JP3214208U - Electric furnace and analyzer equipped with the same - Google Patents

Abstract

An electric furnace that can be used for both 100V and 200V power supply voltages and an analyzer equipped with the electric furnace are provided. An electric furnace includes two heating elements (511, 512), a power input unit (52), and a relay (53). The two heating elements 511 and 512 have equivalent resistance values. A power supply 50 for the two heating elements 511 and 512 is input to the power input unit 52. The relay 53 switches the connection state to either the state in which the two heat generating elements 511 and 512 are connected in series or the state in which the power supply input unit 52 is connected in parallel. [Selection] Figure 2A

Description

  The present invention relates to an electric furnace for heating an object with a heating element, and an analyzer equipped with the electric furnace.

  For example, total organic carbon (TOC) measuring device for measuring total organic carbon (TOC) contained in various samples in addition to environmental water such as river water, lake water, marine water, rain water or ground water Is known (see, for example, Patent Document 1 below).

  The total organic carbon measuring device includes a total carbon measuring device for measuring total carbon (TC) and an inorganic carbon measuring device for measuring inorganic carbon (IC). It has been. Based on the total carbon measured by the total carbon measuring device and the inorganic carbon measured by the inorganic carbon measuring device, the total organic carbon contained in the sample can be measured.

  The total carbon measuring device is provided with a combustion section for burning the sample, and the total carbon contained in the sample is measured by detecting the carbon dioxide generated by the combustion in the combustion section with the gas detection section. be able to. Further, the inorganic carbon measuring device is provided with a reaction unit for heating the sample to which the acid solution is added, and by detecting the carbon dioxide generated by the reaction in the reaction unit by the gas detection unit, The inorganic carbon contained in the sample can be measured.

  An electric furnace for heating the sample is provided in each of the combustion unit of the total carbon measurement device and the reaction unit of the inorganic carbon measurement device. The temperature of the electric furnace provided in the combustion part of the total carbon measuring device is set to 900 ° C., for example. On the other hand, the temperature of the electric furnace provided in the reaction part of the inorganic carbon measuring device is set to 200 ° C., for example.

JP 2014-132236 A

  The electric furnace as described above may be used with a 100V system power supply voltage or with a 200V system power supply voltage. Here, the power supply voltage of 100V system means a power supply voltage close to 100V, and the power supply voltage of 200V system means a power supply voltage close to 200V.

  For example, in Japan, a 100V AC power supply is generally used as a household power supply, but a 200V AC power supply may be used when large power is required or in a factory. In China and Korea, a 220V AC power supply (200V system) is used. In Taiwan, a 110V AC power supply (100V system) is used in addition to 220V. In Europe, a 220V or 230V AC power supply (200V system) is mainly used, and in the United States, a 115V AC power supply (100V system) is used in addition to 230V.

  In order to be able to heat an object with the same amount of heat regardless of whether the power supply voltage is a 100V system or a 200V system, conventionally, an electric furnace provided with a heating element having a different resistance value for each power supply voltage is prepared. Had to do. In addition, when a power supply voltage of 200 V system is applied to an electric furnace corresponding to the 100 V system, there is a risk that the heating element will burn out. These problems are not only limited to the total organic carbon measuring apparatus but also occur similarly in electric furnaces used in other analytical apparatuses.

  The present invention has been made in view of the above circumstances, and an object of the present invention is to provide an electric furnace that can be shared by 100V and 200V power supply voltages and an analyzer equipped with the electric furnace. Another object of the present invention is to provide an electric furnace capable of preventing a heating element from being burned out by applying an incorrect power supply voltage, and an analyzer equipped with the electric furnace.

  The electric furnace according to the present invention includes two heating elements, a power input unit, and a switching unit. The two heating elements have equivalent resistance values. A power source for the two heating elements is input to the power input unit. The switching unit switches the connection state to either the state where the two heating elements are connected in series or the state where they are connected in parallel to the power input unit.

  According to such a configuration, the connection state of the two heating elements with respect to the power input unit can be switched in series or in parallel by the switching unit. The resistance value when two heating elements are connected in series is about four times the resistance value when two heating elements are connected in parallel. Therefore, when a 100V power supply is input to the power input unit, two heating elements are connected in parallel to the power input unit, and a 200V power supply is input to the power input unit. The object can be heated with an equivalent amount of heat by setting the two heating elements connected in series to the power input section. Therefore, by switching the connection state of the two heating elements with respect to the power input unit by the switching unit, the electric furnace can be shared for the 100V system and 200V system power supply voltages.

  The electric furnace may further include a voltage detection unit that detects a voltage of a power source input to the power input unit. In this case, the switching unit may switch the connection state of the two heating elements to the power input unit based on a detection result by the voltage detection unit.

  According to such a configuration, the voltage of the power source input to the power input unit is detected by the voltage detection unit, and based on the detection result, the connection state of the two heating elements to the power input unit is automatically serially or in parallel. Can be switched. Therefore, it is possible to prevent the heating element from being burned out by applying an incorrect power supply voltage.

  An analyzer according to the present invention includes the electric furnace. The analyzer may include a total carbon measurement device, an inorganic carbon measurement device, and a total organic carbon calculation processing unit. The total carbon measuring device measures total carbon. The inorganic carbon measuring device measures inorganic carbon. The total organic carbon calculation processing unit calculates the total organic carbon contained in the sample based on the total carbon measured by the total carbon measuring device and the inorganic carbon measured by the inorganic carbon measuring device. calculate. In this case, the electric furnace may be provided in at least one of the total carbon measuring device and the inorganic carbon measuring device.

  According to the present invention, by switching the connection state of the two heating elements to the power input unit by the switching unit, it is possible to share the electric furnace for the 100V system and 200V system power supply voltages. Moreover, if the connection state of the two heat generating elements to the power input unit is automatically switched in series or in parallel, it is possible to prevent the heat generating elements from being burned out by applying an incorrect power supply voltage.

It is the schematic which showed the structural example of the analyzer which concerns on one Embodiment of this invention. It is a circuit diagram showing an example of the concrete composition of an electric furnace, and shows the state where two heating elements were connected in parallel. It is a circuit diagram showing an example of the concrete composition of an electric furnace, and shows the state where two heating elements were connected in series. It is the block diagram which showed the structural example of the control part which controls operation | movement of the analyzer of FIG. It is the flowchart which showed an example of the process by a switching process part.

1. Overall Configuration of Analyzer FIG. 1 is a schematic diagram showing a configuration example of an analyzer according to an embodiment of the present invention. This analyzer is a total organic carbon measuring device for measuring total organic carbon (TOC) contained in a sample.

  This total organic carbon measuring device includes a total carbon measuring device 1 and an inorganic carbon measuring device 2, and the total carbon (TC) measured by the total carbon measuring device 1 and the inorganic carbon measuring device. The total organic carbon contained in the sample can be measured based on inorganic carbon (IC: Inorganic Carbon) measured by 2. The TOC can be calculated using a relational expression of TOC = TC-IC.

  The total carbon measuring apparatus 1 includes, for example, a sample setting unit 102 for setting a sample boat 101 on which a sample is placed, and a combustion unit 103 for burning a sample on the sample boat 101 inserted from the sample setting unit 102. Is provided. The sample boat 101 can be formed of, for example, ceramic, but is not limited to this, and can be formed of other various materials having heat resistance.

  The sample installation unit 102 is provided with a cover 121 that can be opened and closed, and the sample boat 101 can be installed in the sample installation unit 102 with the cover 121 opened. The sample boat 101 installed in the sample installation unit 102 can be inserted into the combustion unit 103 by moving a moving rod 122 provided in the sample installation unit 102.

  The combustion unit 103 includes, for example, a cylindrical electric furnace 131 that is disposed sideways, and a hard glass combustion tube 132 that is disposed in the electric furnace 131. The sample boat 101 moved by the moving rod 122 from the sample setting unit 102 is inserted into the combustion tube 132 in the combustion unit 103. The temperature of the electric furnace 131 is set to 900 ° C., for example, so that the sample on the sample boat 101 inserted into the combustion tube 132 can be burned.

  The combustion tube 132 is filled with, for example, an oxidation catalyst 133. The organic matter contained in the sample on the sample boat 101 inserted into the combustion tube 132 is oxidized by the action of the oxidation catalyst 133, and carbon dioxide corresponding to the amount of the organic matter contained in the sample is generated. A carrier gas that also functions as a combustion support gas is supplied into the sample placement unit 102 via a cover 121. The carrier gas is continuously supplied at a flow rate of 500 mL / min, for example. Carbon dioxide generated in the combustion pipe 132 is sent to the cooling pipe 104 together with the carrier gas, cooled in the cooling pipe 104, and then sent to the drain separator 3 through the gas flow path 105.

  The inorganic carbon measuring apparatus 2 includes, for example, a sample setting unit 202 for setting a sample boat 201 on which a sample is placed, and a reaction unit 203 for heating a sample on the sample boat 201 inserted from the sample setting unit 202. And an acid solution addition unit 204 for adding an acid solution to the sample on the sample boat 201. The sample boat 201 can be formed of, for example, ceramic, but is not limited to this, and can be formed of other various materials having heat resistance.

  The sample installation unit 202 is provided with an openable / closable cover 221, and the sample boat 201 can be installed in the sample installation unit 202 with the cover 221 opened. The sample boat 201 installed in the sample installation unit 202 can be inserted into the reaction unit 203 by moving a moving rod 222 provided in the sample installation unit 202.

  The reaction unit 203 includes, for example, a cylindrical electric furnace 231 arranged sideways and a hard glass reaction tube 232 arranged in the electric furnace 231. The sample boat 201 moved by the moving rod 222 from within the sample setting unit 202 is inserted into the reaction tube 232 in the reaction unit 203. The temperature of the electric furnace 231 is set to 200 ° C., for example, and the sample on the sample boat 201 inserted into the reaction tube 232 can be heated.

  The acid solution adding unit 204 includes a dispenser 241 that can discharge an acid solution, for example. The discharge port of the dispenser 241 communicates with the inside of the sample setting unit 202 via the cover 221 of the sample setting unit 202. When the sample boat 201 is installed at a specified position in the sample installation unit 202 and the cover 221 is closed, the dispenser 241 is driven to add (drop) the acid solution to the sample on the sample boat 201. be able to.

  After the acid solution is added to the sample as described above, the sample boat 201 is inserted into the reaction tube 232 of the reaction unit 203. The sample on the sample boat 201 inserted into the reaction tube 232 reacts with the acid solution, and carbon dioxide corresponding to the amount of inorganic carbon contained in the sample is generated. As the acid solution, phosphoric acid which is an example of a nonvolatile acid can be used, but the acid solution is not limited thereto.

  The inorganic carbon measuring device 2 is connected in series to the all-carbon measuring device 1 described above via the drain separator 3 and the gas flow path 205. As a result, the carrier gas supplied to the total carbon measuring device 1 can be supplied to the inorganic carbon measuring device 2 via the drain separator 3 and the gas flow path 205.

  In the inorganic carbon measuring device 2, the carrier gas sent from the total carbon measuring device 1 is supplied into the sample placement unit 202 via the cover 221. The carbon dioxide generated in the reaction tube 232 is sent to the drain separator 3 through the gas flow path 206 together with the carrier gas sent as described above.

  A gas detector 4 for detecting carbon dioxide is connected to the drain separator 3. Although the gas detection part 4 can be comprised by the infrared type carbon dioxide detector, for example, it is not restricted to this. When measuring the total carbon, carbon dioxide generated by burning the sample in the combustion tube 132 of the total carbon measuring device 1 is sent to the gas detection unit 4 together with the carrier gas. By detecting, the total carbon contained in the sample can be measured. On the other hand, when measuring inorganic carbon, carbon dioxide generated by reacting the sample in the reaction tube 232 of the inorganic carbon measuring device 2 is sent to the gas detection unit 4 together with the carrier gas, and the gas detection unit 4 By detecting carbon dioxide with, inorganic carbon contained in the sample can be measured.

  In this embodiment, the combustion unit 103 of the total carbon measurement device 1 and the reaction unit 203 of the inorganic carbon measurement device 2 constitute a heating unit for heating the sample. Gas (carbon dioxide) generated from the sample during heating in the heating unit (combustion unit 103 and reaction unit 203) flows to the gas detection unit 4 via the gas flow paths 105, 205, and 206, and the gas detection unit 4 Will be detected.

  The drain separator 3 has a gas flow from the first separation unit 31 through which the gas sent from the combustion unit 103 of the total carbon measurement device 1 through the gas flow path 105 passes and from the reaction unit 203 of the inorganic carbon measurement device 2. And a second separation unit 32 through which the gas sent through the path 206 passes. In each separation part 31, 32, moisture contained in the gas is separated from the gas, and moisture is recovered into the drain pot 33 from the openings 311, 321 provided at the lower part of each separation part 31, 32. ing.

  The drain pot 33 constitutes a liquid storage part in which a liquid 34 such as water is stored. The drain pot 33 has an opening 311 of the first separation part 31 formed so as to open a middle part of the gas flow path 105 and a second separation formed so as to open a middle part of the gas flow path 206. The gas flow paths 105 and 206 are communicated with each other through the opening 321 of the part 32. In the drain pot 33, the liquid 34 is stored up to a position higher than the openings 311, 321, whereby the openings 311, 321 are arranged in the liquid stored in the drain pot 33. It has become.

2. Specific Configuration of Electric Furnace FIGS. 2A and 2B are circuit diagrams illustrating an example of a specific configuration of the electric furnaces 131 and 231. Each electric furnace 131, 231 includes a heating element 51, a power input part 52, and a relay 53. The electric furnaces 131 and 231 are heated when the power supply 50 is input. As the power supply 50, a 100V AC power supply whose power supply voltage is close to 100V or a 200V AC power supply whose power supply voltage is close to 200V is used. A power supply voltage of 50V or more and less than 150V is applied from the 100V system power supply 50, and a power supply voltage of 150V or more and less than 250V is applied from the 200V system power supply 50.

  As the heating element 51, two heating elements 511 and 512 having equivalent resistance values are used. The power supply 50 for these two heating elements 511 and 512 is input to the power input unit 52. The power input unit 52 can be attached to and detached from the power source 50 such as an outlet (plug socket), and is shared by the 100 V and 200 V power sources 50.

  As the relay 53, two relays 531 and 532 are provided in the middle of the wiring connecting the power input unit 52 and the two heating elements 511 and 512. By switching these relays 531 and 532, a state in which the two heating elements 511 and 512 are connected in parallel to the power input unit 52 (the state shown in FIG. 2A), or the two heating elements 511 and 512 are connected in series. The connection state can be switched to any one of the states connected to (the state of FIG. 2B).

Assuming that the resistance value of each of the heating elements 511 and 512 is R, in the state of FIG. 2A in which these heating elements 511 and 512 are connected in parallel to the power input unit 52, the resistance value of each heating element 511 and 512 is The total value r _A is represented by the following formula (1). From this equation (1), the total value r _A of the resistance values of the heating elements 511 and 512 is r _A = R / 2.
1 / r _A = 1 / R + 1 / R = 2 / R (1)

On the other hand, in the state of FIG. 2B in which the two heating elements 511 and 512 are connected in series to the power input unit 52, the total resistance value r _B of the heating elements 511 and 512 is expressed by the following equation (2). Is done. Thus, the total value r _B (= 2R) of the resistance values of the heating elements 511 and 512 in a state where the two heating elements 511 and 512 are connected in series to the power input unit 52 (the state shown in FIG. 2B). The total value r _A (= R / 2) of the resistance values of the heating elements 511 and 512 in a state where the two heating elements 511 and 512 are connected in parallel to the power input section 52 (state shown in FIG. 2A). Will be 4 times.
r _B = R + R = 2R (2)

The amount of heat W generated in each electric furnace 131, 231 by the two heating elements 511, 512 is expressed by the following formula (3). r is a sum of the resistance values of the heating elements 511 and 512, the _{r A} next if the heating elements 511 and 512 are connected in parallel, connecting the heating elements 511 and 512 in series the said r _B is if it is.
W = V ² / r (3)

Therefore, when the voltage of the power source 50 input to the power input unit 52 is 100 V, the two heating elements 511 and 512 are connected in parallel to the power input unit 52 (the state shown in FIG. 2A). The amount of heat W is calculated as follows using the above equation (3).
W = 100 ² / r _A = 100 ² / (R / 2) = 2 × 100 ² / R

On the other hand, when the voltage of the power source 50 input to the power input unit 52 is 200 V, the two heating elements 511 and 512 are connected in series to the power input unit 52 (the state shown in FIG. 2B). The amount of heat W is calculated as follows using the above equation (3).
W = 200 ² / r _B = 200 ² / 2R = 2 × 100 ² / R

  As described above, when the 100V power source 50 is input to the power input unit 52, the two heating elements 511 and 512 are connected in parallel to the power input unit 52, and the 200V power source 50 is connected. Is input to the power input unit 52, the two heating elements 511 and 512 are connected in series to the power input unit 52, thereby heating the object with an equivalent amount of heat W. Can do. Therefore, by switching the connection state of the two heat generating elements 511 and 512 to the power input unit 52 with the relay 53, it is possible to share the electric furnaces 131 and 231 for the 100V system power supply voltage and the 200V system power supply voltage.

3. Electrical Configuration of Control Unit FIG. 3 is a block diagram illustrating a configuration example of the control unit 10 that controls the operation of the analyzer of FIG. The control unit 10 includes, for example, a CPU (Central Processing Unit), and when the CPU executes a program, the switching processing unit 11, the total carbon measurement processing unit 12, the inorganic carbon measurement processing unit 13, and the total organic substance. It functions as various functional units such as the carbon calculation processing unit 14.

  The analyzer according to the present embodiment includes a voltage detection unit 54 that detects the voltage of the power supply 50 input to the power supply input unit 52. The voltage detection unit 54 can detect whether the power source 50 input to the power input unit 52 is a 100V system or a 200V system. The voltage detection unit 54 may be provided in the power input unit 52 or may be provided in the middle of the wiring connecting the power input unit 52 and the two heating elements 511 and 512.

  The switching processing unit 11 performs processing for switching the connection state of the two heating elements 511 and 512 to the power input unit 52 based on the detection result by the voltage detection unit 54. Specifically, when the power supply 50 input to the power supply input unit 52 is 100V system, the switching processing unit 11 sets the relay 53 to the state shown in FIG. 2A, and when the power supply 50 input to the power supply input unit 52 is 200V system. The switching processing unit 11 puts the relay 53 in the state shown in FIG. 2B. The switching processing unit 11 and the relay 53 constitute a switching unit for switching the connection state of the two heating elements 511 and 512 with respect to the power input unit 52.

  Thus, in this embodiment, the voltage of the power supply 50 input to the power supply input unit 52 is detected by the voltage detection unit 54, and the two heating elements 511 and 512 for the power supply input unit 52 are detected based on the detection result. The connection state can be automatically switched in series or in parallel. Therefore, it is possible to prevent the heating elements 511 and 512 from being burned out by applying an incorrect power supply voltage.

  The total carbon measurement processing unit 12 is for controlling the operation of the total carbon measurement device 1 and includes, for example, a combustion processing unit 15. The combustion processing unit 15 moves the moving rod 122 of the sample setting unit 102 to move the sample boat 101 in the sample setting unit 102 into the combustion tube 132 of the combustion unit 103, thereby causing the combustion processing unit 15 to move within the combustion tube 132. The sample on the sample boat 101 is burned.

  The inorganic carbon measurement processing unit 13 is for controlling the operation of the inorganic carbon measurement device 2, and includes, for example, an addition processing unit 16 and a heat processing unit 17. The addition processing unit 16 controls the operation of the acid solution addition unit 204 to discharge the acid solution from the dispenser 241, thereby causing the acid solution to be applied to the sample on the sample boat 201 installed in the sample installation unit 202. Add. The heat processing unit 17 moves the moving rod 222 of the sample setting unit 202 to move the sample boat 201 in the sample setting unit 202 into the reaction tube 232 of the reaction unit 203, thereby causing the reaction tube 232 to move inside the reaction tube 232. The sample on the sample boat 101 is heated.

  The total organic carbon calculation processing unit 14 performs processing for calculating the total organic carbon (TOC) contained in the sample based on the detection result in the gas detection unit 4. That is, the total carbon (TC) detected by the gas detection unit 4 during measurement by the total carbon measurement device 1 and the inorganic carbon (IC) detected by the gas detection unit 4 during measurement by the inorganic carbon measurement device 2 Based on the relational expression of TOC = TC-IC, total organic carbon (TOC) contained in the sample is calculated.

4). Processing by Switching Processing Unit FIG. 4 is a flowchart showing an example of processing by the switching processing unit 11. By connecting the power supply input unit 52 to the power supply 50, when there is an input from the power supply 50 (Yes in step S101), the voltage of the power supply 50 is detected by the voltage detection unit 54 (step S102).

  In this example, if the detected power supply voltage is less than the threshold value (Yes in step S103), the switching processing unit 11 sets the relay 53 to the state shown in FIG. 2A so that the two heating elements 511 and 512 are connected to the power input unit. 52 is connected in parallel to step 52 (step S104). On the other hand, if the detected power supply voltage is equal to or higher than the threshold value (No in step S103), the switching processing unit 11 places the relay 53 in the state shown in FIG. 2B so that the two heating elements 511 and 512 are connected to the power input unit 52. On the other hand, they are connected in series (step S105).

  The threshold is a value larger than 100V and smaller than 200V. The threshold is preferably about 150V, but is not limited to this. If the threshold value is appropriately set between 100V and 200V, the two heating elements 511 and 512 are connected in parallel to the power input unit 52 when the power supply voltage is 100V, and the power supply voltage is 200V. The two heating elements 511 and 512 are connected in series to the power input unit 52. However, as the threshold value, a threshold value for detecting a 100V power supply voltage and a threshold value for detecting a 200V power supply voltage may be set individually. Further, the threshold value may be set to an arbitrary value.

5. Modifications In the above embodiment, the configuration in which the connection state of the two heating elements 511 and 512 with respect to the power input unit 52 is automatically switched based on the detection result by the voltage detection unit 54 has been described. However, the configuration is not limited to such a configuration, and a configuration in which switching by the switching unit is manually performed may be employed.

  Moreover, in the above embodiment, the structure provided with the switch part as shown to FIG. 2A and FIG. 2B in both the electric furnace 131 of the total carbon measuring apparatus 1 and the electric furnace 231 of the inorganic carbon measuring apparatus 2 is demonstrated. did. However, the configuration is not limited to this, and a configuration in which the switching unit is provided only in one of the electric furnace 131 of the total carbon measuring device 1 or the electric furnace 231 of the inorganic carbon measuring device 2 may be used.

  Furthermore, although the above embodiment demonstrated the case where the electric furnace which concerns on this invention was applied to the total organic carbon measuring device, this invention is not limited to a total organic carbon measuring device, but also to other analyzers. Applicable. In this case, the target object heated by the electric furnace is not limited to the sample, but may be another target object used for analysis.

DESCRIPTION OF SYMBOLS 1 Total carbon measurement apparatus 2 Inorganic carbon measurement apparatus 4 Gas detection part 10 Control part 11 Switching process part 12 Total carbon measurement process part 13 Inorganic carbon measurement process part 14 Total organic carbon calculation process part 15 Combustion process part 16 Addition process Unit 17 Heat Treatment Unit 50 Power Supply 51 Heating Element 52 Power Supply Input Unit 53 Relay 54 Voltage Detection Unit 103 Combustion Unit 131 Electric Furnace 203 Reaction Unit 231 Electric Furnace 511, 512 Heating Element 531 532 Relay

Claims (4)

Two heating elements having equivalent resistance values;
A power input unit for inputting power to the two heating elements;
An electric furnace comprising: a switching unit that switches a connection state to either the state where the two heating elements are connected in series or the state where they are connected in parallel with respect to the power input unit. A voltage detection unit that detects a voltage of a power source input to the power input unit;
The electric furnace according to claim 1, wherein the switching unit switches a connection state of the two heating elements to the power input unit based on a detection result by the voltage detection unit.   An analysis apparatus comprising the electric furnace according to claim 1. A total carbon measuring device for measuring total carbon;
An inorganic carbon measuring device for measuring inorganic carbon;
Based on the total carbon measured by the total carbon measurement device and the inorganic carbon measured by the inorganic carbon measurement device, a total organic carbon calculation processing unit that calculates the total organic carbon contained in the sample; With
The analyzer according to claim 3, wherein the electric furnace is provided in at least one of the total carbon measuring device and the inorganic carbon measuring device.

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