KR102187689B1 - Crucible furnace structure for TOC measurement - Google Patents

Abstract

The present invention relates to a crucible furnace structure for TOC measurement. More specifically, the crucible furnace structure comprises a heating housing, a heating pipe, and a heater unit. The structure precisely and stably outputs a TOC measurement value of measurement water.

Description

Crucible furnace structure for TOC measurement

The present invention relates to a crucible furnace structure for TOC measurement, and more particularly, by repeatedly heating a panel that sequentially heats the measured water flowing into the TOC measuring device from a low temperature to a high temperature, The present invention relates to a crucible furnace structure for TOC measurement that does not cause a problem of splashing by heating and can accurately and stably output the total organic carbon measurement value of the measured water.

In general, TOC (Total Organic Carbon) is used as a representative organic material index along with the biochemical oxygen demand (BOD) and the chemical oxygen demand (COD). In particular, interest in TOC is growing because of the difference in oxidation efficiency of each compound and errors resulting from the measurement methods of BOD and COD.

Accordingly, various methods have been developed for TOC analysis, and the prior art for such TOC analysis is Patent No. 10-1161861 『Total Organic Carbon Measurement Device and Method』 and Patent No. 10-1274830 『Dissolved Organic Carbon. There is a measurement device”, and “Total organic carbon measurement device and its method” in the prior art registration patent No. 10-1161861 is a material supply unit for supplying substances required for transport and oxidation reactions, and measurement water supplying the collected measurement water. A reaction for generating carbon dioxide by reacting a supply unit, a reagent supply unit for supplying reagents necessary for the oxidation reaction, the gas supplied from the substance supply unit, the measurement water supplied from the measurement water supply unit, and the reaction reagent supplied from the reagent supply unit in a reaction tank A total organic carbon measuring apparatus and a method thereof including a concentration measuring unit for measuring total organic carbon by measuring the concentration of carbon dioxide generated in the unit and the reaction unit are provided.

However, there is a problem in that the measurement water is heated by a high-temperature furnace during the process of introducing the measurement water into the furnace and crucible of the conventional TOC measurement device, and the measurement water is heated and splashed. There is this.

The above-described invention refers to the background technology in the technical field to which the present invention belongs, and does not mean the prior art.

Registered Patent No. 10-1274830

The present invention was conceived to solve the above-described conventional problem, and an object of the present invention is to repeatedly heat a panel that sequentially heats the measured water flowing into the TOC measuring device from a low temperature to a high temperature. The purpose of this is to provide a crucible furnace structure for TOC measurement that does not cause the problem of rapid heating and splashing when water is introduced, and capable of accurately and stably outputting the total organic carbon measurement value of the measured water.

The present invention is a TOC measuring crucible furnace structure configured to heat the incoming measurement water, a heating housing having an operating space formed therein, a heating pipe installed passing through the heating housing and receiving and heating the measurement water, A heater unit for heating the heating pipe, wherein the heating housing is further provided with an elevating heating temperature control unit to adjust the temperature after sensing the temperature of the heating unit of the heater unit heating the heating pipe, and the The elevating heating temperature control means comprises an elevating cylinder fixed by connecting a lower end to the inner bottom of the heating housing, and a sensing bracket and a blowing bracket that are elevated by the driving of the elevating cylinder and fixed to the elevating shaft of the elevating cylinder. A bracket part, a temperature sensor installed in the detection bracket and elevated by driving of the lifting cylinder, and a temperature sensing sensor that senses the temperature of the heating units, and a temperature sensor installed in the blowing bracket to be elevated by driving the lifting cylinder, and the It is characterized by consisting of a blower fan that supplies wind to the heating unit.

In addition, the heater unit is formed of heating wire units installed while surrounding the heating pipe path of the heating housing, and the heating wire units are formed while maintaining a predetermined interval along the length direction of the heating pipe path.

In addition, the heater unit maintains the heating temperature of the heating wire unit disposed at the central portion of the heating pipe line higher than the heating temperature of the heating wire units disposed at both ends of the heating pipe line, and an annular heat dissipation panel is provided above the heating housing. It characterized in that it is provided more.

In addition, the heating pipe is characterized in that the alumina pipe is further fitted therein.

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The crucible furnace structure for TOC measurement of the present invention repeatedly heats a panel that sequentially heats the measured water flowing into the OC measuring device from a low temperature to a high temperature, so that when the measured water flows in, it is rapidly heated and splashed. There is an effect of being able to accurately and stably output the measured total organic carbon of the number of measurements.

1 is a front view showing a crucible furnace structure for measuring TOC according to the present invention.
2 is a cross-sectional view showing a crucible furnace structure for measuring TOC according to the present invention.
Figure 3 is an operational state diagram showing the TOC measurement crucible furnace structure according to the present invention.
4 is a cross-sectional view showing another embodiment of the crucible furnace structure for measuring TOC according to the present invention.
5 is an operational state diagram showing another embodiment of a crucible furnace structure for measuring TOC according to the present invention.
6 is a partially enlarged view showing another embodiment of a crucible furnace structure for measuring TOC according to the present invention.
7 is a cross-sectional view showing another embodiment of a crucible furnace structure for measuring TOC according to the present invention.
8 is an operational state diagram showing another embodiment of the crucible furnace structure for measuring TOC according to the present invention.

Hereinafter, a preferred embodiment of a TOC measuring crucible furnace structure according to the present invention will be described with reference to the accompanying drawings. In this process, the thickness of the lines or the size of components shown in the drawings may be exaggerated for clarity and convenience of description. In addition, terms to be described later are terms defined in consideration of functions in the present invention and may vary according to the intention or custom of users or operators. Therefore, definitions of these terms should be made based on the contents throughout the present specification.

In addition, the following examples are not intended to limit the scope of the present invention, but are presented merely as examples, and there may be various embodiments implemented through the present technical idea.

1 is a front view showing a TOC measurement crucible furnace structure according to the present invention. 2 is a cross-sectional view showing a crucible furnace structure for measuring TOC according to the present invention. Figure 3 is an operational state diagram showing the TOC measurement crucible furnace structure according to the present invention. 4 is a cross-sectional view showing another embodiment of a crucible furnace structure for measuring TOC according to the present invention. 5 is an operational state diagram showing another embodiment of the crucible furnace structure for measuring TOC according to the present invention. 6 is a partially enlarged view showing another embodiment of a crucible furnace structure for measuring TOC according to the present invention. 7 is a cross-sectional view showing another embodiment of a crucible furnace structure for measuring TOC according to the present invention. 8 is an operational state diagram showing another embodiment of the crucible furnace structure for measuring TOC according to the present invention.

As shown in the drawing, the present inventor's TOC measuring crucible furnace structure 10 (hereinafter referred to as a crucible furnace structure for convenience of description) is a TOC measuring crucible furnace structure 10 configured to heat the incoming measurement water. Such a furnace structure 10 is composed of a heating housing 20, a heating pipe 30, and a heater 40.

The heating housing 20 has a working space therein.

The heating housing 20 is formed of a metal material or a synthetic resin material, and any material may be used as long as it is made of a material having heat resistance.

The heating housing 20 is formed in a rectangular housing structure, and may be formed in various shapes and shapes in which an operating space is provided therein.

The heating housing 20 is provided inside the TOC measuring device to heat the measured water flowing into the heating pipe 30.

The heating pipe 30 is installed while passing through the heating housing 20, receives the measured water, and heated by the heater 40 to the measured water moved through the heating pipe 30.

The heating pipe 30 is formed of quartz or a glass material and a metal material, and passes through the top panel and the bottom panel of the heating housing 20 of the heating housing 20 and is attached or screwed to the heating housing 20. ) Is fixed.

The heater unit 40 heats the heating pipe 30.

The heater part 40 is composed of heating wire units 41 installed while surrounding the heating pipe 30 of the heating housing 20, and the heating wire units 41 are the heating pipe 30 as shown in the drawing. It is formed while maintaining a certain interval along the length direction of ).

The heating units 41 are connected to an external power supply unit or a control unit connected to the power supply unit to generate heat by receiving electricity from the power supply unit.

The heating wire unit 41 is disposed with one end surrounding the heating pipe 30, and the other end passes through the heating housing 20 and is electrically connected to the power supply unit.

At this time, one end of the heating wire unit 41 surrounds the heating pipe 30 in a coil shape.

The heating wire unit 41 is fixed by friction or pressure after wrapping one end while contacting the heating pipe 30 and fixing it by bonding or fusion bonding. Alternatively, it is also possible to arrange the heating pipe 30 to maintain a predetermined distance.

It is also possible to support the heating wires by screwing support brackets on the inner surface of the heating housing 20.

The furnace structure 10 is disposed inside the TOC measuring device, and the measured water flowing into the heating pipe 30 is heated by the heater unit 40 to oxidize organic carbons in the measured water at a high temperature to produce carbon dioxide ( After conversion into CO2), the heating pipe 30 is heated as described above so that TOC can be measured by measuring the concentration of this CO2.

At this time, the TOC measuring device is a device that measures TOC by oxidizing organic carbons in the measured water collected for total organic carbon (TOC) measurement at high temperature and converting them to carbon dioxide (CO2), and then measuring the concentration of this CO2. , It is a high-temperature reactor that converts organic carbon in measured water to CO2 by promoting oxidation at high temperature.

The heater unit 40 maintains the heating temperature of the heating unit 41 disposed at the central portion of the heating pipe 30 higher than the heating temperature of the heating unit 41 disposed at both ends of the heating pipe 30 The heat dissipation panel 21 of an annular shape is further provided on the heating housing 20 so as to pass through the heating pipe 30 and disposed on the upper surface of the heating housing 20.

That is, it is possible to discharge the heat of the heating housing 20 to the outside by the heat dissipation panel 21, and the heating temperature of the heating unit 41 disposed at both ends of the heating pipe 30 is disposed in the center. By keeping the heating temperature lower than the heating temperature of the heating wire unit 41, the measured water flowing into the heating pipe part can be sequentially heated, vaporized and oxidized, so that the measured water flows into the heating pipe 30 and splashed by the heat. Can be prevented.

In the heating pipe 30, an alumina pipe portion 50 is further inserted therein to guide the measured water to be heated and can be stably dispersed.

The heating housing 20 is further provided with an elevating heating temperature control means 60 to adjust the temperature after sensing the temperature of the heating units 41 of the heater unit 40 for heating the heating pipe 30 do.

The elevating heating temperature control means (60) is screwed or welded to an elevating cylinder (61) having a lower end screwed and fixed to the inner bottom of the heating housing (20), and the elevating shaft of the elevating cylinder (61). It is fixed, the bracket part 62 consisting of a detection bracket 621 and a ventilation bracket 622 that are raised and lowered by the driving of the lifting cylinder 61, and the detection bracket 621 is fixed by screwing to the lifting and lowering A temperature sensing sensor 63 that is elevated by the driving of the cylinder 61 and senses the temperature of the heating unit 41, and is fixed to the blowing bracket 622 by screwing the lifting cylinder 61. It is elevated by driving and consists of a blower pen 64 that supplies wind to the heating unit 41, and the temperature sensor 63 senses the temperature of the heating unit 41 and then the heating unit 41 ), when a heating unit 41 having a temperature higher than a set temperature is detected, the signal is transmitted to the elevator cylinder 61 and the blowing pen 64 faces or closes to the detected heating unit 41 Then, by driving the blower pen 64 in response to a signal from the temperature sensor 63 to lower the temperature of the detected twisted pair unit to a set temperature, it is possible to prevent splashing while the measured water is heated.

Alternatively, the heating cylinder 61 is continuously driven so that the temperature sensor increases and descends along the heating pipe 30 to measure the temperature of the heating wire units 41 and overheated the heating wire unit 41 It is also possible to cool them with the blower pen 64.

The temperature sensor 63 may be screwed to the inner surface of the heating housing 20 to be fixed.

In addition, one end of an elastic radiating coil spring is welded to the lifting shaft of the lifting cylinder 61, and one end of a radiating fin is welded to the other end of the elastic radiating coil spring, and the elastic radiating coil spring and It is preferable that the heat dissipation fins are moved so that the ends of the heat dissipation fins come into contact with the overheated heating wire unit 41 so as to radiate heat and cool them. It is preferable to prevent the heat radiation fins from being bent when they are caught by the heating wire units 41 in the process of ascending and descending due to the elasticity of the elastic radiation coil spring.

Here, by further screwing or welding a vibrator, which is a vibrator, to the heating housing 20, the vibration of the vibrator is transmitted to the heating pipe 30 to prevent oxidized impurities sticking to the inner surface of the heating pipe 30 or It is desirable to prevent foreign substances and water droplets from being removed, as well as to prevent friction or jamming during the movement of the singi heat control pipe.

One embodiment of the present invention described above is merely exemplary, and those of ordinary skill in the technical field to which the present invention belongs will appreciate that various modifications and other equivalent embodiments are possible. . Therefore, it will be appreciated that the present invention is not limited to the form mentioned in the detailed description above. Therefore, the true technical protection scope of the present invention should be determined by the technical spirit of the appended claims. In addition, the present invention is to be understood as including the spirit of the present invention as defined by the appended claims and all modifications, equivalents and substitutes within the scope thereof.

10: furnace structure
20: heating housing
21: heat dissipation panel
30: heating pipe furnace
40: heater part
41: heating unit
50: alumina tube
60: elevating heating temperature control means
61: lifting cylinder
62: bracket
621: detection bracket
622: ventilation bracket
63: temperature sensor
64: blower pen

Claims (5)

This is a crucible furnace structure for TOC measurement to heat the incoming measurement water,
A heating housing having an operating space formed therein;
A heating pipe installed passing through the heating housing and receiving and heating the measured water; And
Including; a heater for heating the heating pipe,
The heating housing is further provided with an elevating heating temperature control means to adjust the temperature after sensing the temperature of the heating wire units of the heater unit heating the heating pipe,
The elevating heating temperature control means,
An elevating cylinder that is fixed by connecting a lower end to the inner bottom of the heating housing,
A bracket part consisting of a sensing bracket and a blowing bracket that are fixed to the lifting shaft of the lifting cylinder and lifted by the driving of the lifting cylinder,
A temperature sensing sensor installed on the sensing bracket and elevated by driving of the lifting cylinder, and sensing the temperature of the heating units,
A crucible furnace structure for measuring TOC, characterized in that it is installed on the blowing bracket, is elevated by driving of the lift cylinder, and comprises a blowing fan that supplies wind to the heating unit.
The method of claim 1,
The heater part is made of heating wire units installed while surrounding the heating pipe of the heating housing,
The heating wire unit is a crucible furnace structure for measuring TOC, characterized in that formed while maintaining a predetermined interval along the length direction of the heating pipe.
The method of claim 1,
The heater unit maintains the heating temperature of the heating wire unit disposed at the central portion of the heating pipe line higher than the heating temperature of the heating wire unit disposed at both ends of the heating pipe line,
A crucible furnace structure for measuring TOC, characterized in that an annular heat dissipation panel is further provided on the upper part of the heating housing.
The method of claim 1,
A crucible furnace structure for TOC measurement, characterized in that an alumina tube part is further inserted into the heating pipe.
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