HU210895B - Method and device for sensing and indicating predefined critical temperatures of materials stored in containers of closed system, primarily cereals stored in granaries - Google Patents

Abstract

The present invention relates to a method for detecting and signaling a specific critical temperature of materials stored in closed-circuit containers (1), in particular grain stored in grain silos, by measuring the temperature at specific levels of the material in the container (1). The present invention also relates to a device for detecting and signaling a critical temperature of a critical temperature of a material stored in a closed-circuit container (1), particularly a grain storage device, in which a temperature sensor (6) for measuring the temperature of the material in the container (1) is arranged. It is an object of the present invention that, when filling the container (1) with the material in the specified layers of the container (1), autonomous thermometer probes (2) indicating the temperature to be filled together with the material to be filled (2) are described in Zabra HU 210 895 AA description: 6 pages (inside / page figure)

Description

The invention further relates to an apparatus for detecting and indicating a specific critical temperature of material stored in closed system containers (1), in particular grain silos, comprising a temperature sensor (6) suitable for measuring the temperature of material in the container (1). The object of the invention is that, when the container (1) is being filled with material, autonomous telemetry probes (2) indicating a direct temperature value are supplied to certain layers of the container (1) together with the material to be filled.

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HU 210 895 A

Scope of the description: 6 pages (including page 1 figure)

EN 210 895 A tat, which emits a radio frequency signal at a specific frequency and strength at a specified temperature, preferably at a temperature of 2-3 ° C, by means of probes (2), which radio signal is received by a receiver (1) located outside the container (1). 3) sensing.

It is a further object of the invention that the heat detector (6) is housed in an autonomous probe (2) with a closed housing (5) having appropriate mechanical and thermal conductivity parameters, the outer dimensions of the housing (5) the largest particle diameter of the material stored in the container (1), and the temperature sensor (6) is connected to a long-life power supply (7) and an electronic switching unit and oscillator (8), which is connected to a radio frequency output (9) connected.

BACKGROUND OF THE INVENTION The present invention relates to a method for detecting and indicating a specified critical temperature of a material stored in a closed system container, in particular a grain silo, by measuring temperature at specific levels of the material in the container by means of temperature sensors.

The present invention also relates to an apparatus for detecting and indicating a specific critical temperature of a material stored in a closed system container, in particular a grain silo, comprising a temperature sensor suitable for measuring the temperature of the material in the container.

It is known that the above-critical rise in temperature in grain silos leads to spontaneous ignition and subsequent "chain reaction explosion". Based on practical experience, this critical temperature value is 38 ° C. Due to the large volume of grain, it is advisable to intervene at 35 ° C due to the rapid overheating of the heat inertia. In practice, this intervention is carried out by withdrawing or turning the whole mass of cereals in whole or in part.

According to the current state of the art, the temperature measurement in cereal silos is a so-called. special measuring cables are installed. There is a holding spiral inside the grain silo, around the measuring wire (s) and every 2 to 3 meters the temperature sensors. They are covered with a special, abrasion-resistant shrinkable plastic jacket. Thermo-Scan systems for district thermometers of the Danish company A / S N. FOSS ELECTRIC are the most widely used in Europe.

A common feature of these - and other companies' solutions - is that the system to be measured is a so-called. measuring cables or cables with thermal sensors (thermistors, resistors) are installed at specified levels. The measuring cables must be able to withstand multiple directions of high stress. These stresses are broadly as follows:

- tensile strength (the maximum force in this direction awakens during expansion and filling, calculated to be above 5 MN),

- resistance to crushing force applied to the outer jacket without damaging the temperature sensors,

- mechanical resistance to abrasion, grinding and surface destructive action of the outer jacket, particularly when filling the container,

- a good heat transfer capability so that the thermocouples inside the cable can accurately track the temperature change of the actual system being measured, so that proper action can be taken before reaching a critical temperature value, while ensuring safety. All in all, measuring cable is the critical and weakest element of these systems.

A common feature of district heating systems currently manufactured for this purpose, together with the Danish system, is the use of measuring cables with the highest risk of error.

The installation and replacement of measuring cables is highly problematic and requires special expertise and construction standards. (Some cables must have a tensile strength greater than 5 MN / cm ^2. ) Repair of test leads cannot be guaranteed.

The cost of measuring cables is extremely expensive due to special requirements. When installing a new cable, the entire system must be recalibrated.

The district heating alarm system to be activated in cereal silos in the given region must be extremely reliable, as this is the basis for intervention. Depending on the design level, the intervention can be control (open-circuit) or advanced level automatic, where the "dead time for intervention" is obviously reduced as human subjective factors can minimize time.

In Hungary, due to the scarce financial resources, a controlled solution would also be of great importance, since safe storage can only be ensured at this time by the fact that the stored material is virtually redundant in time. In most cases, district heating systems are either not installed at all or existing systems are so obsolete that they are inherently inoperable. The repair, due to the degree of obsolescence, would cost more than the cost of the original complete system, since the necessary cables are no longer produced in series.

It is an object of the present invention to provide a temperature sensing system for use in closed system containers which eliminates a significant portion of the error potentials of measuring cable systems,

EN 210 895 A and at the same time create a much simpler, more reliable, easier to operate and more economical system.

The present invention is based on the discovery that, when filling with a storage medium, by providing autonomous probes specially designed for detecting heat and temperature-dependent radio frequency signals, and for sensing the signals emitted by the probes outside the container, .

SUMMARY OF THE INVENTION During filling of the container with the material, autonomous telemetry probes indicating a direct temperature value are introduced into the specified layers of the container with the material to be loaded, preferably at a temperature of 2-3 ° C below the critical temperature of the material. and outputting a frequency and intensity radio frequency signal, which radio signal is detected by a receiver located outside the storage.

It is a further object of the present invention that the heat sensor is housed in an autonomous probe, preferably spherical in shape, with a closed housing having appropriate mechanical and thermal conductivity parameters, the outer diameter of which exceeds the maximum particle diameter of the material stored in the container. It is connected to a switching unit and an oscillator, which electronic switching unit and oscillator is connected to a radio frequency signal output located inside the housing.

The invention will now be illustrated by means of the drawings, in which a preferred embodiment is described.

Figure 1 shows an autonomous telemetering system installed to prevent spontaneous ignition of a set of cereals stored in a grain silo, while Figure 2 shows the conceptual design of an autonomous telemetry probe indicating a direct temperature value.

As shown in Figure 1, autonomous probes 2 are located in the container 1, in the material stored in the grain silo of the example. In addition to the storage 1, a receiver 3 is provided for receiving signals from probes 2 capable of emitting radio frequency signals. At the bottom of the reservoir 1, above the outlet, a grid 4 is provided for receiving the probes 2 during emptying of the reservoir.

Figure 2 shows the configuration of the autonomous probe 2. The probe 2 has a spherical closed outer casing 5 having mechanical and thermal conductivity parameters. Within the casing 5, two thermal sensors 6, which are special heat resistors, are arranged according to the example. The heat sensors 6 are connected to high-life batteries 7. Connected to the thermal sensor 6 within the enclosure 5, the electronic switching unit 8 and oscillator 8 having a radio frequency signal output 9, preferably with an antenna, and the radio frequency signal output 9 are contained in a resin 10 filling the interior of the housing 5.

When loading the container 1, for certain quantities of grain, depending on the parameters of the stored material, 0 40 ... 0 150 mm impact, pressure and highly abrasion resistant, good heat conductivity, preferably spherical, internally 7, heat sensors and transmitters 2 probes containing a radio transmitter, which is thus present in the layers of the stored medium and follows the dynamic and stationary states of the stored medium.

These 2 probes meet increased pressure requirements and are resistant to multi-directional mechanical forces.

The autonomous probes 2 thus installed (without wired connection) indicate the temperature of the stored medium at a predetermined value, taking into account the thermal conductivity correction factors of the housing 5 and the resin 10 with a maximum accuracy of ± 0.5 ° C. Since intervention (at least 2-3 ° C) must be carried out before reaching the critical (auto-ignition) temperature value (thermal inertia overrun, open-circuit intervention), the indicated accuracy is almost negligible.

The function of the individual probes (2) introduced into the system is thus to emit a radio frequency signal of a given frequency and strength according to the dimensioning of the integrated transmitter system at a temperature of 2-3 ° C below the critical temperature. The emitted signals can be received within 250 meters of the center within the storage area. In the case of an open chain of action, the operator can receive the transmitters of the probes 2 using a radio receiver tuned to this frequency, thus enabling timely intervention, whereas in the case of an automatic system this signal triggers an immediate intervention. The probes 2 are "collected" during emptying (dislocation) by mounting a grid 4 with a hole diameter 10 mm smaller than the defining outer dimensions of the probe 2, on which only the probes 2 are suspended.

Checking the functionality of the 2 probes is a requirement before each reuse. Controls can be easily performed under artificial conditions. The condition for re-qualification is to check the integrity of the external condition, the reaction to the external temperature level and the functionality of the long-life batteries 7. Autonomous 2 probes should be numbered and credentials recorded.

If the wall structure of closed containers is metal, "metal-woven" or heavily shielded, then it is necessary to install an insulated relay antenna, preferably in the upper closing part of the container.

In view of the cost, it is expedient to minimize the use of probes 2 having different frequencies for each cylindrical and rectangular cell within a silo unit, thus assigning a specific frequency to a container. For other technologies, different frequencies may be used per level within a storage.

The apparatus of the present invention does not require measuring cables with a high probability of failure, bulky wired networking, and complicated instrumentation.

The energy demand of the district heating alarm system according to the invention is an order of magnitude lower than that of the present state of the art.

HU 210 895 A

The maintenance, technical inspection and installation of the system based on the invention is much simpler than the known solutions. Thus, the required time, investment and maintenance costs are significantly reduced. Less chance of failure and safe operation.

The invention is not limited to the embodiment described in the description and the figures, but encompasses all embodiments within the scope of the claims, in particular the claims.

Claims (4)

PATENT CLAIMS CLAIMS 1. A method for detecting and indicating a specified critical temperature of a material stored in a closed system container, in particular a grain silo, by measuring temperature at specific levels of the material in the container by means of heat sensors, characterized in that the container (1) 1) supplying to its defined layers, together with the material to be loaded, autonomous telemetry probes (2) indicating a direct temperature value, by means of which the frequency and intensity of the radio frequency signal is given at a specified temperature, preferably at 2-3 ° C. which radio signal is detected by a receiver (3) located outside the container (1). Method according to claim 1, characterized in that, when emptying the container (1), the probes (2) are mounted on the outlet of the container (1), preferably with a mesh diameter (4) smaller than the defining outer dimensions of the probe (2). let's get it. 3. Apparatus for detecting and indicating a specific critical temperature of material stored in closed system containers, in particular grain silos, comprising a temperature sensor suitable for measuring the temperature of the material in the container, characterized in that the thermal sensor (6) has a closed housing with appropriate mechanical and thermal conductivity parameters. (5) is preferably arranged in a spherical-shaped autonomous probe (2), the outer dimensions of the probe (2) having a defining outer dimension exceeding the largest particle diameter of the material stored in the reservoir (1) and a long-life power supply (7). ) and connected to an electronic switching unit and oscillator (8), which is connected to the radio frequency signal output (9) located inside the housing (5). Apparatus according to claim 3, characterized in that the thermal sensor (s) (6), the battery (s) (7), the electronic switching unit and the oscillator (8), and the radio frequency signal output are located inside the enclosure (5). (9), preferably an antenna, is incorporated in the resin (10) which fills the probe (2).