RU135142U1 - CONDUCT METER INDUSTRIAL ATLANT 1101 - Google Patents

Abstract

1. An ATLANT 1101 industrial conductometer, comprising a liquid conductivity control unit, in which a stainless steel housing is made and an electrical conductivity sensor is located, which includes a contact measuring cell consisting of two electrodes, in which the first electrode is a control unit housing, and the second electrode is located on the portion of the housing of the control unit, which is sealed and connected during operation with an external pipeline with a controlled flow sample, thermo a sensor in thermal contact with the second electrode and designed to control the temperature of the liquid passing through the external pipeline, a terminal box, the housing of which is structurally combined with the housing of the control unit, and containing connecting elements for connecting the terminals of the first electrode, second electrode and temperature sensor to them, information cable, in which the signal conductors at the input are connected to the connecting elements of the terminal box, and a controlled display measuring unit, in which inform The input inputs are connected to the outputs of the signal conductors of the information cable, characterized in that the terminal box is made of composite metal based on aluminum. 2. A conductometer according to claim 1, characterized in that silumin is used as a composite metal based on aluminum. 3. A conductometer according to claim 2, characterized in that a silumin, for example, of the ADZZ brand, is used.

Description

This utility model relates to a device for measuring the electrical conductivity of liquids and their temperature. Measurement of these parameters, as a rule, is carried out directly at the selected objects.

Conductometers can be used to operate as part of automatic control, measurement and control systems or for autonomous use in nuclear (nuclear power plants - category 4) and thermal energy, chemical, oil, gas, metallurgy, mechanical engineering and other industries, as well as in scientific research institutes and laboratories.

A known industrial conductometer, comprising a unit for controlling the electrical conductivity of a liquid, is equipped with a housing in which a contact cell is made with a sensor consisting of two electrodes. One of the electrodes is formed by a control unit housing made of stainless steel. The second electrode is also implemented in the housing of the control unit. It is installed on a section of the control unit’s body, which is sealed and equipped with input and output nodes, with the help of which they are connected during measurement to an external pipeline with controlled sample. A thermal sensor is also installed in the housing of the control unit, which is in thermal contact with the second electrode and provides a measurement of the temperature of the liquid passing through an external pipeline with a controlled sample.

The conductometer also contains a terminal box made of a special plastic mass - caprolon and connected to the housing of the control unit for the electrical conductivity of the liquid. The conclusions from the second electrode, the temperature sensor, as well as from the housing, which is the first electrode, and containing the controlled parameters, are connected to the connecting elements - the block with contacts located in the terminal box.

The received information about all the monitored parameters from the output of the terminal box is fed through the signal conductors of the information cable to the electronic unit with a digital display that provides measurement of the monitored parameters.

The design of the electronic unit with digital indication is possible in two versions: for panel or wall mounting.

The display of the indicator electronic unit displays all the necessary parameters.

(See ATLANT 1101 industrial conductometer. ATVR. 414311. 100.00.00.00 RE. ATREKO CJSC).

With all the advantages of this conductometer, such as an extended range of measurements of the specific electrical conductivity of the liquid used, monitoring and measuring its temperature during the entire measurement workflow, compactness and detailed study of the individual elements of the device, the latter has the following disadvantages.

The main unit, which provides parameter control, contains a housing in which a sensor is installed, consisting of a contact measuring cell with two electrodes, as well as a temperature sensor.

The block is equipped with a terminal box, structurally combined with the housing and made, as was noted, of caprolon.

With this design, the terminal box in the process of its production requires a significant investment in machine time due to the complexity of its shape. In the terminal box, due to the characteristics of the material, it is necessary to install additional metal reinforcing elements necessary for fixing the structural parts and the box itself. In addition to toto, the terminal box material is less wear-resistant and subject to surface contamination. For this design, it is possible that the sealing of the connection of the terminal box housing to the metal housing of the main unit, in which the sensor electrodes and the temperature sensor are located, is possible. When screwing the terminal box cover, for example, after inspecting the electrode connections to the block, the cover is not skewed in the area of the threaded connection and the latter is violated.

Caprolon is radiolucent, any interference is affected through this material, including such as electric and magnetic fields. Due to the dielectric properties of the terminal box material, it is necessary to apply additional measures to screen weak analogue information signals, that is, to use additional metal shielding elements that do not carry mechanical semantic loads, but perform only the role of an electromagnetic screen.

The signal circuits formed in the block that provides control of the parameters and connected to the corresponding contacts in the block located in the terminal box are affected by external noise, which, as a rule, leads to a decrease in the measurement accuracy. And the screening of signal circuits in this case does not lead to the desired result.

The task, which is aimed by the inventive conductometer, is to eliminate the above disadvantages.

The technical result consists in providing shielding of signal circuits from external interference, improving measurement accuracy, improving mechanical strength and ensuring the tightness and reliability of the connections of the main unit housing with the terminal box housing and the elements contained therein.

The specified technical result in an industrial conductometer containing a unit for controlling the electrical conductivity of a liquid in which a housing made of stainless steel is made, and in the housing of the control unit there is a sensor containing a contact measuring cell consisting of two electrodes, the first of which is the housing of the control unit and the second electrode is located on a section of the housing, which is sealed and connected during operation with an external pipeline with a controlled flow sample, term a sensor in thermal contact with the second electrode and designed to control the temperature of the liquid passing through the external pipeline, a terminal box, the housing of which is structurally combined with the housing of the control unit, and containing connecting elements for connecting the leads from the first electrode, second electrode and temperature sensor to them , an information cable, in which the signal conductors at the input are connected to the connecting elements of the terminal box, and a controlled display measuring unit, in which ormatsionnye inputs connected to outputs of signal conductors data cable, is achieved in that the terminal box is made of a composite aluminum-based metal.

In addition, it is possible a special case of the specified distinguishing feature, which consists in the fact that:

- silumin is used as a composite metal.

- in this case, silumin, for example, grade AD33, was used.

To explain this utility model, the design of the conductivity meter is shown in the drawings of Fig.1 - Fig.3.

Figure 1 shows the control unit of the electrical conductivity of the liquid in the context, its connection with the remaining elements of the conductivity meter and with an external pipeline with a controlled flow-through sample at the selected object.

Figure 2 shows the measuring unit, front view and side view.

Figure 3 is a cross-section along aa of the information cable shown in figure 2.

The conductometer contains a unit 1 for controlling the electrical conductivity of the liquid, in the housing 2 of which is a sensor made in the form of a contact measuring cell consisting of two electrodes.

The first electrode is the housing 2 of the control unit. In order to ensure reliable operation in an aggressive environment, the housing 2 of the control unit is made of stainless steel. Using the first electrode, the constancy of the interelectrode space and the reliability of electrical contact with the flowing sample to be controlled are ensured.

The control unit body 2 is equipped with an input unit 3 and an output unit 4. The input unit 3 is designed to be tightly connected to an external pipe 5 through which a controlled flow sample passes. The output node 4 is also necessary for tight connection to an external pipe 5 with a controlled flow sample, for its exit from the housing 2.

In order to measure the electrical conductivity of the flowing sample, a second electrode 6 is located in the housing 2.

To monitor the temperature of the current measurement of the sample in the housing 2 is installed a temperature sensor 7.

Between the first electrode (housing 2 of the control unit) and the second electrode 6, an insulating element 8 is installed.

To ensure effective control of such a parameter as the electrical conductivity of the flowing sample, the second electrode 6 is located on the section of the housing 2 of the control unit, which is sealed and connected in the process of working with an external pipeline 5 with a controlled flow-through breakdown of the PP. The temperature sensor 7 in this embodiment is in thermal contact with the second electrode 6.

In order to reliably connect the terminals from the first electrode (housing 2), the second electrode 6 and the temperature sensor 7 with the electronic circuit of the device, a terminal box 9 is used.

The terminal box 9 consists of a cover 10 and a housing 11, which are made of composite metal based on aluminum. Aluminum is the base metal in the composition of silumin; it is preferably an Al-Mg-Si alloy having the best casting properties.

As a specific brand, simple silumin was used, for example, of the AD 33 brand.

(See. Industrial aluminum alloys. / Alieva SG, Altman MB and others. 2nd ed. - M., Metallurgy, 1984. P.56-73).

As follows from the information given in this source of information, such an alloy is characterized by good corrosion resistance, mechanical strength, ductility, anodizing ability, and also allows, with this implementation, to improve the sealing of the connection of the cover 10 of the terminal box 9 with its housing 11. Thus, complex the parts that make up the terminal box 9 have a reinforced structure, and the connection of its elements 10 and 11 is reliable and tight.

The terminal box 9, as follows from the drawing of FIG. 1, is structurally aligned with the housing 2. This combination is achieved by mechanical connection of the housing 11 of the terminal box 9, made of an aluminum-based alloy, like the entire terminal box 9, and the housing 2 made from stainless steel.

In the terminal box 9 there are connecting elements made, for example, in the form of a block 12 with contacts to which the terminal 13 of the first electrode is connected, the terminal 14 of the second electrode 6 and the terminal 15 of the temperature sensor 7.

Conclusion 13, a consequence of the design features of the control unit, passes through a sealed section of plastic mass located on the housing 11 of the terminal box 9, and is made with an electric screen.

Fixing the pads 12 relative to the housing 11 of the terminal box 9 in various ways, for example, on racks (not shown).

At the output 16 of the terminal box 9, an input 17 for the information cable 18 is located, the length of which in this design can be up to 15 m.

The information cable 18 contains several signal conductors, which are connected by the corresponding terminals of the sensor and temperature sensor. So, for example, a conductor 19 is connected to a temperature sensor 7, a conductor 20 is connected to a first electrode (housing 2), and a conductor 21 is connected to a second electrode 2. (FIG. 3).

To install the control unit of the electrical conductivity of the liquid in the working position on the housing 2 of the control unit, a strip 22 with holes (Figure 1) is made, fixed on a selected surface (not shown).

Using the information cable 18, the outputs of the second electrode 6, the temperature sensor 7 and the first electrode are connected to the input 23 of the measuring unit 24 (Figure 2).

The measuring unit 24 is located in the housing 25, which can be mounted, as shown, for example, on the shield 26 or mounted using attachments (not shown).

The measuring unit 24 comprises a display 27, on the front panel of which control buttons 28 are installed. The conductometer software allows, following the information on the display 27, to carry out various types of settings and calibrations using the mentioned control buttons 28.

To exclude spurious interference in the measuring system of the conductometer, the information cable 18 is implemented with a screen 29 covered with a plastic protective sheath 30 (Figure 3). This embodiment, in combination with the executed terminal box 9, its connection with the housing 2, provides measurement errors of the controlled parameters at the set level.

Preparing the device for work.

The housing 2 of the unit 1 for controlling the electrical conductivity of the liquid is installed in the working position using the strip 22 with holes (Figure 1).

Connect the input node 3 and the output node 4 to the external pipe 5, through which a controlled flow test should flow (Figure 1). The input and output nodes 3 and 4 are fixed using threaded elements 31.

They control the main information circuits and their connection. This is the second electrode 6, for this purpose terminal 11, the temperature sensor 7 are used, terminal 14 is used for this, and the first electrode is used for terminal 13. The connection of the terminals to the block 12 is controlled.

The control unit 1 and the measuring unit 24 are also connected to the common circuit using the information cable 18. Reliable grounding of all device nodes (not shown) is performed.

The conductivity meter. After applying power, using the control buttons 28, the operating modes of the entire device are checked. Next, the flow of the controlled flow test is provided through the external pipeline 5. After reaching the preset mode, which is displayed on the display 27, periodically control the necessary parameters, also using the display 27.

Due to the implementation of the terminal box parts 9, such as the cover 10 and the housing 11, made of aluminum-based composite metal and in combination with known elements used, reliable operation of the device and effective measurement of the necessary parameters are ensured.

Sources of information taken into account during the examination.

1. Conductivity meter ATLANT 1101. ATVR. 414311. 100.00.00.00 RE. ATREKO CJSC.

2. Industrial aluminum alloys. Directory. / Alieva S.G., Altman M.B. et al. 2nd ed. - M., Metallurgy, 1984.

Claims (3)

1. An ATLANT 1101 industrial conductometer, comprising a liquid conductivity control unit, in which a stainless steel housing is made and an electrical conductivity sensor is located, which includes a contact measuring cell consisting of two electrodes, in which the first electrode is a control unit housing, and the second electrode is located on the portion of the housing of the control unit, which is sealed and connected during operation with an external pipeline with a controlled flow sample, thermo a sensor in thermal contact with the second electrode and designed to control the temperature of the liquid passing through the external pipeline, a terminal box, the housing of which is structurally combined with the housing of the control unit, and containing connecting elements for connecting the terminals of the first electrode, second electrode and temperature sensor to them, information cable, in which the signal conductors at the input are connected to the connecting elements of the terminal box, and a controlled display measuring unit, in which inform The input inputs are connected to the outputs of the signal conductors of the information cable, characterized in that the terminal box is made of composite metal based on aluminum. 2. The conductometer according to claim 1, characterized in that silumin is used as a composite metal based on aluminum. 3. The conductometer according to claim 2, characterized in that a silumin, for example, of the ADZZ brand, is used.

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