Furthermore, the device 1 for starting the measurement process on the top 14 includes a mechanical control element 6, preferably as a button which closes by pressing the electrical circuit, and usually when released back into the Swings back home position and breaks the circuit or a switch for opening or closing the electrical connection, which separates or connects the on the component 16 (see Figure 2) arranged electrical / electronic components of the power source 17. Another operating element 6 on the upper side 14 of the device 1 can be provided for adjusting the various vegetable products. In the front surface 12 are the display elements 7 for the quality levels of ripeness, in Figure 1 in the form of a quality scale, the left indicator 36 corresponds to the "immature" pulp and the right display value 37 that of "overripe" pulp The reverse side arrangement, in which the operating elements 6 are arranged in the front surface 12 and the display elements 7 on the narrow upper side 14, is likewise possible The device 1 according to the invention for acquiring and displaying qualified measured values may contain further useful components for the user in further construction designs .The components consist of a voice recording module 38, a pocket calculator 39, a bar code reader 40, and a transmitter / receiver 41. for the voice recording module 38, are located at de r left narrow side 13 and consist of a Microspeaker 42, a recording 43 and StarWStop button 44 and are suitable for receiving the shopping list as electronic shopping list. The function keys 45 of the calculator 39 are arranged in the front surface 12 of the device 1. The window 46 for the bar code reader 40 is located on the narrow right narrow side 13. The bar code reader 40 serves for the detection and evaluation of bar codes which are mounted on products and displays the determined value in a display 47. The display 47 has multifunctional tasks in that the display 47 can be used to display the calculator results, the level of maturity levels, and the barcode reader 40 readings. The operating elements 6 of the transmitter / receiver 41 are likewise integrated in the narrow upper side 14, wherein the operating elements 6 can also be arranged in the other narrow sides 13, 13 '. With the Sender-ZEmpfängerfunktion general information, for example on daily offers, can be obtained or queried. It is also possible to receive special information on products, on the one hand according to the respective spatial position of the device in the sales room or via the reading of a bar code of the information about the scanned product. The desired information is displayed to the user of the device 1 directly or indirectly on a display 47 or communicated acoustically by an integrated loudspeaker 48. At the lower narrow side 14 ^Λ is the area in which the sensors are arranged and reserved for the measuring method.

2 shows the basic representation of the device 1 of the electromechanical method according to the invention, which is illustrated by a block diagram 28. The block diagram 28 shows that the electrical / electronic components 16 are arranged on a printed circuit board 32, wherein the electrical / electronic components consist of a device 9, a trigger 23, a processor 25, which are connected to a power source 17. The device 9 serves to excite and detect the measured variable of vegetable products and consists of a vibration exciter 10, a sensor 11 and a double coil 18. The one double coil 18, consists of two round coils, wherein a coil 1 19 for the movement of the vibration exciter 10 and the second coil II 20 is responsible for the sensor 11. In order to increase the measuring voltage of the measuring sensor 11, the coils I and II work together during the measurement, ie the coil I has a double function. The device 9 uses the physical principle of electromagnetic induction. The coil 1 19 supplies the vibration exciter 10, which is preferably in the form of a plunger, which is designed as a permanent magnetic rod and at its outer end with a blunt cone 21 or hemisphere, preferably made of rubber or plastic hard rubber, with kinetic energy. The kinetic energy is needed to vibrate the surface of the vegetable product. The plunger, which is perpendicular to the surface of the vegetable product, takes over after switching on the coil II 20, the function of the sensor 11, wherein the vibration exciter 10 and the sensor 11 represent the same object. The sensor 11 induces voltages in the coils 19 and 20 by measuring the oscillations of the excited body of the subject (not shown), appearing as a damped sine wave 22 at the output of the series coils 1 19 and II 20. The output signal 22 of the device 9 is fed to a trigger 23. The trigger 23 generates from the sine wave 22 a square wave signal 24, which is supplied to the processor 25 for evaluation, which contains a software program and a table in the memory area. The table contains the key figures of the maturity levels of the herbal products. The processor 24 calculates from the square-wave signal 24 a code 26, which is compared with the codes 27, which are stored in a table 28. If the characteristic number 26 ascertained from the measurement coincides with a stored characteristic number 27 which is stored in a table 28 in a non-volatile memory 29, a classification result is established. The classification result corresponds to a value of 30 of a certain herbal product and a certain degree of maturity. The value 30 of the maturity level is displayed on the display element 7.

3 shows the basic representation of the device 1 according to the second method of the capacitive method according to the invention, which is illustrated by a block diagram 28. The block diagram 28 shows that the electrical / electronic components 16 are arranged on a printed circuit board 32. The electrical / electronic components consist of the device 9, which contains an air capacitor as a capacitive sensor, which consists of two times two multi-layer disk capacitors 33 and their RC element, which determines the time constant of the oscillator 34 consists. Analogously, this results in a frequency which is supplied to the processor 25. Due to the fact that two measurements are made by the oscillator 34 on the subject, offset by 180 degrees, two frequencies go to the processor 25 for evaluation.

The oscillator 34 thus generates from two measurements two frequencies (rectangular signals) 35, which are supplied to the processor for frequency evaluation. The processor 25 then calculates the frequency ratio from both frequencies and determines therefrom a characteristic number, or the processor 25 calculates from the rectangular signal 35 a characteristic number 26 which is compared with the characteristic numbers 27 which are stored in a table 28. If the characteristic number 26 determined from the measurement coincides with a characteristic number 27 stored from the table 28, which code is stored in a non-volatile memory 29 of the processor 25, an arrangement result is established. The classification result corresponds to a value of 30 for a given herbal product and for a given degree of maturity. The value 30 of the maturity level is displayed on the display element 7.

LIST OF REFERENCE NUMBERS

1 device 26 code

2 insulating housing 27 Key figures

3 Housing part 28 Table

4 housing cover 29 memory

5 openings 30 value

6 Operating elements 31 Block diagram

7 display elements 32 PCB

8 Medium 33 film capacitor

9 Device 34 Oscillator

10 vibration exciter 35 signal

11 Sensor 36 Left display value

12 front surface 37 right display value

13, 13 Longitudinal side 38 Voice recording module

14,, 14 top / bottom 39 pocket calculator

15 back 40 barcode reader

16 component ^; 41 transmitter / receiver

17 energy source 42 Microspeaker

18 double reel 43 Record button

19 Coil I 44 StarWStop button

20 bobbin II 45 function keys

21 cones 46 windows

22 Output signal (sine) 47 Display

23 triggers 48 speakers

24 output signal (rectangle) 49

25 processor 50

Claims

 claims

1. A method for determining the health of vegetable products, in particular food, such as fruit and vegetable fruits, by detecting, evaluating and displaying

5 of the state of the substance of the vegetable products, characterized in that the

Examination of the condition of the substance by a non-destructive process takes place.

2. The method according to claim I ₅ characterized in that the method is a physical measuring method.

3. The method according to claim 1 to 2, characterized in that the physical measuring method 10 is formed from an electromechanical method.

4. The method according to claim 1 to 2, characterized in that the physical measuring method is formed from a capacitive method.

5. The method according to claim 1 to 4, characterized in that the physical measuring method by simply placing the device (1) on the surface of the

I ₅ subjects or after touchdown using a simple control element (6) is started.

6. The method according to any one of the preceding claims, characterized in that a vibration exciter (19) abuts against the surface of the subject and generates a wave.

A method according to claim 6, characterized in that the wave is a pressure wave, which propagates through the substance of the subject and the sensor (11) in

Oscillation.

8. The method according to claim 6 to 7, characterized in that the movements of the Meßaufhehmers (11) generate induction voltages in the device (9).

9. The method according to claim 6 to 8, characterized in that from the 5 induction voltages (22) digital signals (24) are formed.

10. The method according to claim 6 to 9, characterized in that from the digital signals (24) a code (26) is determined.

11. The method according to claim 6 to 10, characterized in that the determined characteristic number (26) with those in a table (28) deposited key figures (27) is compared and assigned in accordance.

12. The method according to claim 6 to 11, characterized in that in agreement of the 5 ratios (26,27) is a classification result, which represents a maturity level (30) is fixed.

13. The method according to claim 6 to 11, characterized in that the maturity level, or its value (30), is displayed.

14. A device (1) for detecting the health of vegetable products, in particular 10 foods, such as fruit and vegetable fruits, by detecting, evaluating and displaying the state of the substance of the vegetable products, characterized in that the device comprises (1)

a) an insulating material housing (2) with openings (5) for receiving control (6) and display elements (7);

I ₅ b) operating elements (6) for starting the measuring process and adjusting the vegetable products;

c) display elements (7) for displaying the values (30) of the ripeness of the vegetable products;

d) electrical / electronic components which are arranged on a printed circuit board (32), 0 wherein the electrical / electronic components of a device (9), a

Trigger (23), a processor (25) connected to a power source (17);

15. Device (1) according to claim 14, characterized in that the means (9) of plant for exciting and detecting the measured variable products used consisting of a ₅ vibration exciter (10), a Messaufhehmer (11) and a double coil (18), the

Vibration exciter (10) and the Messehhehmer (11) represent the same object.

16. Device (1) according to claim 14 to 15, characterized in that the processor includes a software program and a table (28) which are stored in the memory area.

17. Device (1) according to claim 14 to 16, characterized in that the table (28) contains the indices (27) of the maturity levels of the vegetable products.

18. Device (1) according to any one of the preceding claims, characterized in that the device (1) comprises an opening (5) for receiving means (8).

19. Device (1) according to claim 18, characterized in that the means (8) are formed from a coin or plastic disc

20. A device (1) for detecting the health of vegetable products, in particular food, such as fruit and vegetable fruits, by detecting, evaluating and displaying the state of the substance of the vegetable products, characterized in that the device (1) comprises additional components,

a) a voice recording module (38) having a microspeaker (42), a record (43) and start / stop button (44);

b) a calculator (39) with function keys (45);

c) a bar code reader (40);

d) a transmitter / receiver (41);

e) a display (47) for displaying the calculator results, the determined values of the bar code reader (40), the determined values of the maturity level and from the query of the transmitter / receiver function;