The Garisenda Tower is one of the so-called two towers of Bologna, a symbol of the city built in the late 11th and early 12th century. The historical slope is due to an ancient subsidence of the foundation ground, which led to its lowering to the current 48 metres in 1353. The initial height was in fact 60 metres, but the steep slope risked causing it to collapse, so it was lowered by 12 metres to prevent this.
Since 2018, the Garisenda has undergone consolidation works and has been constantly monitored to verify the structure’s behaviour over time and ensure its safety and preservation.
The current monitoring system of the Garisenda Tower supplied by Lunitek in the first half of 2022, based on the acoustic emission technique, a little-known and little-exploited monitoring technique with great potential, consists of a total of 16 ultrasonic sensors, 2 AEMission dataloggers for data synchronisation and recording, and a 4G router for remote acquisition on a server. An SFTP space, accessible from the Internet using the appropriate credentials, is also available to allow technicians to access and process the data. This system has already allowed a risk profile of the structure’s stability to be elaborated in almost real time.
The surveys and analyses are carried out by the Polytechnic University of Turin, and the data collected were processed using modern multi-parametric statistical analysis techniques to identify correlations between the data that most influence the stability of the structure.
In recent months, the reports from the sensors have increased, detecting abnormal vibrations and oscillations. The monitoring system will be expanded to allow a more detailed analysis of the structure.
Yeti is a compact and lightweight measurement sensor based on GNSS technology ideal for low budget projects.
It was designed for monitoring and early-warning of critical areas in the presence of hydrogeological risk.
Landslides, subsidence, volcanos, slope instability are some of the most common applications of the system but not only. All infrastructures such as civil buildings, water pipelines, energy plants, railways, bridges, dams, quarries, viaducts can be monitored using Yeti.
Circo Massimo monitoring during the Maneskin concert
The Circo Massimo is the largest building for spectacle of antiquity and one of the largest of all time (600 m long by 140 m wide) and is linked by legend to the very origins of Rome: here, in fact, the Rape of the Sabine Women took place.
On occasion of the Maneskin concert on 9 July 2022, Lunitek installed, on behalf of the Polytechnic of Turin and Fine Arts, 7 seismometers to record and assess the vibrations caused by the concert and their impact on the remains of the Circus.
LUNITEK is proud to present and offer you our HERMES, a premium-quality INFRASOUND SENSOR to detect low-frequency (not audible) sound waves produced by natural phenomena such as volcanic eruptions, adverse weather conditions, lightning, asteroids, wave motion, outgassing and minor volcanic explosions, debris-flow, rapid mass flows such as snow avalanches and landslides, earthquakes and related ground shaking, sea storms, mountain waves.
The rugged casing together with the low power consumption guarantee the employment of HERMES sensors also in hostile environment.
•BROADBAND (0.033* HZ to 200 HZ) *lower frequencies on request
•HIGH DYNAMIC RANGE (110 dB) LOW NOISE (-62DB PA² /HZ, REL TO 1 PA AT 1 HZ)
•LOW POWER
•LOW COST
•ROBUST PHYSICAL BUILD QUALITY AND SEALED ELECTRONICS
The eruption of the submarine volcano Hunga-Tonga-Ha’apai took place on Sunday January, 15th 2022 at 17:15 local time (5:15 in Italy) in the South Pacific archipelago and was one of the most powerful recorded in decades in the area. The Hunga Tonga – Hunga Ha’apai volcano is located in the Pacific Ocean in the Kingdom of Tonga about 65 km from the island where the capital Tonga is located and about 450 km from Fiji. It is a chain of islands located northeast of New Zealand, an area geologically set above a subduction zone of the Pacific plate below the Australian one. Nasa claimed that the force of the eruption was 500 times stronger than that of the atomic bomb dropped by the United States on Hiroshima, Japan, at the end of World War II.
Tsunami waves unleashed by the eruption up to more than 10.000 km away reached the coasts of several countries bordering the Pacific, from the United States to Japan, Chile, Peru and Ecuador.
The volcano produced an eruption with a gigantic explosion, generating a cloud that extended over 30 km in height (stratosphere) and a shock wave that propagated across the planet, travelling thousands of kilometers in spherical propagation (green lines in Figure 1 and link)
The phenomenon was observed by some geostationary satellites, whose sequential images show not only the enormous column of smoke produced, but also the displacement of dust and gas pushed by the shock wave.
The extraordinary power of the volcanic eruption was immortalized by satellites and also the shock wave that, travelling at the speed of sound, travelled the entire globe. Numerous barometers reports from all over the world captured its passage, with a sudden rise followed by an equally sudden fall in pressure.
The explosion was so powerful that it was recorded in detection instruments around the world.
Laboratorio di Geofisica Sperimentale) of the Department of Earth Sciences of the University of Florence, as well as an infrasonic sensor of Lunitek, located in Sarzana, from 20:15 local time on January, 15th, began to record the shock waves produced by the volcano’s explosion (at a distance between 17300 and 17900 km from the eruption) with an average direction of origin of about 30°N (red lines in Figures 2 and 3). These first waves passed north of Russia near the Arctic Circle and have a very long period of about 5 minutes, at the limit of the physical properties of acoustic waves (blue lines in Figures 1 and 2).
figura 2
The waves were recorded about 19 hours after the eruption (blue line in Figures 1 and 2). They traveled in an opposite direction, covering a greater distance, about 22.600, and passing from the south to the Antarctic, with a direction of origin 210 ° S.
The difference in arrival times made it possible to calculate that both wave fronts propagated with a speed of about 310 m/s (about 1100 km/h), which is the apparent speed of sound propagation in the upper atmosphere (Figure 3).
figura 3
Lunitek Hermes infrasonic sensor
Infrasounds are low-frequency sound waves that are below the hearing threshold (20 Hz), little perturbations of atmospheric pressure which, due to the low atmospheric absorption of these low frequencies, can propagate for thousands of kilometers and be detected by pressure sensors..
The differential infrasonic sensor Hermes is based on differential pressure measurement and the use of an acoustic filter to eliminate the stationary component of atmospheric pressure. Pressure measurement is entrusted to industrial-grade electronic sensors, which combine high precision with high reliability and constant performance over time.
In addition to strong eruptions such as that of the Hunga-Tonga-Ha’apai submarine volcano on January, 15th 2022, there are many sources of infrasonic waves, most of them produced by natural phenomena such as non-linear interactions between open ocean waves (microbaroms, which generate a signal at ~0.16 Hz recorded across the earth’s surface at any time), adverse weather conditions, outgassing and minor volcanic explosions, rapid mass flows such as avalanches and landslides, earthquakes and associated ground shaking, storms, mountain waves. Effective anthropogenic sources of infrasound, on the other hand, are aircrafts, trains and disturbances generated by powerful explosions.
A range of sensors with different sensitivity, dynamics and frequency ranges are being industrialized by Lunitek, which are able to cover the amplitude and frequency ranges of most of the above mentioned infrasonic sources, thus enabling their effective monitoring.
The study of the infrasonic spectrum is often carried out using array techniques to improve the signal-to- noise ratio and locate sources. In such techniques, signals recorded by sensors placed at a known distance are compared and processed and it is essential that the amplitude and phase response of the sensors be the same. Particular care was taken in the design of the Lunitek sensor in order to have products with identical characteristics and therefore immediately usable in arrays.
Below is shown the infrasonic signal produced by the eruption of the Hunga-Tonga-Ha’apai volcano and recorded in the Sarzana laboratories by the Lunitek Hermes 50 with high sensititvity (0.8V/Pa) and medium frequency range (0.03 – 200 Hz).
Bibliografia:
GECO S.r.l. , gennaio 2020, “Progetto di industrializzazione di Sensore Infrasonico”, LGS – Laboratorio Geofisica Sperimentale, 19 gennaio 2022, “L’eruzione del vulcano Hunga Tonga Ha’apai del 15 gennaio 2022 – aggiornamento con prima analisi dei dati”
Lunitek has a duty to reduce workplace risk to the lowest feasible level by taking preventative measures. Lunitek has made every reasonable effort to enable working from home as a first option. Where working from home is not possible, we have made every reasonable effort to comply with the social distancing guidelines set out by the government. We fully maintained our operations and activities despite this crisis and we postponed all in-person events and meetings turning, them into virtual events. We have been in close contact with our customers and have provided technical support just as we did before. Lunitek will continue to evaluate and review current practices to ensure staff safety is kept to the highest possible standards and in line with the latest government guidelines.
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