JP6853090B2 - Automatic analyzer - Google Patents

Description

The present invention relates to an automatic analyzer having a reagent cool box.

Conventionally, an analyzer that mixes various reagents and a sample for analysis includes a reagent cold storage that holds these various reagents. This reagent cold storage has a hole for sucking the reagent in a part of the lid member so that the reagent to be held can be easily sucked, and the hole for sucking the reagent is always open. The inside of this reagent cold storage is generally kept at a temperature lower than room temperature, but since the above-mentioned holes for suction of reagents are always open, dew condensation occurs in the vicinity of these holes. Therefore, a technique for preventing dew condensation by heating the suction holes has been disclosed (Patent Document 1).

JP-A-2007-040900

By the way, conventionally, since the roles of cooling the reagent refrigerator and heating the suction holes are completely different, such as cooling and heating, they have been performed by using different devices. Using separate devices in this way has a problem of large power consumption. Further, by using separate devices, there is a problem that the configuration of the automatic analyzer becomes complicated.

The present invention has been made in view of the above, and an object of the present invention is to provide an automatic analyzer capable of preventing dew condensation with low power consumption and a simple configuration.

In order to solve the above problems, the present invention provides a reagent cold storage for cooling and storing a reagent container containing a reagent to be mixed with a sample to be measured, and a suction hole provided in the upper part of the reagent cold storage. , A reagent probe that sucks out the reagent from the reagent container in the reagent cold storage, a measuring device that measures a measurement sample in which the reagent sucked out by the reagent probe and the sample are mixed, and the reagent cold storage. provided at the bottom, and a heat absorbing means for cooling the reagent in the reagent refrigerator, provided at a lower portion of said heat absorbing means, a heat radiation means for radiating heat absorbs heat in the heat absorbing means, which is radiated by the radiator means An exhaust duct for discharging heat-based warm air from the heat radiating means to the outside and the suction hole for guiding the heat-based warm air radiated by the heat radiating means and communicating the inside and outside of the reagent cold storage are added. a warm air duct temperature, provided between the heat dissipating means and the warm duct, measuring and switching means capable of switching change or flow rate ratio, the temperature of the suction hole of the warm duct and the exhaust duct The warming duct is connected to the side of the suction hole from the other side of the heat radiating means through the side of the reagent cold storage, and is connected to the side of the suction hole. Is connected to the outside through the outer peripheral portion of the suction hole, and the exhaust duct is connected to the outside from one side of the heat radiating means without passing through the suction hole. When the temperature of the suction hole is equal to or lower than a predetermined temperature at which dew condensation occurs in the suction hole, the suction hole is heated by the warm air, and when the temperature of the suction hole is higher than the predetermined temperature, the suction hole is added. It is characterized in that the warm air is discharged to the outside without being heated .

According to the present invention, it is possible to provide an automatic analyzer that enables prevention of dew condensation with low power consumption and a simple configuration.

It is a top view which shows the outline of the automatic analyzer which concerns on this embodiment. FIG. 5 is a cross-sectional view taken along the line AA of the reagent cold storage portion in the automatic analyzer shown in FIG. FIG. 2 is a schematic view taken along the line CC of the reagent cold storage portion in the automatic analyzer shown in FIG. 2, showing the flow of warm air in a state where the switching means is open. FIG. 2 is a schematic view taken along the line BB of the reagent cold storage portion in the automatic analyzer shown in FIG. 2, showing that the tubular member constituting the suction hole is warmed up with the switching means open. .. It is a flowchart which shows an example of the process performed by the automatic analyzer which concerns on Embodiment 1 of this invention. It is a cross-sectional view of AA of the reagent cold storage part in the automatic analyzer shown in FIG. 1, and shows the modification different from FIG. It is sectional drawing which shows the structure of the automatic analyzer which concerns on 2nd Embodiment of this invention. It is a figure for demonstrating the part which performs heat transfer in the automatic analyzer shown in FIG. 7. It is a flowchart which shows an example of the process performed by the automatic analyzer which concerns on 2nd Embodiment of this invention. It is a figure which shows the modification of the automatic analyzer shown in FIG. 7.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. In each drawing, the same parts (common components) are designated by the same reference numerals in principle, and the repeated description thereof will be omitted.

<< Embodiment 1 >>
[Overall configuration of automatic analyzer]
FIG. 1 is a plan view showing an outline of an automatic analyzer 100 according to an embodiment of the present invention. The automatic analyzer 100 is an apparatus that mixes a sample and a reagent and automatically analyzes the mixed measurement sample. As shown in FIG. 1, the automatic analyzer 100 includes a transfer line 1, a sample probe 4 for sucking a sample, a reaction vessel supply cabinet 6, a reaction vessel supply mechanism 7, a reaction vessel table 9, and reaction measurement. It has an apparatus 10, a reagent cold storage 8, a reagent probe 12, a reagent stirring rod 13, and a reagent disk 14.

The transport line 1 is a line for transporting the sample container 3 containing the sample that has been centrifuged, for example. In the present embodiment, a plurality of sample containers 3 are collectively held in one sample container transport rack 2 and transported on the transport line 1. The sample is, for example, blood, urine, or the like collected from a patient or the like.

The sample probe 4 has an arm and performs a suction operation and a discharge operation of the sample contained in the sample container 3. A nozzle for sucking and discharging the sample is provided at the tip of the sample probe 4.

The reaction vessel supply chamber 6 holds a plurality of unused reaction vessels 5. The reaction vessel supply mechanism 7 has a mechanism for supplying the reaction vessel 5 held by the reaction vessel supply cabinet 6 to the reaction vessel table 9. The reaction vessel table 9 has a mechanism for moving the supplied reaction vessel 5 from the reagent probe 12 to the reagent discharge position where the reagent is discharged by rotating itself.
The reaction vessel 5 is placed on the reaction vessel table 9 from the reaction vessel supply chamber 6 by the reaction vessel supply mechanism 7. The reaction vessel 5 is moved in the order of the reagent discharge position, the sample discharge position, and the reaction measurement position of the reaction vessel table 9 by rotating the reaction vessel table 9. Incidentally, the sample discharged by the sample probe 4 and the reagent discharged by the reagent probe 12 are mixed in the reaction vessel 5, left on the reaction vessel table 9 for a predetermined time, and then the reaction state is measured by the reaction measuring device 10. Will be done.

The reagent cool box 8 is a cold box whose inside is adjusted to a predetermined temperature or lower by the endothermic means 101, and houses a plurality of reagent containers 11 containing reagents. The temperature inside the reagent cold storage 8 is maintained at a predetermined temperature, for example, a temperature lower than room temperature (for example, 5 ° C. to 10 ° C.). This makes it possible to keep the reagent cool and prevent the reagent from deteriorating. The reagent cold storage 8 has a cylindrical shape, and the upper portion thereof is covered with a reagent cold storage lid 15. A suction hole 16 is formed in the reagent cold storage lid 15. A reagent disc 14 is provided in the reagent cold storage 8, and a plurality of reagent containers 11 are placed in the reagent disc 14.

Further, as shown in FIG. 1, the automatic analyzer 100 is provided with an arm 20 so as to straddle the reagent cold storage 8 and the reaction vessel table 9, and the arm 20 is provided with a reagent probe 12. The reagent stirring rod 13 is provided so as to be able to move horizontally along the arm 20.

The suction hole 16 for the reagent probe 12 to suck the reagent is composed of, for example, a tubular member having a through hole. The suction hole 16 is formed by providing this tubular member through the upper part of the reagent cold storage 8 and the reagent cold storage lid 15 (communication between the inside and the outside of the reagent cold storage 8). The reagent probe 12 can move in the vertical direction as well as in the horizontal direction along the arm 20, and performs a suction operation and a discharge operation of the reagent contained in the reagent container 11. A nozzle for sucking and discharging the reagent is provided at the tip of the reagent probe 12. Further, the reagent stirring rod 13 can also move in the vertical direction as well as in the horizontal direction along the arm 20.

The upper end of the reagent container 11 is open. The reagent stirring rod 13 is moved to the reagent stirring position where the reagent in the reagent container 11 is stirred. Then, the reagent stirring rod 13 is inserted into the reagent container 11 via the suction hole 16 and the upper end of the reagent container 11. Then, the reagent stirring rod 13 is rotated in the inserted state to stir the reagent contained in the reagent container 11. The reagent stirring rod 13 in which the reagent is stirred is withdrawn from the reagent container 11.

After that, the reagent probe 12 is moved from the reagent container 11 to the reagent suction position for sucking the reagent. Then, the reagent probe 12 is inserted into the reagent container 11 via the suction hole and the upper end of the reagent container 11. Then, the reagent probe 12 sucks the reagent from the reagent container 11 in the inserted state.
The reagent probe 12 that has sucked the reagent is withdrawn from the reagent container 11. After that, the reagent probe 12 is moved to the reagent discharge position (a predetermined position on the reaction vessel table 9), and the reagent is discharged into the reaction vessel 5.
After the reagent is discharged, the reaction vessel table 9 rotates itself to move the reaction vessel 5 from the sample probe 4 to the sample discharge position where the sample is discharged.

The transport line 1 transports the sample container 3 held by the sample container transport rack 2 to the sample suction position where the sample is sucked from the sample probe 4. The sample container 3 contains a sample to be inspected. Further, the upper end of the sample container 3 is open. After the sample container 3 is transported to the sample suction position by the transfer line 1, the sample probe 4 is inserted into the sample container 3 from the upper end of the sample container 3. Then, the sample probe 4 sucks the sample from the sample container 3 in the inserted state.

After aspirating the sample, the sample probe 4 is withdrawn from the sample container 3. After that, the sample probe 4 is moved to the sample discharge position on the reaction vessel table 9. After being moved to the sample discharge position, the sample probe 4 discharges the sucked sample into the reaction vessel 5 (containing the reagent).
A stirring mechanism (not shown) stirs the reagent discharged into the reaction vessel 5 and the sample. The stirred reagent and sample are left for a predetermined time. After being left unattended, the reaction vessel 5 is moved to the reaction measuring device 10. Then, the reaction measuring device 10 measures the reaction state between the reagent and the sample in the moved reaction vessel 5.
A plurality of reagent containers 11 are installed on the reagent disc 14, and by rotating the reagent disc 8, the reagents to be stirred and sucked by the reagent stirring rod 13 and the reagent probe 12 can be replaced.

[Structure related to dew condensation prevention of automatic analyzer]
Next, with reference to FIGS. 2 to 4, a detailed configuration of the automatic analyzer 100, that is, a configuration capable of preventing dew condensation with a low power consumption and a simple configuration will be described.

FIG. 2 is a cross-sectional view taken along the line AA in the automatic analyzer shown in FIG. FIG. 3 is a schematic view taken along the line CC of the automatic analyzer shown in FIG. 2, showing the flow of warm air in a state where the switching means is open. FIG. 4 is a schematic view taken along the arrow BB in the automatic analyzer shown in FIG. 2, showing that the tubular member constituting the suction hole is warmed up with the switching means open. The broken line arrows shown in FIGS. 2 to 4 indicate the flow of warm air, and the solid line arrows shown in FIG. 2 indicate the flow of outside air.

As shown in FIG. 2, in addition to the above-described components, the automatic analyzer 100 includes a heat absorbing means 101, a heat radiating means 102, a warming means (warming duct) 103, a blowing means 104, an exhaust duct 105, and a switching means 106. It includes a control device 107, a suction hole temperature sensor 111, a temperature sensor 112 inside the cold storage, a temperature sensor 113 outside the cold storage, and the like.

The temperature sensors are attached to a plurality of locations of the automatic analyzer 100 and measure the temperature at each location. Among these temperature sensors, the suction hole temperature sensor 111 is attached to the outer peripheral surface or the inner peripheral surface of the suction hole 16 (the tubular member constituting the suction hole 16), and measures the temperature (surface temperature) of the suction hole 16. .. Further, the temperature sensor 112 inside the cold storage is attached to the inside of the reagent cold storage 8 and on the side of the reagent cold storage lid 15, and measures the ambient temperature inside the reagent cold storage 8. The cold storage outside temperature sensor 113 is attached to the surface of the reagent cold storage lid 15 and measures the surface temperature of the reagent cold storage lid 15.

The endothermic means 101 is attached to the bottom of the reagent cold storage 8, and lowers the temperature inside the reagent cold storage 8 by absorbing the heat inside the reagent cold storage 8. As a means for realizing such an endothermic means 101, for example, a Peltier element or the like can be mentioned as an example. As the capacity of the Peltier element (heat absorbing means 101) in this embodiment, it is assumed that the heat absorbing surface is about 3 ° C and the heat generating surface is about 45 ° C, and the reagent cold storage temperature in that case is about 6.5 ° C. I'm assuming.

The heat radiating means 102 is provided below the heat absorbing means 101. The heat absorbed by the heat absorbing means 101 is dissipated by the heat radiating means 102. It is desirable that the heat radiating means 102 is made of a member having high thermal conductivity and has a shape having a large surface area. Further, the air blowing means 104 is provided so as to be connected to the heat radiating means 102. The blowing means 104 guides the outside air to the heat radiating means 102 and mixes the heat of the radiating means 102 with the outside air to generate warm air H which is higher than the outside air temperature. The blower means 104 may be able to radiate heat by applying outside air to the heat radiating means 102, and the position of the blower means 104 may be below or on the side of the heat radiating means 102. In other words, the heat radiating means 102 may be arranged on the suction side or the discharge side of the blower means 104.

Incidentally, the heat radiating means 102 (although the heat absorbing means 101 is also the same) is made of a metal material such as aluminum, iron, copper, etc. as a material having high thermal conductivity. Further, it is preferable that the heat radiating means 102 has a shape having a surface area as large as possible. By increasing the heat dissipation area, the amount of heat dissipation can be increased.

Further, as shown in FIGS. 2 and 3, the automatic analyzer 100 of the present embodiment includes a warming duct 103, an exhaust duct 105, and a switching means 106. The exhaust duct 105 is provided on one side of the heat radiating means 102, and the warming duct 103 is provided on the other side facing the exhaust duct 105. Further, a switching means 106 is provided between the heat radiating means 102 and the warming duct 103. The switching means 106 is provided with a valve having a size that shields the entire cross section of the warm air duct 103, and the valve is driven by an actuator to close or open the inside of the warm air duct 103. An electric motor, solenoid, or the like is used as the actuator. That is, when the switching means 106 is open, the warm air H flows to both the exhaust duct 105 and the warm air duct 103, but when the switching means 106 is closed, the warm air flows only to the exhaust duct 105. That is, regardless of whether the warm air duct 103 is opened or closed by the switching means 106, the exhaust duct 105 causes the warm air to flow inside and discharges the warm air to the outside.

As shown in the cross-sectional view taken along the line BB in FIG. 4, the warming duct 103 passes through the outer peripheral portion of the suction hole 16 (cylindrical member constituting the suction hole 16) provided in the reagent cold storage 8 to the outside. Is connected to. The tubular member constituting the suction hole 16 has a cylindrical shape composed of a member having a high thermal conductivity, and is attached through the reagent cold storage lid 15 (warm air passes through the suction hole 16). It is prevented from flowing into the reagent cool box 8). On the other hand, the exhaust duct 105 is connected to the outside of the automatic analyzer 100 without passing through the suction hole 16.

That is, the warming duct 103 is provided so as to be connected to the side portion of the heat radiating means 102, passes through the lower part of the reagent cold storage 8, the side part of the reagent cold storage 8, the suction hole 16, and the upper part of the reagent cold storage 8. It is connected to the outside. When the warm air duct 103 is opened by the switching means 106, the warm air flows inside and the warm air is discharged to the outside (see the broken line arrows in FIGS. 2 to 4). Further, when the warm air duct 103 is closed by the switching means 106, the warm air does not flow inside and the warm air is not discharged to the outside. (Warm air flows only through the exhaust duct 105 and is discharged to the outside). That is, the flow of warm air inside the warm air duct 103 is controlled as the switching means 106 is driven.

When warm air flows inside the warm air duct 103, the warm air duct 103 heats the suction hole 16. If the temperature of the suction hole 16 is equal to or lower than the predetermined temperature, the warming duct 103 heats the suction hole 16 until the suction hole 16 exceeds the predetermined temperature. By heating the suction hole 16 by the warm air duct 103, the temperature of the suction hole 16 is maintained at a temperature exceeding a predetermined temperature. This makes it possible to prevent the dew condensation that occurs in the suction hole 16 in the automatic analyzer 100 (reagent cold storage 8), and the dew condensation inside the reagent cold storage 8 (the inside of the reagent container 11 that is not covered). Condensation dripping on the lid) is prevented.

The control device 107 is connected to the heat absorbing means 101, the blowing means 104, the switching means 106, the suction hole temperature sensor 111, the temperature sensor 112 inside the cool box, the temperature sensor 113 outside the cool box, and the like via electrical wiring. The control device 107 activates the endothermic means 101 and the blower means 104 after the automatic analyzer 100 is activated. After that, the switching means 106 is driven by the temperature information obtained from the suction hole temperature sensor 111, the cold storage outside temperature sensor 113, and the cold storage inside temperature sensor 112.

That is, the control device 107 measures the temperature of the suction hole 16 via the suction hole temperature sensor 111, and controls the flow of warm air based on the acquired temperature information (controls the drive of the switching means 106). Further, the control device 107 adjusts the temperature of the suction hole 16 by controlling the flow of warm air. For example, when the temperature of the suction hole 16 is equal to or lower than the predetermined temperature (dew point threshold value), the control device 107 opens the warming duct 103 and stays in the suction hole 16 until the temperature of the suction hole 16 exceeds the predetermined temperature (dew point threshold value). Let the warm air flow. When the temperature of the suction hole 16 is higher than the predetermined temperature (dew point threshold value), the control device 107 closes the warm air duct 103 and does not allow warm air to flow through the suction hole 16.

Here, the dew point threshold is set to a value obtained by taking a temperature margin from the dew point temperature (the temperature at which dew condensation occurs when air containing water vapor is cooled). For example, since the dew point temperature in an environment of 32 ° C. and 85% humidity is 29 ° C., the dew point threshold value is 31 ° C. when the temperature margin is 2 ° C. Condensation in the suction hole 16 can be prevented by controlling the flow of warm air so that the temperature of the suction hole 16 always exceeds the dew point threshold value (for example, 31 ° C.). The control device 107 calculates the dew point temperature based on the surface temperature of the reagent cold storage lid 15 measured by the cold storage outside temperature sensor 113, and automatically sets the dew point threshold value together with the separately set temperature margin. To do.

The control device 107 measures the temperature inside the reagent cold storage 8 via the temperature sensor 112 inside the cold storage, and adjusts the temperature inside the reagent cold storage 8 based on the acquired temperature information (heat absorbing means 101). Control). For example, when the temperature inside the reagent cold storage 8 is equal to or higher than a predetermined temperature (cold storage threshold), the control device 107 causes the heat absorbing means 101 to keep the temperature inside the reagent cold storage 8 below the predetermined temperature (cold storage threshold). To control. When the temperature inside the reagent cold storage 8 is smaller than a predetermined temperature (cold storage threshold), the control device 107 controls the endothermic means 101 so as to maintain the temperature inside the reagent cold storage 8.

Here, the cold insulation threshold value is an upper limit value of the recommended temperature when the reagent is stored inside the reagent container 11. That is, by storing the reagent below the cold insulation threshold, the effect of the reagent is guaranteed within the expiration date.

The control device 107 controls the temperature sensor 113 outside the cold storage to measure the temperature outside the reagent cold storage 8, and appropriately controls various devices based on the acquired temperature information. For example, the control device 107 calculates the dew point temperature based on the surface temperature of the reagent cold storage lid 15, and adjusts the temperature of the suction hole 16 so as to exceed the dew point threshold value.

The control device 107 controls the endothermic means 101 to adjust the temperature inside the reagent cool box 8 and cool the inside of the reagent cool box 8. For example, when the control device 107 activates the heat absorbing means 101, the heat absorbing means 101 absorbs the heat inside the reagent cold storage 8, so that the temperature inside the reagent cold storage 8 drops.

The control device 107 controls the blower means 104 to generate warm air. For example, when the control device 107 turns on the power of the air blowing means 104, the outside air is guided to the heat radiating means 102, and the outside air is warmed by the heat absorbed by the heat absorbing means 101, so that warm air is generated.

The control device 107 controls the flow of warm air by controlling the drive of the switching means 106. For example, when the control device 107 drives and controls the switching means 106 in the direction of opening the warm air duct 103, the warm air flows through the warm air duct 103 and the exhaust duct 105. Further, for example, when the control device 107 drives and controls the switching means 106 in the direction of closing the warm air duct 103, the warm air flows only through the exhaust duct 105.

The automatic analyzer 100 according to the present embodiment uses the warm air generated by the cooling of the reagent cold storage for heating the suction holes. As a result, it is not necessary to separately mount the device for cooling the reagent cooler and the device for heating the suction hole in the automatic analyzer 100 as in the conventional case, and it is consumed with a simple configuration. It is possible to provide 100 automatic analyzers with reduced power consumption.
Although the switching means 106 has been described as fully open (open) or fully closed (closed), the opening degree of the valve can be adjusted by a stepping motor or the like so that the flow rate ratio between the warm air duct 103 and the exhaust duct 105 can be changed. Needless to say, it's okay.

〔flowchart〕
Next, the heating process of the suction hole 16 will be described with reference to FIG. FIG. 5 is a flowchart showing an example of processing performed by the automatic analyzer 100.

In step S201, the power of the automatic analyzer 100 is turned on, and the automatic analyzer 100 is started.

In step S202, the endothermic means 101 is activated, and the endothermic means 101 cools the inside of the reagent cool box 8 by absorbing the heat inside the reagent cool box 8. Further, the blowing means 104 is activated, and the blowing means 104 blows the outside air toward the heat radiating means 102. The heat radiating means 102 dissipates the warm air generated by warming the outside air.

In step S203, the control device 107 controls the drive of the switching means 106 to close the warming duct 103. As a result, the warm air flows only through the exhaust duct 105 and is discharged to the outside.

In step S204, the control device 107 determines whether or not the temperature inside the reagent cold storage 8 obtained via the cold storage internal temperature sensor 112 is equal to or higher than the cold storage threshold. When the control device 107 determines that the temperature inside the reagent cold storage 8 is equal to or higher than the cold storage threshold value (step S204 → Yes), the control device 107 proceeds to the process of step S205. When the control device 107 determines that the temperature inside the reagent cold storage 8 is less than the cold storage threshold value (step S204 → No), the control device 107 proceeds to the process of step S206.

In step S205, the control device 107 controls the endothermic means 101 so that the temperature inside the reagent cold storage 8 is below the cold storage threshold, until the temperature inside the reagent cold storage 8 drops below the cold storage threshold. stand by.

In step S206, the control device 107 determines whether or not the temperature of the suction hole 16 obtained via the suction hole temperature sensor 111 is equal to or lower than the dew point threshold value. When the control device 107 determines that the temperature of the suction hole 16 is equal to or lower than the dew point threshold value (step S206 → Yes), the control device 107 proceeds to the process of step S207. When the control device 107 determines that the temperature of the suction hole 16 is larger than the dew point threshold value (step S206 → No), the control device 107 returns to the process of step S201.

In step S207, the control device 107 controls the drive of the switching means 106 to open the warming duct 103. As a result, the warm air flows through the warm air duct 103 and the exhaust duct 105 and is discharged to the outside.

In step S208, the warm air duct 103 heats the suction hole 16 with the warm air flowing inside. The processes of steps S206 to S208 are repeated until the temperature of the suction hole 16 exceeds the dew point threshold value.

As described above, when the temperature of the suction hole 16 is equal to or lower than the dew point threshold value, the automatic analyzer 100 heats the suction hole 16 by the warm air flowing through the warm air duct 103 until the temperature of the suction hole 16 exceeds a predetermined temperature. .. By controlling the heating according to the temperature of the suction hole 16 in this way, it is possible to keep the temperature of the suction hole 16 at a temperature at which dew condensation does not occur while preventing the suction hole 16 from becoming too warm.

[Modification example]
Next, a modified example of the automatic analyzer 100 according to the present embodiment will be described. FIG. 6 is a diagram showing a configuration of an automatic analyzer 200 according to a modified example of the present embodiment.

Unlike the example shown in FIG. 2, the automatic analyzer 200 of the modified example does not include the blower means 104 under the heat radiating means 102. Further, the switching means 106 as a switching valve is not provided. In the modified example, the blower means 108a and the blower means 108b are provided, and the two blower means 108a and the blower means 108b are provided with the roles of the blower means 104 and the switching means 106 in the example of FIG. That is, it embodies "a switching means capable of changing the flow rate ratio between the warming duct 103 and the exhaust duct 105 or switching the flow".

The blower means 108a is attached near the end of the warming duct 103, and the blower means 108b is attached near the end of the exhaust duct 105. The blower means 108a and the blower means 108b are controlled on and off by the control device 107 to switch the flow of warm air.

For example, when the blower means 108a is turned on and the blower means 108b is turned on, warm air flows through the warm air duct 103 and the exhaust duct 105, so that the warm air duct 103 heats the suction hole 16. Further, for example, when the blower means 108a is turned off and the blower means 108b is turned on, the warm air flows only through the exhaust duct 105, so that the warm air duct 103 does not heat the suction hole 16.

The control device 107 switches the flow of warm air by controlling the blower means 108a and the blower means 108b. For example, when the control device 107 controls the blower means 108a and the blower means 108b to be turned on, the warm air flows through the warm air duct 103 and the exhaust duct 105. Further, for example, when the control device 107 controls the blower means 108a to be off and the blower means 108b to be on, the warm air flows only through the exhaust duct 105.

That is, the blower means 108a and the blower means 108b included in the automatic analyzer 200 have the same functions as the blower means 104 and the switching means 106 included in the automatic analyzer 100. The automatic analyzer 200 switches the flow of warm air by properly using the two blowing means 108a and the blowing means 108b, and heats the suction hole 16 at an appropriate timing according to the temperature of the suction hole 16. Thereby, dew condensation generated in the vicinity of the suction hole 16 can be prevented.

Also in the automatic analyzer 200 according to the modified example of the present embodiment, the warm air generated by the cooling of the reagent cold storage 8 is used for heating the suction holes. As a result, it is not necessary to separately mount the device for cooling the reagent cooler and the device for heating the suction hole in the automatic analyzer 200 as in the conventional case, and it is consumed with a simple configuration. It is possible to provide an automatic analyzer 200 with reduced power consumption.

<< Embodiment 2 >>
[Configuration of automatic analyzer]
Next, the configuration of the automatic analyzer 300 according to the present embodiment will be described with reference to FIG. 7. FIG. 8 is a cross-sectional view taken along the line DD in which only the main functions of the automatic analyzer 300 shown in FIG. 7 are extracted. The description of the same configuration and the same contents as those of the first embodiment will be omitted.

As shown in FIG. 7, the automatic analyzer 300 includes a heat absorbing means 101, a heat radiating means 102, a blowing means 104, a control device 107, a warming means (heat transfer duct) 108, a heat transfer means (heat transfer plate) 109, and a heat transfer. The switching means 110, the heat transfer suction hole 160 (suction hole 16), the suction hole temperature sensor 111, the temperature sensor 112 inside the cold storage, the temperature sensor 113 outside the cold storage, and the like are provided.

The suction hole temperature sensor 111 is attached to the outside or inside of the surface of the heat transfer suction hole 160 and measures the surface temperature of the heat transfer suction hole 160. The temperature sensor 112 inside the cold storage is inside the reagent cold storage 8 and is attached to the reagent cold storage lid 15 side to measure the ambient temperature inside the reagent cold storage 8. The cold storage outside temperature sensor 113 is attached to the surface of the reagent cold storage lid 15 and measures the surface temperature of the reagent cold storage lid 15.

The heat transfer suction hole 160 (corresponding to the suction hole 16 of the first embodiment) is provided so as to penetrate the reagent cold storage lid 15, and has a shape in which the end is extended toward the heat transfer duct 108 as shown in FIG. It has become. The heat transfer suction hole 160 is made of a material having high thermal conductivity, and is heated by the heat transferred from the heat transfer duct 108 via the heat transfer plate 109 until the dew point threshold is exceeded.

The endothermic means 101 is provided in the lower part of the reagent cold storage 8, and cools the inside of the reagent cold storage 8 by absorbing the heat inside the reagent cold storage 8. The heat radiating means 102 is provided below the heat absorbing means 101, and dissipates warm air generated by the heat absorbed by the heat absorbing means 101.

The heat transfer duct 108 is made of a material having high thermal conductivity, is provided on the side of the heat radiating means 102, passes through the lower part of the reagent cold storage 8 and the side of the reagent cold storage 8, and is connected to the outside. There is. Therefore, the heat transfer duct 108 allows warm air to flow from the lower part to the upper part of the reagent cold storage 8 and is discharged to the outside.

The heat transfer plate 109 is made of a material having high thermal conductivity, and is fixed to either the heat transfer duct 108 or the heat transfer suction hole 160. In the examples shown in FIGS. 7 and 8, a configuration in which the heat transfer plate 109 is fixed to the heat transfer duct 108 and connected to or disconnected from the heat transfer suction hole 160 will be described as an example. The 109 may be fixed to the heat transfer suction hole 160 and connected to or disconnected from the heat transfer duct 108.

The heat transfer plate 109 is driven and controlled by the heat transfer switching means 110. When the heat transfer plate 109 is driven in the direction of arrow Z1 in FIG. 7, the heat transfer duct 108 and the heat transfer suction hole 160 are connected via the heat transfer plate 109. When the heat transfer plate 109 is driven in the direction of arrow Z2 in FIG. 7, the heat transfer duct 108 and the heat transfer suction hole 160 are not connected.

For example, as shown in FIG. 8A, when the heat transfer plate 109 connects the heat transfer duct 108 and the heat transfer suction hole 160, the heat transfer plate 109 transfers the heat transferred from the heat transfer duct 108. It is transmitted to the heat suction hole 160. On the other hand, as shown in FIG. 8B, when the heat transfer plate 109 does not connect the heat transfer duct 108 and the heat transfer suction hole 160, the heat transfer plate 109 transfers the heat transferred from the heat transfer duct 108. Do not communicate to the heat suction hole 160.

When the heat transfer plate 109 and the heat transfer suction hole 160 are connected, the heat transfer plate 109 heats the heat transfer suction hole 160 with the heat transferred from the heat transfer duct 108. If the temperature of the heat transfer suction hole 160 is equal to or lower than the dew point threshold value, the heat transfer plate 109 heats the heat transfer suction hole 160 until the heat transfer suction hole 160 exceeds the dew point threshold value. By heating the heat transfer suction hole 160 by the heat transfer plate 109, the temperature of the heat transfer suction hole 160 is maintained at a temperature exceeding a predetermined temperature. This makes it possible to prevent dew condensation that occurs in the heat transfer suction hole 160 in the automatic analyzer 300.

The heat transfer switching means 110 is provided on the heat transfer plate 109, and by driving and controlling the heat transfer plate 109, the connection or non-connection between the heat transfer duct 108 and the heat transfer suction hole 160 is switched. The heat transfer switching means 110 is composed of, for example, a rotary actuator or the like. The heat transfer switching means 110 may drive and control the heat transfer plate 109 in the vertical direction, or may drive and control the heat transfer plate 109 in the horizontal direction. The driving direction of the heat transfer plate 109 is not particularly limited.

For example, when the heat transfer switching means 110 drives and controls the heat transfer plate 109 in the direction of connecting the heat transfer duct 108 and the heat transfer suction hole 160, heat is transferred from the heat transfer duct 108 to the heat transfer suction hole 160. It is transmitted. In this case, the heat transfer suction hole 160 is heated by the heat transferred from the heat transfer duct 108. On the other hand, when the heat transfer switching means 110 drives and controls the heat transfer plate 109 in the direction in which the heat transfer duct 108 and the heat transfer suction hole 160 are not connected, heat is transferred from the heat transfer duct 108 to the heat transfer suction hole 160. Is not transmitted.

The control device 107 is connected to the heat absorbing means 101, the blowing means 104, the heat transfer switching means 110, the suction hole temperature sensor 111, the temperature sensor 112 inside the cold storage, the temperature sensor 113 outside the cold storage, and the like via electrical wiring. After starting the automatic analyzer 300, the control device 107 obtains the heat absorbing means 101, the blowing means 104, and the heat transfer switching means 110 from the suction hole temperature sensor 111, the temperature sensor 112 inside the cold storage, the temperature sensor 113 outside the cold storage, and the like. It is controlled by the temperature information.

The control device 107 controls the drive of the heat transfer plate 109 by controlling the heat transfer switching means 110. For example, when the heat transfer plate 109 and the heat transfer suction hole 160 are connected by the control device 107 controlling the heat transfer switching means 110, the heat transfer suction hole 160 is generated by the warm air flowing inside the heat transfer duct 108. Heat is transferred to.

According to the automatic analyzer 300 according to the present embodiment, the warm air generated by the cooling of the reagent cold storage is used for heating the suction holes. As a result, it is not necessary to separately mount the device for cooling the reagent cooler and the device for heating the suction hole in the automatic analyzer 300 as in the conventional case, and it is consumed with a simple configuration. It is possible to provide an automatic analyzer 300 with reduced power consumption.

〔flowchart〕
Next, the heating process of the heat transfer suction hole 160 will be described with reference to FIG. FIG. 9 is a flowchart showing an example of processing performed by the automatic analyzer 300.

In step S301, the power of the automatic analyzer 300 is turned on, and the automatic analyzer 300 is started.

In step S302, the endothermic means 101 is activated, and the endothermic means 101 cools the inside of the reagent cool box 8 by absorbing the heat inside the reagent cool box 8. Further, the blowing means 104 is activated, and the blowing means 104 blows the outside air toward the heat radiating means 102. The heat radiating means 102 dissipates the warm air generated by warming the outside air.

In step S303, the control device 107 controls the heat transfer switching means 110 to disconnect the heat transfer plate 109 and the heat transfer suction hole 160. Even if warm air flows inside the heat transfer duct 108, heat is not transferred from the heat transfer duct 108 to the heat transfer suction hole 160.

In step S304, the control device 107 controls the temperature sensor 112 in the cold storage to determine whether or not the temperature inside the reagent cold storage 8 is equal to or higher than the cold storage threshold. When the control device 107 determines that the temperature inside the reagent cold storage 8 is equal to or higher than the cold storage threshold value (step S304 → Yes), the control device 107 proceeds to the process of step S305. When the control device 107 determines that the temperature inside the reagent cold storage 8 is less than the cold storage threshold value (step S304 → No), the control device 107 proceeds to the process of step S306.

In step S305, the control device 107 controls the endothermic means 101 so that the temperature inside the reagent cold storage 8 is below the cold storage threshold, until the temperature inside the reagent cold storage 8 drops below the cold storage threshold. stand by.

In step S306, the control device 107 controls the suction hole temperature sensor 111 to determine whether or not the temperature of the heat transfer suction hole 160 is equal to or lower than the dew point threshold value. When the control device 107 determines that the temperature of the heat transfer suction hole 160 is equal to or lower than the dew point threshold value (step S306 → Yes), the control device 107 proceeds to the process of step S307. When the control device 107 determines that the temperature of the heat transfer suction hole 160 is larger than the dew point threshold value (step S306 → No), the control device 107 returns to the process of step S301.

In step S307, the control device 107 controls the heat transfer switching means 110 to connect the heat transfer plate 109 and the heat transfer suction hole 160. As a result, heat is transferred from the heat transfer duct 108 to the heat transfer suction hole 160 via the heat transfer plate 109.

In step S308, the heat transfer duct 108 transfers the heat generated by the warm air flowing inside to the heat transfer plate 109 to heat the heat transfer suction hole 160. The processes of steps S306 to S308 are repeated until the temperature of the heat transfer suction hole 160 exceeds the dew point threshold value.

As described above, when the temperature of the heat transfer suction hole 160 is equal to or lower than the dew point threshold value, the automatic analyzer 300 connects the heat transfer duct 108 and the heat transfer suction hole 160 via the heat transfer plate 109. The heat transfer suction hole 160 is heated by the heat transferred from the heat transfer duct 108 until the temperature of the heat transfer suction hole 160 exceeds a predetermined temperature. In this way, by controlling the heating according to the temperature of the heat transfer suction hole 160, the temperature of the heat transfer suction hole 160 can be kept at a temperature at which dew condensation does not occur while preventing the heat transfer suction hole 160 from becoming too warm. Can be done.

[Modification example]
Next, a modified example of the automatic analyzer 300 according to the second embodiment will be described. FIG. 10 is a diagram showing a configuration of an automatic analyzer 400 according to a modified example of the second embodiment.

The automatic analyzer 400 includes a heat absorbing means 101, a heat radiating means 102, a control device 107, a warming means (heat transfer duct) 108, a heat transfer means (heat transfer plate) 109, a heat transfer switching means 110, a heat transfer suction hole 160, and an air blower. The means 120, the suction hole temperature sensor 111, the temperature sensor 112 inside the cold storage, the temperature sensor 113 outside the cold storage, and the like are provided. That is, the automatic analyzer 400 includes a blower means 120 instead of the blower means 104 included in the automatic analyzer 300.

The blower means 120 is attached near the end of the heat transfer duct 108. The blower means 120 is controlled on and off by the control device 107 to switch the flow of warm air.

For example, when the air blowing means 120 is turned on, warm air flows through the heat transfer duct 108. At this time, if the heat transfer duct 108 and the heat transfer suction hole 160 are connected via the heat transfer plate 109, heat is transferred from the heat transfer duct 108 to the heat transfer suction hole 160. For example, when the air blowing means 120 is turned off, warm air does not flow through the heat transfer duct 108. At this time, even if the heat transfer duct 108 and the heat transfer suction hole 160 are connected via the heat transfer plate 109, heat is not transferred from the heat transfer duct 108 to the heat transfer suction hole 160.

That is, the automatic analyzer 400 not only controls the drive of the heat transfer plate 109 to control the heating of the heat transfer suction hole 160, but also controls the on / off of the blower means 120 to control the heat transfer suction hole. It is possible to control the heating to 160.

Also in the automatic analyzer 400 according to the modified example of the second embodiment, the warm air generated by the cooling of the reagent cold storage is used for heating the suction holes. As a result, it is not necessary to separately mount the device for cooling the reagent cold storage and the device for heating the suction holes in the automatic analyzer 400 as in the conventional case. As a result, it is possible to provide an automatic analyzer with reduced power consumption with a simple configuration.

The present invention is not limited to the above-described embodiment (modification example), and can be configured and implemented in various ways. For example, the heat absorbing means and the heat radiating means may be a heat pump type refrigeration cycle device. Further, the warming means may be a heat transfer means such as a heat pipe that does not involve an air flow. That is, as the warming means, the warming duct 103 (FIGS. 2 and 6) was illustrated in the first embodiment, and the heat transfer duct 108 (FIGs. 7 and 10) was exemplified in the second embodiment, but the warming means was a heat pipe. It may be configured (heat transfer means also include heat transfer means such as heat pipes). Further, the first embodiment and the second embodiment can be combined as appropriate. For example, the automatic analyzer 300 and the automatic analyzer 400 of FIGS. 7 and 10 may include the exhaust duct 105 and the switching means 106 of the first embodiment. In this case, it is possible to abolish the heat transfer switching means 110 and the blower means 120 shown in FIGS. 7 and 10. In addition, other appropriate combinations are also possible.

8 Reagent cold storage 10 Reaction measuring device (measuring device)
12 Reagent probe 16 Suction hole 100, 200, 300, 400 Automatic analyzer 101 Endothermic means 102 Heat dissipation means 103 Warming means (warming duct)
105 Exhaust duct 106 Switching means 108 Warming means (heat transfer duct)
109 Heat transfer plate (heat transfer means)
110 Heat transfer switching means 111 Suction hole temperature sensor 113 Cold storage outside temperature sensor 160 Heat transfer suction hole (suction hole)

Claims (2)

A reagent cooler that cools and stores the reagent container containing the reagent to be mixed with the sample to be measured,
A reagent probe that sucks out the reagent from the reagent container in the reagent cold storage through a suction hole provided in the upper part of the reagent cold storage.
A measuring device for measuring a measurement sample in which the reagent sucked out by the reagent probe and the sample are mixed,
An endothermic means provided at the bottom of the reagent cool box to cool the reagent in the reagent cool box.
A heat radiating means provided below the heat absorbing means and dissipating heat absorbed by the heat absorbing means, and a heat radiating means.
An exhaust duct that discharges warm air based on the heat radiated by the heat radiating means to the outside from the heat radiating means, and
A warm air duct that guides warm air based on the heat radiated by the heat radiating means and heats the suction hole that communicates the inside and the outside of the reagent cold storage.
A switching means provided between the heat radiating means and the warming duct and capable of changing the flow rate ratio between the warming duct and the exhaust duct or switching the flow.
A suction hole temperature sensor for measuring the temperature of the suction hole is provided .
The warm air duct is connected from the other side of the heat radiating means to the side of the suction hole through the side of the reagent cool box, and from the side of the suction hole through the outer peripheral portion of the suction hole. It is connected to the outside,
The exhaust duct is connected to the outside from one side of the heat radiating means without passing through the suction hole.
When the temperature of the suction hole is equal to or lower than a predetermined temperature at which dew condensation occurs in the suction hole, the suction hole is heated with the warm air.
An automatic analyzer characterized in that when the temperature of the suction hole is higher than the predetermined temperature, the suction hole is not heated and the warm air is discharged to the outside. A reagent cooler that cools and stores the reagent container containing the reagent to be mixed with the sample to be measured,
A reagent probe that sucks out the reagent from the reagent container in the reagent cold storage through a suction hole provided in the upper part of the reagent cold storage.
A measuring device for measuring a measurement sample in which the reagent sucked out by the reagent probe and the sample are mixed,
An endothermic means for cooling the reagent in the reagent cool box, which is provided in the lower part of the reagent cool box.
A heat radiating means provided below the heat absorbing means and dissipating heat absorbed by the heat absorbing means, and a heat radiating means.
An exhaust duct that discharges warm air based on the heat radiated by the heat radiating means to the outside from the heat radiating means, and
A heat transfer duct that guides warm air based on heat radiation from the heat dissipation means to the upper side of the reagent cool box, and
A heat transfer means that thermally connects the heat transfer duct and the suction hole,
A heat transfer switching means that drives and controls the heat transfer means to switch between thermal connection or non-connection between the heat transfer duct and the suction hole.
A suction hole temperature sensor for measuring the temperature of the suction hole is provided.
The heat transfer duct is connected from one side of the heat radiating means to the side of the suction hole on the upper side of the reagent cold storage through the side of the reagent cold storage, and from the side of the suction hole. It is connected to the outside,
When the temperature of the suction hole is equal to or lower than a predetermined temperature at which dew condensation occurs in the suction hole, the suction hole is heated with the warm air.
When the temperature of the suction hole is higher than the predetermined temperature, the suction hole is not heated and the warm air is discharged to the outside.
An automatic analyzer featuring.

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