WO2020165025A1 - Device and method for measuring the surface melting of a glacier - Google Patents

Abstract

The invention relates to the field of glaciology and more particularly to a device (1) for measuring the surface melting of a glacier, comprising: - a measurement module for measuring the surface melting of the glacier; - a remote transmission system; - a support; and - a battery; characterized in that the measurement module comprises a cable (110), a winder capable of winding the cable (110) so as to keep said cable taut, an encoder wheel configured so as to be rotated when the cable is wound by the winder; the winder and the encoder wheel being arranged such that the surface melting of the glacier causes the cable to be wound by the winder and the encoder wheel to rotate correspondingly; the remote transmission system then being capable of transmitting a measured signal proportional to the surface melting of the glacier.

Description

DEVICE AND METHOD FOR MEASURING CAST IRON ON THE SURFACE OF A

GLACIER

TECHNICAL FIELD OF THE INVENTION

The invention relates to the field of glaciology. It finds a particularly advantageous application in measuring the surface melting of a glacier.

STATE OF THE ART

The measurement of the surface melt of a glacier has historically been carried out using beacons comprising a succession of stakes, generally 2 meters long, linked to each other by a chain. Using a steam probe or a drill, holes are drilled in the ice or snow on the surface of a glacier, to a depth roughly equal to the length of the stakes. The marker posts are then inserted into the drilled holes. With this method, the melting of snow and / or ice on the glacier's surface is quantified by manual measurement of the emergence of beacons over time. This measurement is carried out by an operator visiting the field, generally on a monthly basis during the melting period, generally from June to October in the northern hemisphere.

Measurement by beacon is discontinuous over time and requires a trip in the field. Consequently, the surface melting of the glacier is integrated into the time interval between two successive visits, which does not allow to access the variability of melting on a short time scale, for example per hour, per day or per week. In addition, considering a surface melting of the glacier of 10 meters per year in the ablation zone of the glacier, it is necessary to reinstall the beacons several times a year. Thus, in addition to the trips to measure the emergence of the beacons, trips for the reinstallation of the beacons are also to be expected; however, access to beacons for measurement and / or their reinstallation is always difficult and may be made impossible, in particular due to weather conditions, which consequently limits the carrying out of measurements.

Autonomous devices have been developed to obtain a continuous measurement of the surface melting of a glacier. There are in particular devices comprising an ultrasound probe attached to a mast implanted in the ice or the snowpack. The ultrasound probe is thus theoretically maintained in a fixed position and emits an ultrasound signal, part of which is reflected by the surface of the glacier, so that the reflected signal is detected by the probe and provides information on the distance between the probe and the surface from the glacier. When melting occurs, the distance of the probe to the glacier surface increases, making it possible to measure the glacier's surface melt.

Alternatively, a device known from the state of the art comprises an ultrasound source and a detector, one being buried under the surface of the glacier while the other is fixed on the emerged end of a mast planted in ice or snowpack. The ultrasonic signal emitted by the source thus passes through a portion of ice or snow before being collected by the detector. The portion of ice or snow crossed modifies the detected signal, thus making it possible to quantify the accumulation or melting of ice or snow. It is more particularly known, from document JPH07113877, a device comprising an oscillating source coupled to a detector, said device being suitable for measuring the variation in thickness of the snowpack in order to calculate the water equivalent of the available snow.

Autonomous devices according to the characteristics described above have several drawbacks. In particular, when the surface of the glacier melts, the masts on which said devices are attached gradually emerge. As a result of this increasing emergence, their position may vary, for example by a progressive inclination of the mast or may even drop completely. This reduces, on the one hand, the reliability of the measurement and, on the other hand, may require frequent, potentially monthly, reinstallation of the devices. Their autonomy is therefore quite relative. Current devices and methods for measuring the surface melting of a glacier therefore show limits. In particular, none of them allows continuous measurement of the surface melting of a glacier while minimizing the movements of an operator in the field.

In this context, the present invention proposes, according to a first aspect, a device making it possible to overcome at least one of the aforementioned drawbacks.

More particularly, the device according to the first aspect of the invention aims to allow continuous, precise and reliable measurement over a long period, potentially over at least one year, of the melting on the surface of a glacier, while limiting the need to send an operator to the field.

The other objects, features and advantages of the present invention will become apparent on examination of the following description and the accompanying drawings. It is understood that other advantages can be incorporated. SUMMARY OF THE INVENTION

To achieve this objective, according to one embodiment, the present invention provides a device for measuring the surface melt of a glacier comprising a module for measuring the surface melt of the glacier, an acquisition unit suitable for controlling the module. measurement and receiving a measurement signal from the measurement module, a system for remote transmission of the measurement signal transmitted from the measurement module by the data acquisition unit, a support configured to support at least part of the measurement module, and a battery, suitable for supplying at least the measurement module, the data acquisition unit and the remote transmission system.

The measurement module comprises a cable of which a first portion, or even a first end, is intended to be anchored in a hole drilled in the glacier as well as a reel suitable for winding the cable through a second portion, or even a second end, of the cable, so as to keep the cable in tension between said first and second portions, or even between its two ends. The measuring module further comprises an encoder wheel configured fixedly with respect to the reel and so as to accommodate, along at least part of its circumference, a third portion of the cable located between said first and second portions, or even between the two ends of the cable, so that the encoder wheel is rotated during winding of the cable by the reel; the reel and the encoder wheel being arranged substantially in line with the drilled hole using the support placed on the glacier, so that the melting on the surface of the glacier induces the winding of the cable by rewinder and a corresponding rotation of the encoder wheel. The remote transmission system is therefore able to emit a measurement signal proportional to the melting of the glacier's surface.

The device as introduced above is placed on the surface of the glacier. Thus, the distance between the surface of the glacier and the whole formed by the reel and the encoder wheel does not change over time, it is the progressive winding of the cable which is measured by the encoder wheel to evaluate the melting on the glacier's surface. The measurement of melting at the surface of the glacier can thus be carried out continuously. This also has several advantages. First, the stability of the device is maintained during the melting of the glacier surface. Once installed, the device is therefore operational for a long period of time, potentially for at least a year, without requiring frequent intervention by an operator who has to visit the installation site. The reliability of the measurements of the surface melt of the glacier acquired over this period is also preserved. Second, the use of a measuring module comprising a winder and an encoder wheel according to the invention confers a precision of the order of a millimeter on the measurement, while limiting the cost of the device, in particular compared to a device comprising an ultrasound source and the appropriate detector.

Optionally, the invention may further exhibit at least any of the following characteristics:

- the measurement module can include at least one sensor suitable for measuring at least one environmental condition of the device, in particular the temperature, the force of the wind, the sunshine and / or the depth of snow;

- the measurement module can include at least one sensor, such as an inclinometer or a GPS sensor, capable of measuring at least one operating condition of the device, such as the inclination or the position of the device;

- the data acquisition unit may be suitable for storing measurement signals from the measurement module;

- the reel may be an automatic return reel, preferably comprising a leaf spring;

- The device may further comprise a ballast fixed to the cable in order to anchor the first portion, or even the first end, of the cable in the drilled hole, the ballast being preferably initially deposited resting on the bottom of the drilled hole. The use of a ballast deposited at the bottom of the drilled hole makes it possible to benefit from a measurement capacity of the surface melting of the glacier equal to the depth of the drilled hole. It potentially combines the advantages stated above and is compatible with the following characteristics of the device;

- The cable can be made of a synthetic material, preferably polyamide, preferably nylon. The use of a synthetic material, such as polyamide and more particularly nylon, advantageously makes it possible, on the one hand, to limit the cost and weight of the device, and on the other hand, to withstand the weather conditions observable on a glacier ;

- the initial length of the cable between said first and third portions may be between 5 and 20 meters long, preferably between 8 and 15 meters. The measurement is thus carried out over a large range in length, thus making it possible to measure the melting at the surface of the glacier for high melting amplitudes or to carry out the measurement over an extended period, preferably over one year;

- the cable may be of circular section, thus making it possible to limit its exposure to the wind, in particular on a possible emerged portion, located between the surface of the glacier and the measurement module, which may be exposed to bad weather. The reliability of the measurement is thus improved;

the device may further include a battery recharging module, more particularly a photovoltaic panel.

According to a second aspect, the present invention provides a method for measuring the melting at the surface of a glacier, using at least one device according to any one of the previously stated characteristics, used in combination or alternatively, comprising a step of taking measurements. measurements of the surface melt of the glacier by the measurement module described above, controlled by the data acquisition unit, said measurements comprising:

- progressive winding of the cable by the reel as the surface of the glacier melts, causing the third portion of cable to move in contact with the encoder wheel;

- a rotation of the encoder wheel induced by the winding of the cable;

- a measure of the degree of rotation of the encoder wheel;

- a conversion of the measurement of the degree of rotation into a measurement of the height of the melt; the transmission, by the remote transmission system, of the measurements taken, to a receiving system, such as a server, preferably via the GSM network.

The method according to the invention has the advantages of the device described above. In addition, the reduced cost of the device as well as the limitation of operator intervention is compatible with the deployment of a plurality of devices to measure at several points of the glacier the melting on the surface of the glacier. Thus, a quantification of the melting is possible over a large region, for example at the scale of a glacier.

According to the embodiment in which the measurement module comprises at least one sensor suitable for measuring at least one environmental condition of the device, the method further comprises a measurement of said at least one environmental condition. The measurement of at least one environmental condition, in particular the temperature, the force of the wind, the sunshine and / or the depth of snow present on the surface of the glacier, can thus supplement the measurement of the melting on the surface of the glacier, in the goal, for example, to establish a digital model of glacier surface melting.

According to the embodiment in which the measurement module comprises at least one sensor, such as an inclinometer or a GPS sensor, capable of measuring at least one operating condition of the device, the method further comprises a measurement of said at least an operating condition of the device, such as tilt or position of the device. Measuring said at least one condition makes it possible to ensure the proper functioning of the device regardless of the measurement of the glacier melt. It is thus possible to identify more reliably a malfunction of the device and therefore to limit or even avoid unnecessary movements of an operator.

According to the embodiment in which the acquisition unit is suitable for storing measurement signals coming from the measurement module, the method comprises, between the steps of taking measurements and of transmission, a step of storage by the unit of acquisition of measurements made by the device. In the event that the device does not have access to the GSM network, for example during bad weather, the measurements are thus stored without loss by the data acquisition center. Subsequent transmission is then carried out by the remote transmission system.

Furthermore, according to this particular embodiment, the transmission of the data stored by the acquisition unit is advantageously carried out discontinuously, preferably daily. As an alternative to a continuous data transmission, this embodiment reduces the power consumption of the remote transmission system in order to increase the autonomy of the device.

BRIEF DESCRIPTION OF THE FIGURES

The aims, objects, as well as the characteristics and advantages of the invention will become more apparent from the detailed description of one embodiment thereof which is illustrated by the following accompanying drawings.

Figure 1 illustrates an overview of the device according to one embodiment of the invention.

Figure 2 shows a functional diagram of the device according to one embodiment of the invention.

Figures 3A and 3B and illustrate an embodiment of the measurement module

FIG. 4 illustrates the steps of the method for measuring the surface melting of a glacier according to one embodiment of the invention.

The drawings are given by way of examples and are not limiting of the invention.

They constitute schematic representations of principle intended to facilitate understanding of the invention and are not necessarily on the scale of practical applications. In particular, the relative scales of the elements of the device are not necessarily representative of reality. In addition, the respective placements of the elements of the device as described in FIG. 2 are not representative of reality.

DETAILED DESCRIPTION OF THE INVENTION

During the detailed review of the embodiments of the invention, optional features are stated, which may optionally be used in combination or alternatively.

The device 1 for measuring the melting on the surface of a glacier is intended to be placed on the surface of a glacier, and more particularly on the surface of ice or of a snowpack, preferably on the surface of the area glacier ablation. As illustrated in FIG. 1, the device 1 comprises a support 13 configured to support in a stable manner at least part of the measurement module 11, and in particular to support the whole formed by the reel and the encoder wheel substantially in line with it. 'a hole drilled in the surface of the glacier. According to particular embodiments, the support 13 is configured to support at least part of the device 1, preferably the device 1 in its entirety. We consider in the following the embodiment according to which the support 13 supports the device 1 in its entirety. Since severe weather conditions can occur on a glacier, the support 13 is configured so as to hold and stabilize the device 1, in particular so as to prevent the device 1 from tilting or deviating from its initial position. More particularly, the support 13 is configured so as to minimize its resistance to the wind.

The support 13 thus comprises at least two feet 130, preferably three feet, fixed to the body 10 of the device 1 so as to hold it. The feet may include at their distal ends bases 131, potentially adjustable, intended to be placed in contact with the surface of the glacier. The feet 130 can be directly attached to the body 10 by attachment methods known to those skilled in the art. Said fixing can also be effected by means of a part, for example circular, enclosing all or part of the body 10, and on which the feet 130 are fixed. The fixing of the feet 130 on the body 10 is preferably carried out at the level of the upper half of the body 10 in order to ensure the stability of the device in inclement weather.

Various configurations suitable for allowing the arrangement of the body 10 of the device 1 on the surface of the glacier, while keeping it substantially in line with a hole drilled in the glacier, are conceivable by those skilled in the art. For example, the support may comprise two feet 130 terminated by bases 131 configured so as to stabilize the device 1, for example orthogonally to a plane formed by said feet 130. The support may alternatively comprise a plurality of feet 130 arranged around the body 10, the angles formed between the feet 130 not necessarily being equal to each other. According to a particular embodiment, the support 13 is a tripod comprising three feet 130, each terminated by a base 131 and fixed in a distributed manner around the body 10, for example at angles of substantially 120 ° between the feet 130.

The body 10 of the device 1 is configured so as to contain the battery 14, the measurement module 11, the remote transmission system 12, and a data acquisition unit 15, while minimizing the wind resistance of the device. It is understood that a shape having one main dimension will be chosen, for example a cylinder or an elongated block, rather than having two main dimensions, such as a panel. The body 10 can be held by the support 13 at a distance from the surface of the glacier or in contact with this surface, or even be partially inserted into the drilled hole. In the latter alternative, the device preferably comprises a tube extending the body 10 and configured so as to be partially inserted into the drilled hole. The body 10 can further include openings 16 allowing access to said contained elements. An opening 16 may be formed by a lumen in the wall of the body 10, closed by a door 160, or a non-solid end of the body 10 closed by a cap 161. According to the particular embodiment described in FIG. 1, the body 10 of device 1 comprises a door 160 giving access to the lower part of the body 10, and a cap 161 giving access to its upper part.

The structure of the device 1, comprising the support 13 and the body 10, can be made from a plurality of materials accessible to a person skilled in the art, preferably chosen from synthetic materials, composite or not, and metals, preferably stainless steel, the materials being resistant to meteorological conditions observable on a glacier, and in particular to low temperatures and high humidity. The choice of materials is preferably made so as to limit the weight of the device to facilitate its transport, while aiming to guarantee the stability of the device during the period of its use, preferably for one year.

As illustrated in FIG. 2, the device comprises a battery 14 suitable for supplying at least one of the elements included in the device 1, and particularly at least the measurement module 11, the remote transmission system 12 and the data acquisition unit 15. In the measuring module 11, the battery 14 more particularly supplies the encoder wheel 112 included in the whole 110, 111, 112 formed by the cable 110, the reel 111 and the encoder wheel 112. According to particular embodiments, the module measuring device comprises sensors 113, 114 which can also be powered by battery 14.

The battery 14 thus allows the autonomous measurement of at least the melting on the surface of the glacier and the transmission of the measurement by the device 1. So that the device is operational for a prolonged period, preferably one year, without displacement of an operator. in the field to replace the battery 14, the device can be provided with a recharging module 141 of the battery 14. The recharging module 141 is more particularly a photovoltaic panel, arranged for example on the support 13 as described in figure 1, and / or directly on the body 10 of the device 1.

The measurements performed by the device 1 include the measurement of the melting of the surface of the glacier, described in more detail later, and according to particular embodiments, the measurement of conditions specific to the device or to its environment. The measurement module 11 can thus comprise at least one sensor 113 suitable for measuring at least one environmental condition of the device 1. The The environmental conditions considered are in particular, but not limited to, the temperature, the force of the wind, the sunshine, the depth of snow deposited on the surface of the glacier, said surface being for example defined when the device is installed.

The measurement module 11 may further comprise at least one sensor 114 suitable for measuring at least one operating condition of the device 1. The operating conditions considered are in particular, but not limited to, the position and the inclination of the device. 1. Measuring the position of the device, for example by a GPS sensor, makes it possible to check any abnormal movement of the device, for example in the event of severe weather, in order, if necessary, to find it easily. The inclination of device 1, measured for example by an inclinometer, makes it possible to verify a possible tilting of device 1.

Note that the term measurement module 11 applies here from a functional and not necessarily structural point of view. Indeed, the whole 110, 111, 112, formed by the cable 110, the reel 111 and the encoder wheel 112, can be physically distinct from the sensors 113, 114, and therefore said elements are potentially placed at distinct locations of the device 1.

As illustrated in FIG. 2, the measurements taken by the measurement module 11 are transferred to the acquisition unit 15. The acquisition unit 15 is thus able to receive the measurements, or even process them, and relay them to the monitoring system. remote transmission 12. The acquisition unit is also able to control the measurement module 11, that is to say to manage the measurement parameters of the measurement module 11, for example the frequency of measurement of the rotation of the encoder wheel. and / or sensors 113, 114. The remote transmission system 12 is suitable for transmitting the measurements taken by the measurement module 11 via a satellite network, more preferably via the GSM network, to a receiving system, such as a server or a computer. The teletransmission systems 12 suitable for being incorporated into the device 1 are known from the state of the art. According to a particular embodiment, the remote transmission system 12 can also be included in the central acquisition unit 15.

The measurements can be transmitted continuously by the remote transmission system 12. However, the location of the device 1 can induce limited access, for example intermittent, to the network. According to one embodiment of the invention, the acquisition unit 15 is therefore able to store measurement signals coming from the measurement module 11. Thus, when the network for the transmission of measurements is not accessible, the unit acquisition 15 stores the measurements for transmission later by the remote transmission system 12. This embodiment also allows periodic transmission of measurements, configured to take place a defined number of times per month, per week or even per day, preferably daily. Thus, the remote transmission system 12 is only activated at the scheduled transmission times, thus limiting the consumption of the remote transmission system 12 and consequently that of the device 1.

The glacier surface melt is measured by the measurement module

I I, more particularly by the whole 110, 111, 112 formed by the cable 110, the reel

111 and the encoder wheel 112, illustrated in FIGS. 3A and 3B. The cable 110 is connected by a first portion 1100, or even a first end, to a positioning element

115 suitable for anchoring the first portion 1100, or even the first end, of the cable in the drilled hole. The cable 110 is connected by a second portion 1101, or even a second end, to a reel 111. The reel 111 is able to wind the cable 110 by exerting a restoring force on the cable 110, so as to hold the cable 110 in tension between said first and second portions, or even between its two ends.

The cable 110 is also arranged so that a third portion 1102 of the cable 110, located between said first and second portions, or even between the two ends of the cable 110, is received, preferably in contact, along at at least part of the circumference of the encoder wheel 112, for example in a groove 1120. The encoder wheel 112 is fixedly configured with respect to the rewinder

III, and said part of the encoder wheel 112 is configured such that a displacement of the third portion 1102 of the cable 110, during a winding of the cable 110 by the reel 111, causes the rotation of the encoder wheel 112 according to a axis of rotation passing through the center of the wheel.

Cable 110 is intended to be inserted into a hole drilled vertically in the ice or snowpack. To do this, vertical drilling is carried out beforehand on the surface of the glacier by techniques known to those skilled in the art, in particular using a steam probe, or using a drilling machine. Once the cable 110 has been inserted into the drilled hole, the first portion 1100 of the cable 110 is held by the positioning element 115 at a fixed point of the drilled hole, preferably at the bottom of the drilled hole. The positioning element can for example be an anchor deploying in the drilled hole or a ballast initially deposited resting on the bottom of the drilled hole, of weight preferably between 100 g and 1 kg, more preferably. between 300g and 700g. The use of a ballast constitutes a preferred embodiment of the invention, to which reference is made below.

As the glacier melts, the surface of the ice or snowpack drops from the bottom of the drilled hole. The device 1 being placed on said surface, the distance between the ballast 115 and the reel 111 decreases. As this distance is reduced, the reel 111 winds the cable 110 in a rotational movement illustrated in Figure 3, so that the cable 110 remains in tension between the first 1100 and second 1101 portions, or even between its portions. two ends. Winding of the cable induces a displacement of the third portion 1102 of the cable 110 and a corresponding rotation of the encoder wheel 112. By measuring the rotation of the encoder wheel 112, a continuous measurement of the snowmelt and / or of ice on the surface of the glacier is advantageously obtained.

The ballast 115 being deposited resting on the bottom of the drilled hole, the length of the cable 110 between the first 1100 and third 1102 portions corresponds at least to the depth of the drilled hole. This particular embodiment makes it possible to benefit from a cast iron measurement capacity equal to the depth of the drilled hole. More particularly, the length of the cable 110 between said portions is between 5 and 20 meters, preferably between 8 and 15 meters. Thus, if we consider a surface melt of the glacier of 10 meters per year in the ablation zone of the glacier, device 1 potentially makes it possible to measure the surface melt of a glacier over a prolonged period, and in particular over about a year.

Preferably, the cable 110 is of circular section, thus making it possible to limit its exposure to the wind, in particular on a possible emerged portion. Indeed, in the alternative where the device is free from a tube extending the body 10 and configured so as to be partially inserted into the drilled hole, the cable is liable to be exposed to the weather on a portion situated between the surface of the glacier and the body 10 of the device 1, and more particularly the measuring module 11.

The cable 110 is made from a non-elastic material resistant to meteorological conditions observable on a glacier, and in particular to low temperatures and high humidity. The material can be metal such as stainless steel or preferably a synthetic material, preferably polyamide, more preferably nylon. The use of a synthetic material in fact has advantages over metal. On the one hand, a synthetic cable is lighter and more flexible than a metallic cable. On the other hand, a synthetic cable can be pretreated to improve its resistance to the conditions. weather, in particular by waterproofing. In addition, synthetic cable is compatible with commercial reels of lower cost, weight, and power consumption than wire rope reels. Preferably, the winders used in the measuring module 11 are self-returning, more preferably comprising a leaf spring.

The encoder wheel 112 according to the invention can be a commercial wheel suitable for receiving, for example in a groove 1120, the cable 110 according to the characteristics described above. Preferably, the coding street 112 gives a measurement precision of the length of coiled cable 110 of between 10 cm and 1 mm. According to a particular embodiment, an OTT SE 200 encoder wheel is used.

The relative position of the cable 110, of the reel 111 and of the encoder wheel 112 is chosen so as to allow the winding of the cable 110 and the rotation of the encoder wheel 112 while preventing the movement of the cable 110 from being impeded at one point. any point of its course. Depending on the diameters of the reel 111 and of the encoder wheel 112, it may be advantageous to position lugs 116 so as to guide the path of the cable 110. According to a particular embodiment, the cable passes through a slot 117 for be deflected by at least one lug 116 so as to bypass the reel 111. The light 117, the reel 111 and the encoder wheel 112 being aligned, two additional lugs 116 guide the cable 110 so that the third portion 1102 of the cable 110 is accommodated along part of the circumference of the encoder wheel 112 by making a 180 ° turn to the reel 111. According to an alternative embodiment, it is conceivable that the light 117, the encoder wheel 112 and the reel 111 forms a 90 ° bend, by which the cable 110 is received along a part of the circumference of the encoder wheel 112 by making a 90 ° turn to the reel 111.

The device 1 according to the characteristics described above, used alternatively or in combination, can be used in a method 2 for measuring the surface melting of a glacier. The method 2 has the advantages described above of the device 1, and in particular the continuous, autonomous and remote measurement of the surface melting of a glacier over an extended period of time, preferably over one year. In addition, the limitation of the cost and weight of the device 1 as well as the travel in the field of an operator, facilitates the deployment of a plurality of devices to measure the surface melting of the glacier at several points, or even a multitude of. points, preferably in the glacier ablation zone. Thus, method 2 makes it possible not only to measure the melting at the surface of a glacier, but by no longer to quantify the melting on the scale of the glacier, for example using around twenty devices distributed over the glacier.

Certain steps of method 2, according to one embodiment of the invention, are shown in FIG. 4. Method 2 comprises in particular a first step of taking measurements, and in particular of measuring 200 of the melting on the surface of the glacier. As previously described, the measurement 200 of the melting at the surface of the glacier by the measurement module 11, controlled by the data acquisition unit 15, comprises a progressive 2001 winding of the cable 110 by the reel 111 as the surface of the glacier melts, causing a displacement of the third portion 1102 of cable 110 in contact with the encoder wheel 112. Said displacement induces a rotation 2002 of the encoder wheel 112.

The degree of rotation 2002 of the encoder wheel 112 is measured 2003, preferably by the encoder wheel 112. The degree of rotation 2002 is converted 2004 into a length of coiled cable 110, by the data acquisition unit 15 or by the encoder wheel 112 , the length of coiled cable being equal to a height measurement of melt in the present invention.

The taking of the measurements can also include the measurement 201 of at least one environmental condition by at least one sensor 113 suitable for measuring at least one environmental condition of the device. The measurement 201 of at least one environmental condition, for example the temperature, the force of the wind, the sunshine and / or the depth of snow deposited on the surface of the glacier can thus complete the measurement of the melt on the surface of the glacier, in particular in order to establish a numerical model of the surface melting of glaciers. This embodiment of method 2 is particularly advantageous for quantifying the surface melting of a glacier in a point-wise or distributed manner by multiplying the number of devices 1 on the surface of the glacier. For example, the measurement of the melt 200 can be correlated with the sunshine, for example according to the adret or ubac slope, as well as to the variation of the sunshine during the measurement period.

The taking of the measurements may also include the measurement 202 of at least one operating condition by at least one sensor 114 suitable for measuring at least one operating condition of the device 1. The measurement 202 of at least one operating condition of the device. device 1 makes it possible to ensure the correct functioning of the device independently of the measurement of melting on the surface of the glacier. The envisaged operating conditions are for example the inclination or the position of the device 1. A change in the position of the device may occur, caused by example by bad weather. This displacement can induce unwinding of the cable 110, or cause the ballast 115 to no longer rest against the bottom of the hole drilled in the glacier, disturbing the measurement 200 of the melting on the surface of the glacier. A modification of the inclination of the device 1, or even its tilting, can also occur. It should be noted that an inclination of the device 1 does not disturb the progressive winding of the cable and therefore is not likely to disturb the measurement of the melt by the device 1. On the other hand, tilting the device can cause possible discomfort or even a blocking of the winding of the cable 110. By measuring 202 of at least one operating condition of the device 1, it is possible to identify more surely a malfunction of the device, or even the causes of the malfunction, and potentially to limit or even avoid unnecessary travel by an operator.

As soon as the measurements are taken 20, they can be transmitted 21 to the data acquisition unit 15 and relayed to the remote transmission system 12, intended for a receiving system, such as a server or a computer, preferably via the network GSM.

As access to the GSM network can be limited on the glacier, the measurements can be stored 22 by the central data acquisition 15 in order to avoid loss of measurements. A subsequent transmission is then performed by the remote transmission system 21, when the network is again accessible. Furthermore, the storage step 22 provides an alternative to continuous transmission 21 of the measurements. Indeed, thanks to the storage 22 of the measurements, their transmission 21 can take place discontinuously, preferably daily. Thus, the transmission system is not activated continuously, thus increasing the autonomy of the device 1.

Following the transmission 21, the measurements are received 23 by a receiving system such as a server or a computer for their storage or for their use by an operator. If necessary, measurement instructions can be sent remotely by a transmitter system possibly confused with said receiver system, to the remote transmission system 12 and transmitted to the acquisition unit 15. Thus, the parameters for taking measurements by the measurement module 11 can be modified 24 by the acquisition unit 15, such as the measurement frequency of the sensors 113, 114, the frequency of sending the rotation measurements from the encoder wheel 112 to the acquisition unit 15, and / or the frequency of sending by the remote transmission system 12. It is also envisaged that a measurement of an operating condition of the device 1 is recognized as abnormal and triggers the emission of an alert to warn an operator. . The invention is not limited to the embodiments described above and extends to all the embodiments covered by the claims.

LIST OF REFERENCES

1 Measuring device

10 Device body

11 Measuring module

110 Cable

1,100 First portion

1 101 Second portion

1 102 Third portion

1 1 1 Rewinder

112 Encoder wheel

113 Sensor

114 Sensor

115 Positioning element

12 Remote transmission system

13 Support

14 Battery

141 Charging module

15 Central purchasing office

16 Opening

160 Door

161 Cap

2 Measurement method

20 Taking measurements

200 Measurement of the surface melt of the glacier

2001 Cable winding

2002 Rotation of the encoder wheel

2003 Rotation measurement

2004 Conversion to cast height

201 Environmental condition measurement

202 Operating condition measurement

21 Storage

22 Transmission of measures

23 Receipt of measurements

24 Changing the measurement instructions

Claims

1. Device (1) for measuring the surface melting of a glacier comprising:

- a measurement module (11) of the melting on the surface of the glacier;

- a central acquisition unit (15) capable of controlling the measurement module (11) and receiving a measurement signal from the measurement module (11);

- a remote transmission system (12) of the measurement signal transmitted from the measurement module (11) by the data acquisition unit (15);

- a support (13) configured to support at least part of the measurement module (11), and

- a battery (14) suitable for supplying at least the measurement module (11), the data acquisition unit (15) and the remote transmission system (12);

- characterized in that the measuring module (11) comprises:

- a cable (110), a first portion (1100) of which is intended to be anchored in a hole drilled in the glacier;

- A winder (111) suitable for winding the cable (110) by a second portion (1101) of the cable (110), so as to keep the cable (110) in tension between said first and second portions;

- an encoder wheel (112) configured fixedly relative to the reel and so as to accommodate, along at least part of its circumference, a third portion (1102) of the cable (110) located between said first and second portions so that the encoder wheel (112) is rotated during winding of the cable (110) by the reel (111); the reel (111) and the encoder wheel (112) being arranged substantially in line with the drilled hole using the support (13) placed on the glacier, so that the melting on the surface of the glacier induces the winding of the cable by the reel (111) and a corresponding rotation of the encoder wheel (112), the remote transmission system (12) then being able to emit a measurement signal proportional to the melting on the surface of the glacier.

2. Device (1) according to the preceding claim, wherein the measuring module (11) comprises at least one sensor (113) suitable for measuring at least one environmental condition of the device.

3. Device (1) according to any one of the preceding claims, wherein the measuring module (11) comprises at least one sensor (114), such as a inclinometer or a GPS sensor, suitable for measuring at least one operating condition of the device (1), such as the inclination or the position of the device (1).

4. Device (1) according to any one of the preceding claims, wherein the data acquisition unit (15) is suitable for storing measurement signals from the measurement module (11).

5. Device (1) according to any one of the preceding claims, in which the reel (111) is an automatic return reel, preferably comprising a leaf spring.

6. Device (1) according to any one of the preceding claims, further comprising a ballast (115) fixed to the cable to anchor the first portion (1100) of the cable in the drilled hole, preferably the ballast being initially deposited in support at the bottom of the drilled hole.

7. Device (1) according to any one of the preceding claims, wherein the cable (110) is made of a synthetic material, preferably of polyamide, and more preferably of nylon.

8. Device (1) according to any one of the preceding claims, wherein the initial length of the cable (110) between said first (1100) and third (1102) portions is of a length between 5 and 20 meters, preferably between 8 and 15 meters.

9. Device (1) according to any preceding claim, wherein the cable (110) is of circular section.

10. Device (1) according to any one of the preceding claims, further comprising a recharging module (141) for the battery (14), more particularly a photovoltaic panel.

11. A method (2) for measuring the surface melting of a glacier using at least one device (1) according to any one of claims 1 to 10, comprising the following steps:

- the taking (20) of measurements (200) of the melting on the surface of the glacier by the measurement module (11) controlled by the data acquisition unit (15), each measurement (200) comprising:

• progressive winding (2001) of the cable (110) by the reel (111) as the surface of the glacier melts, causing displacement of the third portion (1102) of the cable;

• a rotation (2002) of the encoder wheel (112) induced by the winding of the cable (110); • a measure (2003) of the degree of rotation of the encoder wheel (1 12);

• a conversion (2004) of the measurement (2003) of the degree of rotation to a measurement of the height of the melt;

- transmission (21), by the remote transmission system (12), of the measurements taken (20), to a receiving system, such as a server, preferably via the GSM network;

12. The method (2) of claim 11, wherein, the measurement module (11) comprising at least one sensor (113) suitable for measuring at least one environmental condition of said device, the method (2) further comprises a measurement. (201) of said at least one environmental condition.

13. Method (2) according to any one of claims 11 and 12, wherein the measurement module (11) comprising at least one sensor (114), such as an inclinometer or a GPS sensor, suitable for measuring at minus one operating condition of the device (1), the method further comprises a measurement (202) of said at least one operating condition of the device, such as tilt or position of the device.

14. A method (2) according to any one of claims 11 to 13, wherein, the acquisition unit (15) being suitable for storing measurement signals from the measurement module (11), the method comprising, between the steps of taking measurements (20) and transmitting (21), a step of storing (22) by the data acquisition unit (15) of the measurements made by the device (1).

15. The method (2) of claim 14, wherein the transmission step (21) comprises the transmission of the stored data (22) by the data acquisition unit (15), and is carried out discontinuously, preferably daily.