WO2018134084A1 - Connected device for composting - Google Patents

Abstract

The invention relates to a device (2) for composting, comprising: a stick (3) for planting in a pile (1) of organic matter; a plurality of sensors (9, 10) arranged on the stick (3) for measuring parameters relating to the organic matter; a power supply (13) for the sensors (9, 10); and a processing unit (11, 16) connected to the sensors (9, 10) for the collection of measuring data and the outward transmission of same.

Description

 "Connected device for composting."

The present invention relates to a tool for assisting composting. It is particularly applicable to a composter for domestic use to treat organic waste. However, the invention is of a broader scope because it can be applied to any type of home or professional composting where one seeks to perform effective composting and quality.

 Compost includes organic matter that has broken down in weeks and months by turning it into humus.

 Composting is an aerobic biological process that transforms organic matter into compost. Under the effect of water and oxygen, a fermentation of the organic matter takes place and after maturation, the compost is obtained. The latter is rich in humus and can be used as a breeding ground. This is a recovery operation including organic waste (bio waste, green waste).

 Many people and communities are becoming increasingly aware of the need to protect the environment by, for example, limiting the huge amount of waste. For example, in France, on average, each inhabitant produces 295Kg of organic waste, or about 25% of total waste. This represents a significant management cost.

 The need to compost is therefore real because it saves money and protects the environment.

State of the art

 In practice, a composting can be done autonomously in heaps or in a tray in the garden, or in a professional community or not.

 Many homes have a composter placed in the garden with more or less sustained management.

The success of compost requires the presence of carbon waste or dry waste and nitrogenous waste or wet waste. It is important to balance carbon waste with nitrogenous waste and to mix it regularly for quality compost. Carbon chains are used by organisms as a source of energy and produce CO2 gas and heat.

 Several phases at different temperatures follow each other in the composting process. The composting begins with a degradation, followed by a ripening phase before the creation of a compost rich in humus. It is possible to follow the evolution of a composting by monitoring the temperature. However, monitoring the temperature does not make it possible to produce quality compost. Quality composting is essential to obtain quality compost and maintain the user's interest in the composting process.

 The present invention relates to the production of a quality compost.

 The present invention also relates to regular monitoring to quickly lead to a compost.

Presentation of the invention

 At least one of the above-mentioned objectives is achieved with a device for composting, comprising:

 - a stick intended to be planted in a pile of organic matter,

several sensors arranged on the stick for measuring parameters relating to the organic matter,

 a sensor supply,

 a processing unit connected to the sensors for collecting the measurement data and transmitting it to the outside.

 The device according to the invention comprises an accelerometer for measuring the movement of the stick. This accelerometer can be arranged in the stick.

The device according to the invention is intended to be permanently implanted in a compost. The invention is particularly remarkable by the fact that by detecting the movements of the stick, it is possible to know if the user to mix, manipulated or simply acts on his compost. We can thus classify the users from the most active to the least active. The presence of an accelerometer to measure the movement of the stick can detect the intervention of the user and the way he intervened. This helps to keep track of the user's activity. It is thus possible to know if the user mixes well his compost, in what way and at what frequency. Alerts can be sent for the least active.

 With the device according to the invention, a stick is used which makes it possible to probe the heap of organic matter in real time, continuously, or periodically. The measurement data are then collected and transmitted especially to the outside for information, analysis or treatment.

 The stick according to the invention may be a stick used to mix the heap of organic material.

 The sensors are arranged on the stick so as to be in contact with the organic material. To do this, the sensors are distributed over a portion of the stick intended to be in regular contact with the organic material.

 The device according to the present invention makes it possible to design a connected composter. In contrast to existing connected container systems, the invention is for example to place sensors on a stick, which may be a tool for mixing the organic material, rather than directly on the composter. Moreover, it should be noted that it is possible to compost in piles without necessarily using a container.

 Such an arrangement of the sensors on the stick makes maintenance more efficient. Indeed, the stick being a removable tool, the repair, cleaning or replacement of the sensors can be done easily, out of the container, in a workshop for example. The stick as a whole can be easily dispatched in transport for a repair in a remote dedicated service. It can also be easily replaced without disturbing the work in composter.

By nature, the stick is intended to be implanted in the heap of organic matter, so it is at the heart of the composter and therefore able to account for the true state of biological transformation within the heap of organic matter. This stick can probe the pile of organic matter in different parts of the composter so as to have a two-dimensional representation if it is not three-dimensional of the state of the organic matter, and thus to account for the quality and the evolution of the compost constituted or in the course of constitution.

 Note that the stick can be telescopic or not, in one piece or in the form of a kit to assemble.

 According to an advantageous characteristic of the invention, the stick may comprise a wireless communication module connected to the processing unit for transmitting measurement data to the outside. The stick becomes a connected object. It can be a module integrated or not to the processing unit and implementing one of the following technologies: Wifi, NFC, RFID, RF, Bluetooth or Bluetooth LE, Zigbee, ...

 Wifi includes several wireless communication protocols. The transmission frequency varies for example between 2.4 GHz and 5 GHz.

 NFC (Near Field Communication) is a near-field communication technology that can transfer data over a distance of a few centimeters.

 RF is any radio frequency technology using radio waves with spectrum ranging from 3kHz to 300GHz.

 The ZigBee is a high-level protocol for low-power, low-power radio communication.

 There may also be other applicable technologies such as LoRa, Sigfox, Qowisio, ANT +, Z-Wave ...

 According to an advantageous characteristic of the invention, the device comprises a removable electronic module capable of communicating and exchanging measurement data with a processing unit disposed in the stick and / or directly with at least one of the sensors.

 With the device according to the invention, there is a removable electronic module capable of making the connection between the stick and for example a computer of the user.

This removable electronic module can collect data from the stick, store for later use in a user's computer for example. But it can also transmit data to the processing unit or to sensors capable of communicate with him for updates of certain applications or for some sensors to be reset.

 Advantageously, the electronic module can communicate directly with at least one of the sensors when the latter is capable in particular using one of the wireless communication technologies mentioned above.

 The removable electronic module can communicate with the processing unit disposed in the stick, preferably wirelessly. This communication can also be done by means of metal connectors for connecting the two components.

 Depending on the technology used, the communication between the stick and the electronic module can be done nearby, a few centimeters or less, at greater distances, a few meters.

 The electronic module can be used permanently attached to the baton and detached from time to time to connect to a computer of the user.

 Preferably, the stick may comprise a platform adapted to receive in a stable position the removable electronic module.

 This platform allows to install the electronic module, but it can also be used to put a mobile phone if the latter is equipped with means for communicating with the processing unit or with the sensors. The platform can be an integral part of the stick or a removable part.

 According to an advantageous embodiment of the invention, the electronic module may be in the form of a disk to be placed on the platform, the latter being located on the upper end of the stick. Other forms may be envisaged, for example linear, cubic or other.

 In addition to the above, the removable electronic module may include a fastening system adapted to engage with a guide disposed on the platform.

The attachment system may for example be an opening cooperating with a stud disposed on the platform. The guide can be a stud, a rail, a hook, a hollow, textile curls, etc. According to an advantageous characteristic of the invention, the device may comprise a processing unit in the stick and / or a processing unit in the electronic module.

 Indeed, the stick may comprise the intelligence, that is to say a processing unit for receiving the data from the sensors, store them, interpret them and transmit them to the outside or to the electronic module . In this case, the electronic module may or may not include a processing unit that can also receive the data, process them and store them.

 However, we may want to lighten the stick, in this case no processing unit is arranged in the stick; the sensors are then able to communicate directly with the electronic module which integrates a processing unit. Otherwise, one can have in the stick a processing unit only able to store and transmit the data without being able to process them.

 By way of nonlimiting example, the electronic module may comprise display means for displaying said measurement data or an interpretation of these measurement data. When the data or their interpretation goes back into the electronic module, the latter can display them in the form of pictograms, texts, images, diode lighting or others. One can also consider sound indications to warn the user.

 Furthermore, the stick may comprise a display module visible from outside the stick and connected to the processing unit for displaying said measurement data or an interpretation of these measurement data.

 One can have a display on the electronic module and / or a display on the stick.

 The data or their interpretations can be indications on the state of the organic matter and possibly on recommendations to follow to improve the composition of this organic matter so as to obtain a compost of quality.

Advantageously, the device according to the invention may comprise a USB connector connected to the processing unit. This connector can be on the stick or on the electronic module and can be used for example for charging and data exchange. According to an advantageous characteristic of the invention, the sensors comprise at least one so-called ripening sensor to measure at least one of the following parameters:

 - temperature,

 - acidity by pH measurement,

 - humidity,

 - oxygen,

 - carbon,

 - nitrogen,

 - ammonia,

 - methane, and

 - movement.

 These parameters are directly detected by the sensor itself as the temperature, but they can also be derived from measurements from one or more sensors.

 For the movement, it is possible to use an accelerometer arranged for example in the electronic module. This sensor makes it possible to detect whether the stick has been moved or not, and thus to detect whether the heap of organic matter has been handled or not.

 According to the present invention, it has been found that the use of carefully selected parameters makes it possible to have sufficient indications of the quality of a compost constituted or in the process of being formed.

 Advantageously, the device according to the invention comprises sensors for at least the following five parameters:

 - temperature,

 - humidity,

 - the pH,

 - oxygen and

 - ammonia.

These five parameters thus make it possible to propose the actions to be carried out for the realization of a compost of quality. The combination of these five parameters makes it possible to obtain actions to be carried out: for example, ammonia makes it possible to deduce the addition or not of dry or wet matter; temperature, humidity and oxygen allow to set up a brewing alone or with watering ... These parameters interact with each other so as to allow to deduce a set of actions, identified as necessary to achieve a very efficient composting. It is also possible to measure carbon, for example by measuring carbon dioxide.

 In some cases of using compost, such as for shared composting or industrial composting, it may be interesting to carry out an analysis of agronomic values and efficiencies.

 According to an advantageous characteristic of the invention, the sensors comprise agronomic sensors for measuring the agronomic quality of a compost.

 The proportions of the different materials incorporated in the organic matter must make it possible to maintain an aerobic environment for composting. Thus, a balance is to be found between dry materials and structuring and wet materials tending to settle.

 In the case of sale or disposal of compost, some states require that the compost meets certain standards, hence the need for analysis. The device according to the invention allows such an analysis efficiently. Some standards set thresholds for agronomic values and efficiencies, inorganic impurities, chemical micropollutants and pathogens.

 Advantageously, the agronomic sensors according to the invention comprise at least one agronomic sensor for measuring at least one of the following parameters:

 - pH, the carbon to nitrogen ratio (C / N), calcium (Ca).

 These parameters are directly detected by the sensor itself as the temperature, but they can also be derived from measurements from one or more sensors.

 The device according to the invention can advantageously be considered as a tool that could be described as a "compost meter" ("compost meter" in English).

Description of Figures and Embodiments

Other characteristics and advantages of the invention will appear on reading the detailed description of implementations and modes of in no way limiting, with reference to appended figures in which:

 Figure 1 is a schematic view of a device, composting tool, according to the invention implanted in a heap of organic material;

 FIG. 2 is a diagrammatic view of a composter in the form of a container in which the tooling according to the invention is implanted;

 Figure 3 is a schematic view illustrating electronic components integrated in the tool according to the invention;

 Figure 4 is a perspective view of the disk-shaped electronic module;

 Figure 5 is an exploded schematic view illustrating various elements to be assembled according to the invention; and

 Figure 6 is a schematic view illustrating the grip of a device according to the invention.

Description of an exemplary embodiment

The embodiments which will be described hereinafter are in no way limiting; it will be possible in particular to implement variants of the invention comprising only a selection of characteristics described hereinafter isolated from the other characteristics described, if this selection of characteristics is sufficient to confer a technical advantage or to differentiate the invention compared in the state of the prior art. This selection comprises at least one feature preferably functional without structural details, or with only a part of the structural details if this part alone is sufficient to confer a technical advantage or to differentiate the invention from the state of the prior art.

 In particular, all the variants and all the embodiments described are intended to be combined with each other in any combination where there is no technical objection to it.

 In the figures, the elements common to several figures retain the same reference.

In Figure 1 there is a pile of organic material 1 consisting of peelings, leaves, coffee grounds, tea bags, crushed eggshell, grass cuts, wood chips ... and deposited on the ground. The device according to the invention is a generally designated tool 2 and comprises a stick 3 implanted in the pile of organic materials and a disk 4 disposed on the upper end of the stick 3. The stick ends in a point in its lower end so as to be implanted easily in the heap or also in the ground. Disc 4 is on an upper part of the stick which is preferably out of the heap of organic material.

 In Figure 2, the tool 2 is also inserted into a heap of organic material disposed in this case in a composter 5. The tool of the invention can be used in a current composter. As will be seen later, sensors are arranged on or in the tool and their role is to track the composter. The tool according to the invention is an object connected in the sense that it integrates components allowing it to communicate for example with a remote server.

 The tool according to the invention is a motivating element for the user. It must allow him to simply compost and efficiently.

 The properties of the compost vary depending on the decomposition process. This evolution is measurable via physicochemical parameters. A feedback of information via sensors, ensures the quality of its compost.

 The parameters to be measured may include:

 Temperature

 The temperature of a compost can change to 60-80 ° C (for home composting). It is due to a strong bacterial activity. This rise in temperature is important because it has a sanitizing effect on compost. Such temperatures are achieved only if a certain volume of materials is formed at one time, with a good humidity. It is also necessary that the ventilation is sufficient.

 Acidity (pH)

 Compost usually goes through an acid phase because of microbial activity. This phase may be longer or shorter depending on the basic parameters of the compost (composition, humidity) and the atmospheric conditions. Under optimal conditions, an acid compost is a compost too young that has not yet reached maturity.

Lacunary oxygen level: The presence of oxygen is essential for the proper conduct of composting. It is in fact consumed on the one hand by the microorganisms during their breathing and on the other hand by oxidation reactions that consume oxygen. The decomposition of the organic matter thus leads to a release of carbon dioxide, the increase of which correlates with a decrease in the oxygen content. It is therefore necessary to provide, in the material to be composted, oxygen by aeration to maintain a sufficient oxygen level.

 Moisture:

 The water contained in the composted organic matter is necessary for the life of the micro-organisms. It also plays a major role in the transport of particles, thus ensuring better contact between organic fractions and microbial flora. The C / N ratio:

 It's the ratio of carbon to nitrogen. It is accepted that this ratio is between 15 and 30 to allow optimal composting. A lack of nitrogen will not allow good degradation, and too high a nitrogen level can lead to the elimination of microorganisms.

 The device according to the invention also makes it possible to ensure the effective use of the composter over time and to analyze in situ the agronomic quality of the compost in a perspective of NFU44051 standardization to be eventually compatible with organic farming.

 To do this, in addition to the parameters mentioned above, other parameters can be measured, such as: P, K, Mg, Ca, Na, S, organic nitrogen and ammonia.

 In FIG. 3, there are two constituent elements of the tool 2, the stick 3 and the disc 4.

 The lower part of the stick 3 is intended to fit into the pile of organic materials. On this lower part are arranged several sensors for measuring the above parameters.

The stick 3 comprises a main body 6 ending in a tip 7 at its lower end and a platform 8 at its upper end. Sensors 9 and 10 are disposed on the main body 6 which is a trunk. Each sensor, depending on its use is totally or partially disposed on the surface of the trunk 6. Preferably, at least a portion of each sensor is inside the trunk 6 so as to allow a secure attachment and easy passage of connection cables.

 The sensors 10 are, for example so-called ripening sensors because they are on an area where the organic matter will be maturing, that is to say the central or upper central zone of the pile of organic materials.

 The sensors 10 may comprise sensors for measuring, for example, the following parameters: the temperature (t °), the acidity (Ph), the% humidity, the carbon (C) and the nitrogen (N).

The sensors 9 are for example sensors known as agronomic sensors for measuring the agronomic quality of the compost and also the non-phytotoxicity of the compost.

 Agronomic sensors can be used to determine all or some of the following parameters:

 - Dry matter

 - Organic material

 - C / N ratio

 - Total nitrogen

 - Total Calcium

 - pH

 - Kinetics of C and N mineralization

 - Biochemical fractionation of organic matter (biological stability)

 - Alkalizing effect by Incubation

 - Water retention capacity

The sensors 9 and 10 can communicate wired or not with a processing unit 11 disposed inside the stick, in the upper part of the trunk 6. When the communication is wired, an electronic bus can be inserted into the stick for wire the various sensors with the processing unit 11. Some sensors can be wired (connected to the treatment unit by a metal conductor) and others can communicate wiredly with the processing unit using short-haul technology.

 Other sensors may be placed outside the heap of organic material, always on the stick or on the disk. For example an outdoor temperature sensor may be disposed at a higher level of the stick so as not to be in the heap of organic material. An accelerometer can be placed on the disk.

 The processing unit 11 comprises software and hardware means for communicating with the sensors, collecting measurement data and communicating with the outside, in particular by means of a wireless communication module 12. It may be a Wifi module or Bluetooth LE ("Bluetooth Low Energy") or other.

 The communication between the processing unit 11 and all or some of the sensors can be bidirectional. Indeed, for some sensors it may be necessary to perform a reset.

 Each sensor can be powered by an internal battery. But, according to one aspect of the invention, a battery 13 is disposed in the stick 3 to power the processing unit and the set of sensors that need it.

 This battery can be removable to allow its replacement, but it can also be a battery to recharge by unrepresented solar panels.

 A display screen 25 may be provided on an upper part of the stick so as to be visible from the outside. This display screen can display measurement data or an interpretation thereof, in particular from the processing unit 11.

 The upper end of the stick comprises a platform 8, circular in the example shown.

 The disc 4 is a removable electronic module that can land on the platform 8 and engage with a guide 14 present in the center of the platform. This guide is a protuberance designed to conform to a central opening 15 made in the disc 4. Once installed, the disc becomes integral with the stick.

In any case, when the disc is sufficiently close to the stick, a fortiori when it is placed on it, the processing unit 11 in the stick can communicate with a second processing unit 16 arranged in the disk via the wireless communication modules 12 and 17 respectively. The processing unit 16 may comprise storage means for storing data that can be transmitted to it by the first processing unit 11.

 The disc 4 may also be equipped with a battery (not shown), rechargeable or not.

 In the illustrated example, a micro-USB connector 18 is disposed on the disk and allows in particular to recharge the disk battery and transmit updating data for example.

 The function of the disk is to retrieve the measurement data.

The user can then retrieve the drive and transport it to his home and wired it or via the micro-USB connector to a computer to retrieve this data.

 The entire device is intended to be used outdoors in an insulated composter with an autonomy of at least six months while resisting environmental constraints (resistant to weather and induced manipulation).

 In Figure 4 is shown the disc 4 in a perspective view. There is the central opening 15 and an upper face equipped with display elements. These are in the form of pictograms 19-24 which may or may not light depending on instructions transmitted by the second processing unit 16. These instructions depend on the measurement data. The processing unit 16 can therefore interpret the measurement data and generate instructions for activating one or more pictograms. The information is intended for the user and may consist of actions to: water, put back cardboard, deliver sopalin and / or branches or leaves, put back peels, hand over leftovers ..., all in order to achieve quality compost.

 For example, the correspondence of the pictograms in FIG. 4 can be as follows:

 Pictogram del9: LED indicating status on,

Pictogram 20: represents a balloon to indicate the defect or the excess of nitrogen, Pictogram 21: represents a drop of water to indicate the lack or excess of water,

 Pictograph 22: is the button to turn on or off the disc,

Pictogram 23: symbolizes a mixer to indicate that it is necessary to mix the pile,

 Pictogram 24: represents a sheet to indicate the defect or the excess of carbon.

 These pictograms may also be displayed on the display screen 25 disposed on the stick.

 According to the invention, a periodicity of measurement of the data can be defined.

 According to the invention, it is possible to envisage a disk capable of transmitting an email via the wireless network to a computer of the user for each action to be performed.

 In Figure 5 is shown by way of non-limiting example, the device according to the invention in an exploded view. This may correspond to a multi-piece manufacture of the tool 2, and then an assembly by the end user. In particular, in the example of Figure 5, the stick consists of three parts to assemble.

 Figure 6 illustrates the tool according to the invention taken in the hand of a user. This allows to appreciate roughly the dimensions of the tool 2.

 Of course, the invention is not limited to the examples that have just been described and many adjustments can be made to these examples without departing from the scope of the invention.

Claims

claims

A device (2) for composting, comprising:

 a stick (3) intended to be planted in a pile (1) of organic matter,

 several sensors (9, 10) arranged on the stick (3) for measuring parameters relating to the organic matter,

 a supply (13) of the sensors (9, 10),

 a processing unit (11, 16) connected to the sensors (9, 10) for collecting the measurement data and transmitting it to the outside,

 characterized in that it comprises an accelerometer for measuring the movement of the stick.

2. Device according to claim 1, characterized in that the stick (3) comprises a wireless communication module (12) connected to the processing unit (11) for transmitting the measurement data to the outside.

3. Device according to claim 1 or 2, characterized in that it comprises a removable electronic module (4) able to communicate and exchange measurement data with a processing unit (11) disposed in the stick (3) and / or directly with at least one of the sensors (9, 10).

4. Device according to claim 3, characterized in that the stick (3) comprises a platform (8) adapted to receive in a stable position the removable electronic module (4).

5. Device according to claims 3 and 4, characterized in that the electronic module (4) is in the form of a disc to be placed on the platform (8), the latter being located on the upper end of the stick (3). ).

6. Device according to one of claims 3 to 5, characterized in that the removable electronic module (4) comprises a fastening system (15) adapted to engage with a guide (14) disposed on the platform (8). ).

7. Device according to any one of claims 3 to 6, characterized in that it comprises a processing unit (11) in the stick and / or a processing unit (16) in the electronic module.

8. Device according to any one of claims 3 to 7, characterized in that the electronic module (4) comprises display means (19-24) for displaying said measurement data or an interpretation of these measurement data.

9. Device according to any one of claims 3 to 8, characterized in that the accelerometer is disposed in the electronic module (4).

10. Device according to any one of claims 1 to 8, characterized in that the accelerometer is disposed in the stick (3).

11. Device according to any one of the preceding claims, characterized in that it comprises a USB connector (18) connected to the processing unit (16).

12. Device according to any one of the preceding claims, characterized in that the sensors (9, 10) comprise at least one sensor said sensor (10) maturation for measuring at least one of the following parameters:

 - temperature,

 - acidity by pH measurement,

 - humidity,

 - carbon,

 - nitrogen,

 - ammonia,

 - oxygen,

 - methane.

13. Device according to any one of the preceding claims, characterized in that the sensors comprise sensors for at least the following five parameters: - temperature,

 - humidity,

 - the pH,

 - oxygen and

 - ammonia.

14. Device according to any one of the preceding claims, characterized in that the sensors comprise agronomic sensors (9) for measuring the agronomic quality of a compost.

Device according to claim 14, characterized in that the agronomic sensors comprise at least one agronomic sensor for measuring at least one of the following parameters:

 - pH, the carbon to nitrogen ratio (C / N), calcium (Ca).