JP5505378B2 - Analyzer - Google Patents

Description

  The present invention relates to an analyzer having a display unit for displaying an image, and more particularly, a total organic carbon meter (TOC meter), a total nitrogen / total phosphorus meter (TNP) for measuring a TOC (total organic carbon) concentration in a solution sample, The present invention relates to an ultraviolet absorbance automatic measuring instrument (UVM) for water quality monitoring.

  In recent years, measurement of organic carbon concentration in water such as water and sewage water, water for various plants, and rivers has become one of the important items for pollution investigations. A total organic carbon meter (TOC meter) is used for measuring the organic carbon concentration. The total organic carbon meter mainly measures the total organic carbon concentration by burning an aqueous solution sample from which inorganic carbon (IC) has been removed in advance by bubbling or the like in a combustion tube and measuring the generated carbon dioxide, A method is known in which an aqueous sample is burned and the total organic carbon concentration is measured by subtracting the measured value of inorganic carbon separately measured from the measured value of total carbon (TC).

FIG. 7 is a front view showing an example of a conventional total organic carbon meter, and FIG. 8 is a sectional view of the total organic carbon meter shown in FIG. 7 as viewed from the side. FIG. 9 is a front view when the front door of the total organic carbon meter shown in FIG. 7 is opened. FIG. 6 is an overall schematic diagram of the total organic carbon meter.
The total organic carbon meter 201 includes a rectangular parallelepiped housing 210, an analysis unit 20 that analyzes the aqueous solution sample S, a control unit 30 that controls the analysis unit 20, an acid container 41, a water container 42, and an aqueous solution sample S. Is provided with a homogenizer 43 and a ventilation fan 51. In this specification, the vertical direction (up and down direction) is the Z direction, the direction perpendicular to the Z direction is the X direction, and the direction perpendicular to the Z direction and the X direction is the Y direction.

The housing 210 includes a rectangular parallelepiped housing having an inner space surrounded by four walls 211 on the top, bottom, left, and right, a back wall 212, and a front door 213 serving as a front wall. A flat hinge 216 is formed between the right side of the front door 213 and the front surface of the right wall 211. Then, when the front door 213 is opened around the flat hinge 216 by a measurer or the like, the internal space is opened.
In the internal space of the housing 210, an arrangement area of the control unit 30, an arrangement area of the analysis unit 20, and an arrangement area of the acid container 41 are formed in this order from the top. A partition wall 214 is formed between the arrangement area of the control unit 30 and the arrangement area of the analysis unit 20.

  Thus, the measurer or the like can open the front door 213 and replace the old acid container 41 arranged in the arrangement region of the acid container 41 with a new acid container 41. Further, a water container 42 containing a large amount of water for automatically introducing water into the analysis unit 20 online is disposed on the right side of the casing 210. Further, a homogenizer 43 for automatically introducing the aqueous solution sample S into the analysis unit 20 online is disposed on the left side of the housing 210.

The analysis unit 20 includes a multi-port valve 21, a micro syringe pump 22 having a syringe 22a and a plunger 22b, a motor M ₂ for driving the plunger 22b of the micro syringe pump 22, and a motor M ₁ for driving the multi-port valve 21. And a measurement unit 23 that converts all organic carbon components in the aqueous solution sample S into carbon dioxide (see, for example, Patent Document 1).

The multiport valve 21 includes a common port 21z and four distribution ports 21a to 21d. The multi-port valve 21 is driven by a motor _{M 1,} the common port 21z and the one dispensing port 21a~21d is adapted to be selectively connected.
A micro syringe pump 22 is connected to the common port 21z by a screw mechanism or the like.

A homogenizer 43 is connected to the distribution port 21b via a sample channel 43a. Thereby, the common port 21z and the distribution port 21b are connected, and the aqueous solution sample S is sucked from the distribution port 21b to the microsyringe pump 22 when the plunger 22b moves downward.
An acid container 41 is connected to the distribution port 21c via an acid inflow pipe 41a. Thereby, the common port 21z and the distribution port 21c are connected, and when the plunger 22b moves downward, hydrochloric acid used for bubbling is sucked into the micro syringe pump 22 from the distribution port 21c. .

In addition, a water container 42 is connected to the distribution port 21d through a water inflow pipe 42a. Thereby, the common port 21z and the distribution port 21d are connected, and when the plunger 22b moves downward, water is sucked into the micro syringe pump 22 from the distribution port 21d.
Further, a TC sample injection unit 23b of the measurement unit 23 is connected to the distribution port 21a via a sample injection tube 23a. Thereby, the common port 21z and the distribution port 21a are connected, and when the plunger 22b moves upward, the bubbled aqueous solution sample S is injected from the distribution port 21a to the TC combustion unit 23b. Yes.

The TC sample injection unit 23b of the measurement unit 23 injects the bubbling aqueous solution sample S sent from the microsyringe pump 22 into the TC combustion unit 23c together with the carrier gas. The TC combustion unit 23c burns the injected aqueous solution sample S and converts all organic carbon components in the aqueous solution sample S into carbon dioxide. Combustion gas generated by combustion in the TC combustion unit 23c is sent to a CO ₂ detection unit 23d such as an infrared gas analyzer. Then, the CO ₂ detection unit 23d outputs the measurement value to the control unit 30 via the wiring 23e.

The control unit 30 includes a CPU 31 and a memory 32, and a display / input device 233 having a monitor screen and the like and a printing machine 34 are connected via a wiring 33a. The display / input device 233 displays a rectangular image on the XZ plane, and is arranged in the upper right part of the front surface of the housing 210. The control unit 30 is a display / input device for space saving and miniaturization. It is arranged inside the casing 210 located behind 233 (Y direction). Further, the display / input device 233 can perform an input operation, and an input signal is output to the CPU 31 when an input operation is performed by a measurer or the like.
The CPU 31 drives the motor M ₂ and the motor M ₁ at a predetermined timing based on the input data input by the display / input device 233, acquires the measurement value measured by the CO ₂ detection unit 23d, Based on the value, the total organic carbon concentration in the aqueous solution sample S is measured from the amount of carbon dioxide in the combustion gas and printed on the printer 34.

  By the way, in the total organic carbon meter 201, it is necessary to maintain the control part 30 regularly. Therefore, a flat hinge 217 is formed between the right side of the display / input device 233 and the front surface of the right wall 211. Accordingly, the measurer or the like opens the display / input device 233 and performs maintenance of the control unit 30. 10 is a front view when the display / input device 233 of the total organic carbon meter 201 shown in FIG. 7 is opened, and FIG. 11 is an enlarged perspective view of the upper portion of the total organic carbon meter 201 shown in FIG. .

JP-A-9-43224

  However, in the total organic carbon meter 201 as described above, the measurer or the like opens the display / input device 233 and performs maintenance of the control unit 30. However, while observing the display / input device 233, the measurer etc. When maintenance is desired, the display / input device 233 is open, making it difficult to observe the display / input device 233.

In order to solve the above problems, the present inventors have studied a method for performing maintenance of the control unit 30 while observing the display / input device 233. First, it was considered to use an arm-type hinge or rail so that the display direction of the display / input device 233 does not change. FIG. 12 is a perspective view when the display / input device of the total organic carbon meter is opened using an arm-type hinge. Thereby, maintenance of the control unit could be performed while observing the display / input device. However, this method has a problem that the cost becomes high.
Therefore, the first female part and the second female part are arranged on the display unit so that the display direction of the display unit such as the display / input device does not change between the normal state and the maintenance state without using an arm type hinge or rail. The first male part and the second male part are formed on the surface of the housing, and the first female part is attached to the first male part and the second female part is attached to the second male part in the normal state. In the maintenance state, it was found that the first female part is attached to the second male part so that the display part moves in parallel.

  That is, the analyzer of the present invention includes a housing, a display unit disposed on the surface of the housing and displaying an image, an analysis unit disposed inside the housing and analyzing a sample, and the display unit. An analyzer including a control unit for controlling, wherein a first female part is formed at a first corner of the display unit, and a second female part is formed at a second corner of the display unit. A first male part is formed at the first corner of the surface of the housing located in front of the control unit, and a second corner of the surface of the housing located in front of the control unit. The second male part is formed, and in the normal state of analyzing the sample, the first female part is attached to the first male part and the second female part is attached to the second male part, and the control In the maintenance state where the maintenance of the part is performed, the first female part is attached to the second male part. To have.

  As described above, according to the analyzer of the present invention, since the display direction of the display unit between the normal state and the maintenance state does not change, the control unit can be maintained while observing the display unit.

(Means and effects for solving other problems)
In the above invention, the display unit is a quadrangle, and a first female part that is an opening is formed in each of the upper left corner and the upper right corner of the display unit, and the lower left corner of the display unit A second female part, which is an opening, is formed in each of the upper part and the lower right corner part. The upper left corner part and the upper right corner part of the surface of the housing located in front of the control part are projecting parts. A single male part is formed, and a second male part that is a protruding part is formed at each of the lower left corner and upper right corner of the surface of the housing located in front of the control part. Also good.

And in said invention, the said display part can perform input operation, and you may make it output an input signal to the said control part.
Furthermore, in the above invention, an arrangement area of the control unit, an arrangement area of the analysis unit, and an arrangement area of the reagent tank may be formed inside the housing in this order from the top.

The front view which shows an example of the total organic carbon meter which concerns on embodiment of this invention. Sectional drawing which looked at the total organic carbon meter shown in FIG. 1 from the side. The front view when the front door of the total organic carbon meter shown in FIG. 1 is opened. The front view when the display and input device of the total organic carbon meter shown in FIG. 1 is moved. The expansion perspective view of the upper part of the total organic carbon meter shown in FIG. Overall schematic diagram of total organic carbon meter. The front view which shows an example of the conventional total organic carbon meter. Sectional drawing which looked at the total organic carbon meter shown in FIG. 7 from the side. The front view when the front door of the total organic carbon meter shown in FIG. 7 is opened. The front view when the display and input device of the total organic carbon meter shown in FIG. 7 is opened. The expansion perspective view of the upper part of the total organic carbon meter shown in FIG. The expansion perspective view of the upper part of a total organic carbon meter.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. Note that the present invention is not limited to the embodiments described below, and it goes without saying that various aspects are included without departing from the spirit of the present invention.

FIG. 1 is a front view showing an example of the total organic carbon meter according to the embodiment of the present invention, and FIG. 2 is a cross-sectional view of the total organic carbon meter shown in FIG. FIG. 3 is a front view when the front door of the total organic carbon meter shown in FIG. 1 is opened. In addition, the same code | symbol is attached | subjected about the thing similar to the total organic carbon meter 201 mentioned above.
The total organic carbon meter 1 includes a rectangular parallelepiped housing 10, an analysis unit 20 that analyzes the aqueous solution sample S, a control unit 30 that controls the analysis unit 20, an acid container 41, a water container 42, and an aqueous solution sample S. Is provided with a homogenizer 43 and a ventilation fan 51.

The housing 10 includes a rectangular parallelepiped housing having an internal space surrounded by four walls 11 on the upper, lower, left, and right sides, a rear wall 12, and a front door 13 serving as a front wall. A flat hinge 16 is formed between the right side of the front door 13 and the front surface of the right wall 11. The interior space is opened by the front door 13 being opened with the flat hinge 16 as an axis by a measurer or the like.
In the internal space of the housing 10, an arrangement area of the control unit 30, an arrangement area of the analysis unit 20, and an arrangement area of the acid container 41 are formed in this order from the top. A partition wall 14 is formed between the arrangement area of the control unit 30 and the arrangement area of the analysis unit 20.

  The control unit 30 includes a CPU 31 and a memory 32, and a display / input device 33 having a monitor screen and the like and a printing machine 34 are connected via a wiring 33a. The display and input device 33 displays a rectangular image on the XZ plane, and is disposed on the front surface of the housing 10. The control unit 30 is located behind the display and input device 33 for space saving and miniaturization. It arrange | positions inside the housing | casing 10 located in (Y direction). The display / input device 33 can perform an input operation, and an input signal is output to the CPU 31 when the measurement operator or the like performs the input operation.

4 is a front view when the display and input device 33 of the total organic carbon meter 1 shown in FIG. 1 is moved. FIG. 5 shown in FIG. It is a perspective view.
In the upper left corner of the display and input device 33, a circular upper left opening (first female portion) 33a penetrating in the Y direction is formed. A circular upper right opening (first female portion) 33b penetrating in the Y direction is formed at the upper right corner of the display / input device 33. In the lower left corner of the display and input device 33, a circular lower left opening (second female portion) 33c penetrating in the Y direction is formed. A circular lower right opening (second female portion) 33d penetrating in the Y direction is formed in the lower right corner of the display / input device 33. The upper left opening 33a, the upper right opening 33b, the lower left opening 33c, and the lower right opening 33d have the same shape.

  A cylindrical upper left screw part (first male part) 19a that can move at a predetermined distance in the Y direction is provided at the upper left part of the surface of the housing 20 located in front of the control unit 30 (Y direction). Is formed. A cylindrical upper right screw portion (first male portion) that is movable at a predetermined distance in the Y direction is provided at the upper right portion of the surface of the housing 20 located in front of the control unit 30 (Y direction). 19b is formed. A cylindrical lower left screw portion (second male portion) that is movable at a predetermined distance in the Y direction is provided at the lower left portion of the surface of the housing 20 positioned in front of the control unit 30 (Y direction). 19c is formed. A cylindrical lower right screw (second male part) that is movable at a predetermined distance in the Y direction is provided at the lower right part of the surface of the housing 20 located in front of the control unit 30 (Y direction). 19d is formed. Note that the upper left screw portion 19a, the upper right screw portion 19b, the lower left screw portion 19c, and the lower right screw 19d have the same shape, and can be inserted into the opening 33.

  Accordingly, the measurer or the like, in a normal state of analyzing the sample, places the upper left opening (first female portion) 33a in the upper left screw portion (first male portion) 19a and the upper right screw portion (first male portion) 19b. Upper right opening (first female part) 33b, lower left screw part (second male part) 19c at lower left opening (second female part) 33c, lower right screw part (second male part) 19d and lower right opening (first female part) Two female parts) 33d are inserted and fixed. At this time, the control unit 30 is arranged inside the housing 10 located behind the display and input device 33 (Y direction).

  On the other hand, the measurer or the like enters the upper left screw part (first female part) 33a from the upper left screw part (first male part) 19a and the upper right screw part (first male part) in the maintenance state in which the control unit 30 is maintained. 19b to upper right opening (first female part) 33b, lower left screw part (second male part) 19c to lower left opening (second female part) 33c, lower right screw part (second male part) 19d to lower right opening (Second female part) 33d is removed by loosening the screw part. Thereafter, the upper left opening (second female part) 33a is inserted into the lower left screw part (second male part) 19c, and the upper right opening (first female part) 33b is inserted into the lower right screw part (second male part) 19d. And temporarily fix. At this time, the display and input device 33 disappears from the front (Y direction) of the control unit 30, and maintenance of the control unit 30 can be performed. Further, since the display / input device 33 translates downward (Z direction), the display direction of the display / input device 33 does not change, so that the maintenance of the control unit 30 can be performed while observing the display / input device 33. it can.

  As described above, according to the total organic carbon meter 1 of the present invention, since the display direction of the display / input device 33 does not change between the normal state and the maintenance state, the control unit 30 is observed while observing the display / input device 33. Maintenance can be performed.

<Other embodiments>
(1) In the total organic carbon meter 1 described above, the display / input device 33 is configured to translate in the downward direction (Z direction), but the display / input device is configured to translate in the right direction (X direction). It is good.
(2) In the total organic carbon meter 1 described above, a circular opening is formed as a female part at the corner of the display / input device 33, but a dalma-shaped or keyhole-shaped opening is formed as the female part. It is good also as a structure in which is formed.
(3) In the total organic carbon meter 1 described above, the display / input device 33 is formed with four points of the upper left opening 33a, the upper right opening 33b, the lower left opening 33c, and the lower right opening 33d. The upper left screw portion 19a, the upper right screw portion 19b, the lower left screw portion 19c, and the lower right screw 19d are formed in four points. A point opening may be formed, and the housing may have two points of an upper screw portion and a lower screw portion. That is, it may be two points instead of four points.
(4) In the total organic carbon meter 1 described above, the display / input device 33 and the housing 20 are configured to be attached and removed by the openings 33a to 33d and the screw portions 19a to 19d. The housing may be configured to be attached and detached with an instrument that can be fixed, such as a magnet.

  The present invention can be used for a total organic carbon meter or the like for measuring the TOC concentration in a solution sample.

1: Total organic carbon 10: Cases 19a, 19b: Screw part (first male part)
19c, 19d: Screw part (second male part)
20: Analysis unit 30: Control unit 33: Display and input device (display unit)
33a, 33b: Opening (first female part)
33c, 33d: Opening (second female part)
41: Acid container (reagent tank)

Claims (4)

A housing,
A display unit arranged on the surface of the housing and displaying an image;
An analyzer that is disposed inside the housing and includes an analysis unit that analyzes a sample and a control unit that controls the display unit,
A first female part is formed at the first corner of the display part, and a second female part is formed at the second corner of the display part,
A first male part is formed at the first corner of the surface of the housing located in front of the control unit, and a second corner is formed at the second corner of the surface of the housing located in front of the control unit. The male part is formed,
In the normal state of analyzing the sample, a first female part is attached to the first male part and a second female part is attached to the second male part,
In the maintenance state in which the control unit is maintained, a first female part is attached to the second male part. The display unit is a rectangle,
A first female part that is an opening is formed in each of the upper left corner and the upper right corner of the display part, and a second female part that is an opening is formed in the lower left corner and the lower right corner of the display part. Each formed,
The upper left corner and the upper right corner of the surface of the housing located in front of the control unit are respectively formed with a first male part as a protrusion, and the surface of the housing located in front of the control unit 2. The analyzer according to claim 1, wherein a second male part which is a protruding part is formed in each of the lower left corner and the upper right corner. The analyzer according to claim 1, wherein the display unit is capable of performing an input operation and outputs an input signal to the control unit. The arrangement area of the control unit, the arrangement area of the analysis unit, and the arrangement area of the reagent tank are formed inside the housing in this order from the top. 2. The analyzer according to item 1.

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