JP6391382B2 - Thermal indicator - Google Patents

Description

  The present invention relates to a thermal indicator that determines whether or not the temperature of an article and the environmental temperature where the article is placed are maintained within a certain temperature range.

  Some must always be kept in a constant temperature environment during transport and storage. For example, proteins can be stored stably in a lyophilized state, but degradation and reduced activity may occur in protein solutions after dissolution. Therefore, it is generally recommended to store proteins as follows.

しかしながら、何らかの事情で輸送中、もしくは保管中に環境温度をコントロールできない事態となる場合もある。
この様に一時的に環境温度をコントロールできない事態に遭遇したとしても、その後に正常な冷凍環境に戻されると、外観上もとの状態に復帰する。即ち凍結融解による活性低下が起こっていたとしても、外観上、その変化を認めることができない。そのため、正常なタンパク質だと判断して実験を行ったとしても、正しい実験結果が得られなくなる懸念がある。

However, there are cases where the environmental temperature cannot be controlled during transportation or storage for some reason.
Even if the environment temperature cannot be temporarily controlled in this way, when it is returned to a normal refrigeration environment, it returns to its original state in appearance. That is, even if the activity is reduced due to freezing and thawing, the change cannot be recognized in appearance. Therefore, even if it is determined that the protein is normal and an experiment is performed, there is a concern that a correct experimental result cannot be obtained.

The same is true for frozen foods. For example, if it is a frozen meat lump, it is essential to be transported while maintaining the frozen state, but if the freezer breaks down or is left outside the freezer, the frozen will melt and gravy Flows out and the quality is significantly reduced.
However, even in the melted state, when it is returned to the freezer and cooled again, it returns to the original frozen meat in appearance.

Therefore, there is a thermal indicator as an instrument for visually confirming that such a situation has occurred.
The heat-sensitive indicator disclosed in Patent Document 1 has a protrusion made of a film that is depressed when pressed with a finger, and a colored hot-melt material is contained in a recessed space surrounded by the film. Under the recess is an absorbent that can penetrate the colored hot-melt material.
Patent Document 1 discloses two specific embodiments.
In the first embodiment, a colored hot-melt material is held on a carrier, and the carrier is arranged in a recessed space surrounded by a film.
In 1st embodiment of patent document 1, the heat-sensitive indicator is frozen and the colored hot-melt material hold | maintained at the support | carrier is solidified. In use, the above-described protrusion is pushed from above to break the bottom of the film, and the carrier holding the colored hot-melt material is dropped onto the absorber.
When the temperature of the environment where the heat-sensitive indicator is placed is high, the colored hot-melt material melts and penetrates into the absorber. By measuring the distance of the colored hot-melt material that has penetrated the absorber, it can be determined whether or not the temperature of the article has been maintained within a certain range.

Moreover, in 2nd embodiment disclosed by patent document 1, only the coloring heat-meltable substance is incorporated in the recessed part enclosed with the film. The carrier is disposed under the recessed space. An absorber is provided under the carrier.
In the second embodiment of Patent Document 1, the heat-sensitive indicator is frozen to solidify only the colored hot-melt material. In use, the protrusion is pushed from above to break the bottom of the film, and the solidified hot-melt material is dropped onto the carrier.
When the temperature of the environment where the heat sensitive indicator is placed is high, the colored hot-melt material is melted and absorbed by the carrier. Then, the colored hot-melt material penetrates from the carrier to the absorber. By measuring the distance of the colored hot-melt material that has penetrated the absorber, it can be determined whether or not the temperature of the article has been maintained within a certain range.

Japanese Patent No. 3077093

  The thermal indicator disclosed in Patent Document 1 has a problem that the accuracy of determination is lacking. That is, the thermal indicator disclosed in Patent Document 1 has low reliability.

That is, the heat-sensitive indicator is used while being enclosed with an article to be kept at a low temperature, but the contact state between the colored heat-meltable substance and the absorber changes depending on the posture of the heat-sensitive indicator.
For example, when an article to be kept at a low temperature and a heat sensitive indicator disclosed in Patent Document 1 are put in an insulated box containing dry ice, and transported in that state, during transportation, vibration, etc. The attitude of the thermal indicator changes.
Here, the heat-sensitive indicator disclosed in Patent Document 1 is premised to be used in a state where a projection made of a horizontal film is turned up, but the top and bottom are reversed during transportation. There is also.
That is, the recessed space may be down and the absorber may be up. In such a case, even if the temperature in the heat insulation box rises and the colored hot-melt material melts, the colored hot-melt material may remain in the lower concave space and may not come into contact with the absorber. Therefore, although the colored hot-melt material is melted, the colored hot-melt material does not penetrate into the absorber.

For example, when checking the cold state of a frozen meat chunk in a vacuum pack, it is assumed that a heat sensitive indicator is directly attached to the pack of frozen meat chunks. Cannot be maintained in a horizontal position.
Under such circumstances, the heat-sensitive indicator of the prior art has low reliability.

  An object of the present invention is to develop a highly reliable thermal indicator by paying attention to the above-mentioned problems of the prior art.

  The invention described in claim 1 for solving the above-described problem is a main body member, an ink occlusion body impregnated with an ink adjusted to have a melting point of a desired temperature, and occluded in the ink occlusion body. The ink storage member and the ink lead-out member are integrated via the main body member, and the ink storage member and the ink lead-out member are moved relative to each other. When not in use, the ink lead-out member and the ink occlusion body are in a non-contact state, and the ink occlusion body and the ink lead-out member are moved relative to each other, and either the ink lead-out member or the ink occlusion body is inserted into the other to store the ink. It is a thermal indicator characterized by being able to make a body and an ink derivation member contact.

  The thermal indicator of the present invention inserts one of the ink lead-out member or the ink occlusion body into the other and brings the ink occlusion body and the ink lead-out member into contact with each other. it can.

  In the invention according to claim 2, the ink occlusion body is disposed in an occlusion body case that does not transmit ink, and a part of the occlusion body case has a low strength planned breakage part, and the ink lead-out member moves. The ink lead-out member and then the ink lead-out member is moved, the ink lead-out member breaks through the planned destruction portion, and a part of the ink lead-out member is inserted into the ink case and the ink lead-out member. The heat-sensitive indicator according to claim 1, wherein the heat-sensitive indicator can be brought into contact with each other.

  In the heat-sensitive indicator of the present invention, the ink occlusion body is disposed in the occlusion body case that does not transmit ink, so that ink does not leak.

  In the invention according to claim 3, the main body member has an accommodating space therein, the ink occlusion body and the ink outlet member are accommodated in the accommodating space, and the ink outlet member is movable in the accommodating space, The main body member has a push member, a part of the push member is exposed to the outside, and can be engaged with the ink lead-out member in the accommodation space, and the ink lead-out member moves by operating the push member. The heat-sensitive indicator according to claim 1 or 2, wherein

  In the heat sensitive indicator of the present invention, a part of the push member is exposed to the outside, and the ink lead-out member can be moved by operating the push member. Therefore, the user can insert the ink lead-out member into the ink occlusion body without touching the ink lead-out member.

  According to a fourth aspect of the present invention, the main body member has a window portion through which the interior can be seen through and a concealing portion through which the inside can not be seen through. The thermal indicator according to any one of claims 1 to 3, wherein the thermal indicator is provided at a position where it cannot be seen.

Although the usage method of a thermal indicator is not limited, It is desirable to freeze a thermal indicator after inserting one of an ink derivation member or an ink occlusion body in the other.
When such a usage is employed, when one of the ink lead-out member or the ink occlusion body is inserted into the other, the ink in the ink occlusion body is liquid. Therefore, the ink begins to be led out to the ink lead-out member. However, since the thermal indicator is frozen after that, the derivation of ink to the ink derivation member stops.
The main body member employed in the heat-sensitive indicator of the present invention has a window portion through which the inside can be seen and a concealing portion through which the inside can not be seen through, and the window portion is a position where a part of the ink outlet member can be seen and the ink occlusion body cannot be seen. Is provided. Therefore, a small amount of ink is led out to the ink lead-out member immediately after one of the ink lead-out member or the ink occlusion body is inserted into the other, but that portion is hidden by the concealing portion of the main body member and cannot be seen.

  The heat sensitive indicator of the present invention has an effect that it is more reliable than the conventional one.

It is a perspective view of the heat-sensitive indicator of embodiment of this invention, Comprising: The state at the time of storage is shown. It is a perspective view of the thermal indicator of FIG. 1, Comprising: The state at the time of use is shown. It is a front view of the thermal indicator of FIG. 1, Comprising: The state at the time of storage is shown. It is sectional drawing of the heat sensitive indicator of FIG. 1, Comprising: The state at the time of storage is shown. It is sectional drawing of the heat sensitive indicator of FIG. 1, Comprising: The state at the time of use is shown. It is a disassembled perspective view of the thermal indicator of FIG. It is a disassembled perspective view of an ink accommodating part. It is a front view of the thermal indicator of other embodiment of this invention. It is a front view of the thermal indicator of other embodiment of this invention. It is a front view of the thermal indicator of other embodiment of this invention, Comprising: The state at the time of storage is shown. It is sectional drawing of the heat sensitive indicator of FIG. 10, Comprising: The state at the time of storage is shown. It is sectional drawing of the thermal indicator of FIG. 10, Comprising: The state at the time of use is shown. It is a perspective view of the heat sensitive indicator of other embodiment of this invention. It is a cross-sectional perspective view of the thermal indicator of FIG. It is the table | surface which listed the typical solvent. It is the table | surface which listed the typical solvent.

Embodiments of the present invention will be further described below.
The thermosensitive indicator 1 of the present embodiment has a main body case (main body member) 2, and the ink container 3 and the ink outlet member 5 are all housed in the main body case 2 and a part of the push member 22 is accommodated. The remaining part of the member 22 protrudes from one end of the main body case 2.

Hereinafter, description will be made sequentially.
The main body case 2 has a hollow cylindrical shape and has an accommodating space 6 therein.
As shown in FIGS. 1 and 6, the main body case 2 is configured by combining two members. That is, the main body case 2 is constituted by the absorber housing portion 7 and the push member housing portion 8.

The absorber accommodating portion 7 is a long and thin cylinder and has a bottom. That is, the absorber housing portion 7 is elongated, one end side is opened, and the other end side is closed.
Although most of the absorber accommodating portion 7 is opaque, there is a window portion 11 in a part, and only the window portion 11 is transparent so that the inside of the main body case 2 can be seen from the outside.
The push member accommodating portion 8 is a long and thin cylinder. Both ends of the push member accommodating portion 8 are open. However, an inner flange 17 is provided on one end side of the push member accommodating portion 8.
A notch portion 18 is provided on the other end side of the push member accommodating portion 8. The position of the notch 18 is a position corresponding to the position of the window 11 when the push member accommodating portion 8 is attached to the absorber accommodating portion 7.

The ink containing portion 3 has an elongated cylindrical shape as shown in FIG. The outer diameter of the ink container 3 is smaller than the inner diameter of the absorber container 7 described above.
The ink storage unit 3 includes an occlusion body case 13, an ink occlusion body 15, and a sealing member 16.
The occlusion body case 13 is a cylinder made of a resin sheet that does not allow liquid ink to pass through and does not allow gas vaporized by the ink to pass through. The occlusion body case 13 is closed at one end and is open at the other end. Although the resin sheet on which the occlusion body case 13 is made is thin, it has considerable strength and elasticity and is not easily destroyed.

The ink occlusion body 15 is obtained by rounding cotton, mat, felt, or a fiber sheet. The ink occlusion body 15 is mainly made of fibers and can be said to be a lump of fibers.
The ink occlusion body 15 is soaked with ink described later.

The ink occlusion body 15 is inserted into the occlusion body case 13, and the opening of the occlusion body case 13 is sealed with a sealing member 16.
The sealing member 16 is made of a material that does not allow the liquid ink to pass through or the gas that the ink vaporizes. The sealing member 16 can be easily broken, or is made of a material that penetrates easily by pushing a needle-like or bar-like member.
In this embodiment, the sealing member 16 is made of aluminum foil. The sealing member 16 is a weaker part than other parts, and is a part to be destroyed.

In this embodiment, the ink lead-out member 5 is a fiber bundle. The ink lead-out member 5 has an elongated rod shape and has a sharp tip. The outer diameter of the ink outlet member 5 is smaller than that of the ink container 3. That is, the outer diameter of the ink lead-out member 5 is not more than one-third of the outer diameter of the ink containing portion 3.
The ink lead-out member 5 is a bundle of a large number of thin fibers. The ink lead-out member 5 employed in the present embodiment has sufficient rigidity to withstand a certain amount of compressive force, and does not cause compressive failure or buckling even if a certain amount of compressive force is applied while holding both ends.
The fiber constituting the ink lead-out member 5 has a yarn density higher than that of the ink occlusion body 15. Therefore, the ink lead-out member 5 can exhibit a stronger capillary force than the ink occlusion body 15. Further, the ink absorbed by the ink outlet member 5 is visible from the outside.

In this embodiment, a fiber bundle is used as the ink lead-out member 5, but the ink lead-out member 5 is not limited to the fiber bundle. For example, a material used as a pen tip for a writing instrument or a marker can be directly used as a material for the ink lead-out member 5. Specifically, the ink lead-out member 5 can be made by using a porous sintered body (for example, a marker chip of a marker), resin, paper, felt or the like in which pores are formed.
In any case, it is desirable that the ink lead-out member 5 can exhibit a stronger capillary force than the ink occlusion body 15.

  The push member 22 is an elongated cylindrical member. The outer diameter of the push member 22 is smaller than the inner diameter of the push member accommodating portion 8. Although most of the push member 22 is solid, a recess 20 is provided on one end side.

Next, the ink soaked in the ink occlusion body 15 will be described.
Ink is a mixture of a dye or pigment in a solvent, and is colored. The ink is adjusted so that the melting point becomes a desired temperature according to the purpose.
That is, a material that melts at a temperature according to the purpose is selected as the solvent for the ink.
The solvent of the ink is not limited, and those mainly composed of water, those mainly composed of alcohol, and organic solvents can be used. Moreover, these may be blended suitably or additives, such as sodium chloride, may be added, and melting | fusing point may be adjusted using a molar freezing point fall.
The main solvents and melting points are summarized in the tables of FIGS.

Next, the assembly structure of the thermal indicator 1 of this embodiment will be described.
In the present embodiment, the main body case 2 is formed by combining the absorber housing portion 7 and the push member housing portion 8, and the housing space 6 is formed in the main body case 2.
An ink storage unit 3 is built in one end of the storage space 6. More specifically, the ink container 3 is built in the main body case 2 on the absorber container 7 side.
The accommodation direction of the ink accommodating portion 3 is as shown in FIG. 4 and is arranged in a posture in which the sealing member (destroy planned portion) 16 side faces the push member accommodating portion 8 side.

An ink lead-out member 5 is arranged in a position that is linearly adjacent to the ink storage portion 3 in the storage space 6 of the main body case 2.
Further, a push member 22 is arranged at a position linearly adjacent to the ink lead-out member 5. The side of the push member 22 where the recess 20 is provided is in the housing space 6 of the main body case 2, and the other end projects out of the housing space 6.
That is, the push member accommodating portion 8 is a cylindrical body whose both ends are open, and the push member 22 projects outward from the open end.
The push member 22 has a protrusion (not shown), and the protrusion of the push member 22 engages with the inner flange 17 of the push member accommodating portion 8, so that the push member 22 does not come out of the main body case 2. Further, the end portion of the ink outlet member 5 is engaged with the concave portion 20 of the push member 22.
The window portion 11 provided in the absorber housing portion 7 is closer to the push member 22 than the boundary between the ink housing portion 3 and the ink outlet member 5, and the ink housing portion 3 cannot be seen from the window portion 11.

In the present embodiment, as described above, the ink lead-out member 5 is provided at the ink containing portion 3 and the position in the containing space 6 of the main body case 2. In addition, there is a part of the push member 22 in the housing space 6 of the main body case 2.
The ink container 3, the ink outlet member 5, and the push member 22 are collected as one member via the main body case 2. That is, the ink storage unit 3, the ink lead-out member 5 and the push member 22 are in the storage space 6 and cannot be taken out unless disassembled.
The ink outlet member 5 and the push member 22 are movable in the axial direction within the main body case 2.

Next, the usage method of the thermal indicator 1 of this embodiment is demonstrated.
As shown in FIG. 4, the thermal indicator 1 is stored in a state where the ink lead-out member 5 is arranged at a position linearly adjacent to the ink containing portion 3, and the ink lead-out member 5 is not pierced into the ink containing portion 3. The

And the thermal indicator 1 of this embodiment pushes the push member 22 just before use. As a result, the ink lead-out member 5 is pushed by the push member 22 and linearly moves toward the ink containing portion 3, and the tip thereof contacts the sealing member (destroy planned portion) 16 of the ink containing portion 3. When the push member 22 is further pushed, the ink lead-out member 5 further advances, and the tip breaks through the sealing member (destroy planned portion) 16 as shown in FIG.
Here, since the ink occlusion body 15 is built in the ink container 3, the tip of the ink lead-out member 5 is inserted into the ink occlusion body 15.
Therefore, the ink lead-out member 5 is surely in contact with the ink in the ink occlusion body 15.

In this state, the thermal indicator 1 is frozen, and the ink absorbed in the ink occluding body 15 is frozen.
When the ink is frozen, the thermal indicator 1 is placed close to an article whose temperature history is desired (hereinafter, an article to be detected). For example, it is placed in an insulated box together with a frozen artificial pluripotent stem cell. Alternatively, the heat sensitive indicator 1 is fixed to a pack of frozen meat chunks with tape or the like.

Then, the detected article is stored or transported.
When the detected article is kept at a desired low temperature during storage or transportation, the ink absorbed in the ink occlusion body 15 of the thermal indicator 1 is also kept frozen. Therefore, the ink is not led out to the ink lead-out member 5. Therefore, even if the thermal indicator 1 is taken out and the window portion 11 is viewed, coloring with ink is not recognized.
It should be noted that a certain amount of ink is generated immediately after the push member 22 is pushed to break through the sealing member (scheduled destruction portion) 16 of the ink containing portion 3 and the ink lead-out member 5 is inserted into the ink occlusion body 15 until the ink freezes. It is led out to the ink lead-out member 5. However, in the present embodiment, since the window portion 11 is located away from the base end portion into which the ink lead-out member 5 is inserted, the portion that has moved to the ink lead-out member 5 and changed its color before the ink is frozen is outside. I can't see it. Therefore, there is no trouble for the user.

  In addition, when the ambient temperature rises during storage or transportation and the article to be detected is not kept at a desired low temperature, the ink absorbed in the ink occlusion body 15 of the thermal indicator 1 is melted. The leading end of the ink lead-out member 5 is inserted into the ink occlusion body 15 and the ink lead-out member 5 is surely in contact with the melted ink occlusion body 15 so that the ink lead-out member 5 leads out the ink. As a result, the portion of the ink lead-out member 5 that is visible from the window portion 11 is discolored by the ink. Therefore, the user knows the fact that the article to be detected was not kept at the desired low temperature.

Further, in the heat sensitive indicator 1 of the present embodiment, the ink is absorbed by the ink occlusion body 15. Therefore, regardless of the posture of the thermal indicator 1, the ink is distributed substantially uniformly in the ink occlusion body 15.
That is, regardless of how the attitude of the thermal indicator 1 changes, the ink is distributed substantially uniformly in the ink occlusion body 15. The ink lead-out member 5 is stuck into the ink occlusion body 15. Therefore, when the ink in the ink occlusion body 15 is melted and liquefied, the ink contacts the ink lead-out member 5 and is led to the ink lead-out member 5 regardless of the attitude of the thermal indicator 1 at that time.
Therefore, the thermal indicator 1 of the present embodiment can accurately know the temperature history of the detected article regardless of the posture.

  In addition, as shown in FIG. 8, by providing a plurality of window portions 11, or by increasing the length of the window portion 11 as shown in FIG. Therefore, it is possible to roughly know the time when the article to be detected was not maintained in the low temperature state and the temperature at that time.

In the embodiment described above, the window portion 11 is formed in a part of the main body case 2 in the longitudinal direction and the circumferential direction, but may be the window portion 11 extending over the entire circumference of the main body case 2. The thermal indicator 50 shown in FIGS. 10 to 12 has a window portion 52 that extends over the entire circumference of the main body case 51.
In the heat sensitive indicator 50 shown in FIGS. 10 to 12, the main body case 51 includes an absorber housing portion 57, a push member housing portion 58, and a window forming portion 60 as shown in FIG. 11. The window forming portion 60 is located between the absorber housing portion 57 and the push member housing portion 58.
The absorber housing portion 57 and the push member housing portion 58 are opaque, but the window forming portion 60 is made of a transparent resin.
Therefore, the ink lead-out member 5 in the window forming portion 60 can be seen through.

The push member 61 employed in the heat sensitive indicator 50 includes a finger rest 62 and a shaft 63. One end 65 of the shaft portion 63 has an outer diameter larger than that of other portions, and slides on the inner wall of the push member housing portion 58.
The push member 61 employed in the thermal indicator 50 is different in shape from the above-described embodiment, but has the same function and is movable in the axial direction within the main body case 51.
Also in the present embodiment, by pushing the push member 61 immediately before use, the ink lead-out member 5 moves linearly to the ink containing portion 3 side, and the tip contacts the sealing member (destroy planned portion) 16 of the ink containing portion 3. To do. When the push member 61 is further pushed, the ink lead-out member 5 further advances, and the tip breaks through the sealing member (destroy planned portion) 16 and enters the ink containing portion 3 as shown in FIG.

The heat-sensitive indicator 1 of the above-described embodiment has a rod shape and can be said to be a pencil type, but the present invention is not limited to this shape.
For example, it may be a sheet shape or a card shape.
The thermal indicator 30 shown in FIGS. 13 and 14 is card-shaped.
The heat sensitive indicator 30 has a main body member 32 formed of two resin sheets 31a and 31b.
One resin sheet 31a is formed with a slide slit 35 and a window 36. The

The two resin sheets 31a and 31b are joined only at the peripheral sides, and the central portion is not bonded. Therefore, there is a storage space 40 between the resin sheets 31, and the ink storage body 33, the ink outlet member 37, and the push member 38 are incorporated therein.
One end of the push member 38 is engaged with the ink outlet member 37. A part of the push member 38 is engaged with the slide slit 35 and guided so as to move only in the linear direction. A part of the push member 38 is exposed from the slide slit 35.

  Also for the thermal indicator 30 of the present embodiment, the push member 38 is pushed immediately before use, the ink lead-out member 37 is advanced, and a part of the ink lead-out member 37 is inserted into the ink occlusion body 33.

  The embodiments described above have the push members 22 and 38, but the push members 22 and 38 are not essential. That is, the user may move the ink lead-out members 5 and 37 directly by hand and insert them into the ink storage members 15 and 33.

Moreover, although embodiment described above showed the example which moves the ink derivation members 5 and 37 and inserts it in the ink occlusion bodies 15 and 33, it moves the ink occlusion bodies 15 and 33, and the ink derivation members 5 and 37. May be inserted into the ink occlusion bodies 15 and 33.
That is, a configuration in which the ink storage members 15 and 33 are inserted into the ink lead-out members 5 and 37 is also possible.

1 Thermal indicator 2 Body case (body member)
3 Ink storage part 5 Ink outlet member 6 Storage space 11 Window part 15 Ink occlusion body 16 Sealing member (destructed part)
22 Push member 30 Thermal indicator 33 Ink occlusion body 36 Window portion 37 Ink outlet member 38 Push member 40 Storage space 50 Thermal indicator 51 Main body case (main body member)
52 Window part 61 Push member

Claims (4)

  A main body member, an ink occlusion body soaked with ink adjusted to have a desired melting point, and an ink lead-out member capable of deriving the ink occluded in the ink occlusion body to the outside of the ink occlusion body by capillary action The ink occlusion body and the ink lead-out member are integrated via the main body member, and the ink occlusion body and the ink lead-out member can be moved relative to each other. In the contact state, the ink occlusion body and the ink outlet member can be moved relative to each other, and the ink occlusion body and the ink outlet member can be brought into contact by inserting one of the ink outlet member or the ink absorber into the other. Heat sensitive indicator.   The ink occlusion body is arranged in an occlusion body case that does not transmit ink, and a part of the occlusion body case has a low-strength planned destruction portion, and the ink lead-out member is moved to contact the ink occlusion body case. Furthermore, it is possible to move the ink lead-out member, break through the planned destruction portion with the ink lead-out member, and insert a part of the ink lead-out member into the ink storage case to bring the ink storage member into contact with the ink lead-out member. The heat-sensitive indicator according to claim 1.   The main body member has a storage space therein, the ink storage member and the ink outlet member are stored in the storage space, the ink outlet member is movable in the storage space, the main body member has a push member, The push member is partially exposed to the outside, can be engaged with the ink lead-out member in the accommodation space, and the ink lead-out member moves by operating the push member. Or the heat sensitive indicator of 2.   The main body member has a window portion where the inside can be seen through and a concealing portion where the inside can not be seen through, and the window portion is provided at a position where a part of the ink lead-out member can be seen and the ink occlusion body cannot be seen. The thermal indicator according to any one of claims 1 to 3.

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