RU145470U1 - TEMPERATURE AND LEVEL CONTROL PROBE - Google Patents

Abstract

1. A probe for temperature and level control (ZKTU) of the liquid in the spent nuclear fuel exposure pool, including a protective cylindrical body, inside of which assemblies of detectors (DM) are uniformly distributed, consisting of cable heated thermocouples (NT) and heaters that are in thermal contact with each other another and lattices for spatial fixation of LEDs mounted in thin pipes, characterized in that the casing is made in the form of two coaxial pipes external and internal, each of which has a longitudinal slit along the entire length, In this case, the slots are 180 ° offset relative to each other, distance elements forming a labyrinth are placed between the tubes, LEDs containing reference thermocouples (RTs) are additionally placed inside the housing, LEDs with RTs are placed in the center of the housing, and LEDs with NTs are placed in a circle around the LED with RT, in the LED with NT, the thermocouples together with the heater are attached to the case by means of metal solder, the LEDs with RT are placed in the housing below the LED with NT, a pair of NT and RT thermocouples forms sensitive elements (CE), while these thermocouples are located in different SD.2. ZKTU according to claim 1, characterized in that the LEDs include both end and side thermocouples. ZKTU according to claim 1, characterized in that the housing has a head in which a passive thermostat is placed and the free ends of the thermocouples are switched. ZKTU according to claim 1, characterized in that the RT and, preferably, NT have a working junction isolated from the housing.

Description

This utility model relates to a thermophysical sensitive device - a temperature and level probe (ZKTU) for a nuclear power plant, which can be used for a spent fuel storage pool, for technological rooms where emergency flooding is possible, for bubblers and other technological tanks.

Known float sensor for the water level in the pool, including a float in the form of a ball, a support structure with left and right support posts located on the pool, a level sensor with the possibility of vertical movement between the support posts and the upper and lower limit switches. The float and level sensor are connected to each other by a traction cable (CN 201926486 (U), class G01F 23/44, 2011).

The disadvantage of this level sensor is the low reliability and sensitivity, determined by the presence of a mechanical connection, by means of a traction cable, between the float (sensitive element) located in the pool and the level sensor located on the shore of the pool. The traction cable can jam, sag or slip, which affects the reliability and accuracy of the level sensor.

The closest set of essential features and the technical result achieved is a temperature and water level sensor (DTU) in the holding pool, including a protective cylindrical body, inside of which detector assemblies (SD) are uniformly located, consisting of cable heated thermocouples (HT) and heaters located in thermal contact with each other. Their thermal contact is ensured by filling the gaps with magnesium oxide. SD pass through the holes of the gratings located at a predetermined distance from each other along the height of the housing of the DTU. The gratings provide spatial fixation of the SD in the housing of the DTU, as well as free passage of fluid through the corresponding holes in the gratings. In the DTU housing, holes for communication with the environment are made in height (JP 2013007721 (A), class G01F 23/22; G01K 7/02. 2013).

The design of the well-known DTU does not provide reliable thermal contact between the heater, the working junction of the thermocouple and the housing: the gaps between them are filled with magnesium oxide. These gaps create additional thermal resistance to the heat flux coming from the heater to the wall of the housing; spurious temperature gradients arise inside the LED. At the same time, the sensitivity of the LED decreases, since the working junction of the thermocouple measures not the temperature of the wall of the case, but something in between the temperature of the wall and the temperature of the heater, depending on the geometry. Also, the spread of the readings of different LEDs in one DTU is inevitable due to the spread of the fill factor of the gaps with magnesium oxide, the spread of the geometry of the gaps and the position of the LED elements in the DTU. This makes it difficult to set up a level control system. The inertia of DM is also increased due to an increase in the time constant of the heat transfer process due to the additional thermal resistance of magnesium oxide. The presence of openings in the housing of the DTU creates conditions for spurious heat transfer through mass transfer with the surrounding gas environment: the SD inside the housing can be cooled by air flow from ventilation or heated by steam flow. Thus, parasitic mass transfer can lead to disruption of the functioning of the DTU. In the design of the DTU there are no reference (unheated) thermocouples that constantly give out the ambient temperature necessary for accurate control of the heat transfer coefficient in the zone of the heated thermocouple. If periodic shutdown of heating is used to control the ambient temperature, the destruction of heaters and thermocouples is likely due to cyclic mechanical stresses. Thus, the prototype is difficult to use, has insufficient reliability and accuracy.

The technical result of the claimed utility model is to increase the accuracy and reliability of the thermophysical level sensor.

The specified technical result is achieved by the fact that the temperature and level control probe (CTL) of the liquid in the spent nuclear fuel (SNF) storage pool includes a protective cylindrical body, inside which the detector assemblies (SD) are uniformly distributed, which are thin pipes containing cable heaters, cable heated thermocouples (NT) that are in thermal contact with heaters, reference thermocouples (RT), also includes lattices for the spatial fixation of LEDs in the housing, while the housing flax in the form of a pipe with double walls - external and internal, the walls have a longitudinal slit along the entire length, while the slots are 180 degrees offset from each other, spacing elements are placed between the walls, LEDs containing RT are placed in the center of the case, and LEDs containing NTs with heaters are placed around a circle around LEDs with RTs, NTs, together with a heater and RTs, are attached to the inner walls of the LEDs with solder; pairs of NT and RT thermocouples form sensitive elements (CEs). RTs of one SE are preferably located below NT.

The double housing with spacer elements has high mechanical strength, which provides protection of the ZKTU from seismic effects, hydrogen explosions, etc. This ensures increased reliability of the ZKTU in emergency conditions. The distance elements form a labyrinth, which makes it difficult to blow the CE by air, the penetration of shock waves and hydrogen flashes. Steam condensation also occurs in the maze, which can distort the readings of the SE. At the same time, the labyrinth passes water, ensuring equal levels in the CE zone and in the pool, as well as equalizing the temperature inside and outside the ZKTU due to the mass transfer of water. To determine the presence of water in the CE zone, the difference in the readings of HT and RT is used, which is uniquely related to the heat transfer coefficient from the SD building in the HT placement zone and gives an accurate criterion for the presence of water in the CE zone.

It is advisable that the ZKTU contain both end CEs (located in the terminal of the DM) and side CEs (located on the inner side wall of the SD). The type and amount of SE in the composition of the ZKTU are determined by the specific control task based on their features:

- End CEs have only one fluid control point per LED, and side CEs have several height control points per LED;

The end CEs provide more precise control of the level position: when the level decreases, the tip completely leaves the water - a gas gap appears, heat transfer drops sharply, and the end HT readings increase rapidly. With lateral placement of the CE, a gas gap does not occur, the heat of the heater leaks through the housing into the water, the readings grow slowly, and the sensor signal is weaker. As a result, the accuracy of the side SEs is somewhat lower.

It is advisable that the PT and, preferably, HT had a working junction isolated from the housing. The isolation of RT and HT working junctions from the housing allows for the on-off inclusion of the indicated thermocouples, which allows you to immediately get the temperature difference HT and RT used to control the presence of liquid.

It is advisable that the housing ZKTU had a head. The presence of the head allows you to place a passive thermostat, necessary to equalize the temperature of the free ends of the thermocouples, as well as to perform the opposite connection of the free ends of thermocouples. It is advisable to place a resistance thermometer in the thermostat, so that according to its readings, it will be corrected for the temperature of the free ends of the thermocouples when measuring the temperature.

The analysis of the prior art showed that the claimed combination of essential features set forth in the utility model formula is unknown. This allows us to conclude that it meets the criterion of "novelty."

The essence of the utility model is illustrated by drawings, a design description and an example of practical implementation.

In FIG. 1 shows a longitudinal section and a cross section of a ZKTU.

In FIG. Figure 2 shows longitudinal sections and cross sections of LEDs with HT, PT, and heaters.

ZKTU (Fig. 1) includes a protective housing 1 with tubular assemblies of detectors 2, 3 located in it, containing thermocouples and heaters. The body is made in the form of a pipe with double walls - external and internal. The outer and inner walls of the housing along the entire length have longitudinal slots 4 for the passage of fluid. These slots are 180 degrees apart to prevent direct air and steam from entering the detector assemblies. Between the inner and outer walls of the housing, longitudinal inserts 5 are fixed, in which cutouts 6 are made for circulating the liquid. The housing has a head 7. In the head is a passive thermostat 8, which are the free ends of the thermocouples. A resistance thermometer is installed in the thermostat (not shown in the figure), designed to measure the temperature of the free ends of thermocouples. The detector assemblies 2, 3 are fixed hermetically in the head 7, the position of the assemblies inside the housing is fixed using several gratings 9. The gratings have openings 10 for free circulation of liquid. The robust housing design protects LEDs from blowing, steam, seismic effects and hydrogen explosions.

SD (Fig. 2) includes a housing 11 with a sealed terminal 12. In the housing are HT 13, PT 14 and heating elements 15.

The heating elements 15 together with HT 13 are soldered to the inner wall and to the end of the detector assemblies with metal solder 16, which provides good thermal contact of this assembly with the housing. The reference thermocouples 14 are also soldered to the body of the detector assembly 11 with solder 16. It is preferable to use a sectional heating element of cable type with a metal sheath 15. The heater is a loop in which the heating sections are connected in series. The end heating section is folded in half and has a U-shape, and the side heater consists of two sections belonging to the forward and reverse branches of the heating cable. It is also possible to use several heating cables in one assembly.

HT and RT are located in the terminal and on the side wall of the assembly.

The number of end CEs is limited by the number of assemblies of different lengths that can be placed in one ZKTU housing, therefore, in this example, a combination of end and side CEs is used.

An assembly with RT 3 is installed in the center of the ZKTU housing, and assemblies with HT of different lengths 2 are located at the edges around the assembly with RT (see Fig. 1).

The temperature of the liquid is controlled using one of the RTs, the readings of which are corrected using a resistance thermometer located in thermostat 8.

The number of thermocouples (end and side) in the assembly, the number of assemblies in the ZKTU and the length of the ZKTU are determined by the required number of fluid control points, the required sampling step and the controlled pool depth.

An example of practical implementation.

Prototypes of the declared ZKTU in accordance with the technical documentation ШПИС.407765.001 were manufactured by the Joint-Stock Company "POSIT" (Moscow region, Pushkin district, settlement Pravdinsky). This ZKTU has a length of about 12 meters and a diameter of the protective casing of 32 mm, it has 6 points for monitoring the presence of liquid and one point for controlling the temperature. Two manufactured ZKTU samples were successfully tested in conjunction with specialized electronic equipment developed by NPO INCOR LLC. Tests showed increased sensitivity and reliability. ZKTU is recommended for production and intended use.

Based on the foregoing, we can conclude that the claimed ZKTU can be implemented in practice with the achievement of the claimed technical result, i.e. It meets the criterion of “industrial applicability”.

Claims (4)

1. A probe for temperature and level control (ZKTU) of the liquid in the spent nuclear fuel exposure pool, including a protective cylindrical body, inside of which assemblies of detectors (DM) are uniformly distributed, consisting of cable heated thermocouples (NT) and heaters that are in thermal contact with each other another and lattices for spatial fixation of LEDs mounted in thin pipes, characterized in that the casing is made in the form of two coaxial pipes external and internal, each of which has a longitudinal slit along the entire length, In this case, the slots are 180 ° offset relative to each other, distance elements forming a labyrinth are placed between the tubes, LEDs containing reference thermocouples (RTs) are additionally placed inside the housing, LEDs with RTs are placed in the center of the housing, and LEDs with NTs are placed in a circle around the LED with RT, in the LED with NT, the thermocouples together with the heater are attached to the case by means of metal solder, the LEDs with RT are placed in the housing below the LED with NT, a pair of NT and RT thermocouples forms sensitive elements (CE), while these thermocouples are located in different SD 2. ZKTU according to claim 1, characterized in that the LEDs include both end and side thermocouples. 3. ZKTU according to claim 1, characterized in that the housing has a head in which the passive thermostat is located and the free ends of the thermocouples are switched. 4. ZKTU according to claim 1, characterized in that the RT and, preferably, the NT have a working junction isolated from the housing.