KR101157943B1 - Precision Critical Temperature Indicator and Manufacturing Method Thereof - Google Patents

Abstract

The precision critical temperature indicator according to the present invention accommodates the development material in the center and is operated by the operation of the movement path and the operation button of the development material connected in a horizontal plane with respect to the operation button and the operation button made of a molded layer which protrudes in a hemispherical shape at the center. The developing material member, the developing material member, and the developing medium member which are provided alone or together with a buffer part of a compartment for buffering the moving speed of the moving material being moved, and forming a plurality of display windows in an arc shape around the operation button to enable temperature display. It consists of a boundary layer which is positioned between and forms a speed control window for controlling the moving speed of the developing material and a developing medium member which forms a developing passage connected to the speed control window of the developing material, which is a sealing sheet composed of a plurality of base layers. , Printing member sheet consisting of a plurality of printing layers for temperature display, a plurality of microporous film A development medium member sheet formed of a media member and a plurality of boundary layer sheets separately formed with a speed control window are prepared, and these sheets are thermally fused to a single sheet based on a heat-adhesive portion forming a development passageway of the development material. The mating sheet is formed with a forming layer of moving passages and cushioning portions which apply adhesive to all parts except the inner circular part of the development passage of the developing material and the display window on the plurality of boundary layers and are horizontally connected to the operation button or the operation button. It is produced by thermally fusion bonding a plurality of sheets on an adhesive layer.

Developing material member, developing medium member, operation button, display window, speed control,

Description

Precision Critical Temperature Indicator and Manufacturing Method {Precision Critical Temperature Indicator and Manufacturing Method Thereof}

The present invention relates to a precision critical temperature indicator, comprising a developing material member having an operating button filled with a developing material and a developing medium member having a double working path of the developing material to determine whether accurate temperature sensing display is made. A precise critical temperature indicator which makes it possible and a manufacturing method thereof are provided.

A representative of the prior art is a product named 3M's "Monitor Mark", in which a temperature indicator is commercially available. As shown in FIG. 1, the critical temperature indicator 10 includes a developing material layer 11 which is allowed to react and diffuse above a set temperature and a developing medium layer 12 which absorbs a solvent from the developing material layer 11. Equipped. The developing material layer 11 is a temperature sensor layer made of ink, fatty acid, paraffin, or the like, and the developing medium layer 12 is made of an ink absorbent paper or a nonwoven fabric. A blocking layer 13 is positioned between the developing material layer 11 and the developing medium layer 12. Below the developing material layer 11 is a support layer 14 and a double-sided adhesive tape 15. The display layer 16 having the display window is positioned above the development medium layer 12. The display layer 16 has a rather large display window 16 'at a position of the development medium layer 12, and a plurality of display windows 16 ", which are somewhat smaller, are formed in the longitudinal direction. The transparent coating layer 17 is positioned on the display layer 16.

On the other hand, the development medium layer 12, the display layer 16 and the transparent coating layer 17, the cut portions 18 of the same size are formed at the same position on one side. These cuts 18 are bonded to each other by applying an adhesive to the bottom. The temperature indicator 10 configured as described above is attached to the support layer 14 on the double-sided adhesive tape 15. The developing material layer 11 and the developing medium layer 12 arranged in the longitudinal direction with the blocking layer 13 therebetween are arranged on the supporting layer 14. The display layer 16 is placed on the blocking layer 13 with the display windows 16 'and 16 "positioned on the development medium layer 12, and the transparent coating layer 17 on the display layer 16. This position is where the assembly of the temperature indicator 10 takes place.

The temperature indicator therefore attaches the adhesive portion to the refrigerated product at the bottom of the double-sided adhesive tape 15, removes the cut 18 and removes the barrier layer 13 so that the developing material layer 11 and the developing medium layer 12 are removed. Make sure they are connected in close contact with each other. Thereafter, the temperature indicator 10 moves as the development material layer 11 starts to operate as the ambient temperature rises, soaking into the development medium layer 12 while melting ink and fatty acid or paraffin, etc., having a pigment, and moving the display window 16. ') And (16 ") indicate the storage status of the product.

However, such a temperature indicator is large in size because the development medium operates in the longitudinal direction, and requires a great care to remove the barrier layer between the development medium layer and the development material layer, and it is difficult to automate. In addition, the temperature indicator is exposed to the developing material without sealing, so it should be cooled for 1 ~ 2 hours before use at the melting point or below. If the product is inadvertently exposed to room temperature, the developing material will be melted and removed when removing the barrier. It has the disadvantage of coming out. In particular, such a strip type has a disadvantage in that the farther the development material is from the starting point when the development material is deployed in one direction, the slower the deployment speed is, and thus the error range for the confirmation time is large.

Another representative of the prior art is disclosed in US Pat. No. 7,232,253 (Publication 2004/0240324, 2004.12.02), which discloses a time indicator and a method of making the same, wherein the time indicator moves a first reservoir, a moving medium and a liquid. An actuating means is provided for contacting the medium and transporting it from the first reservoir to allow the liquid to move through the moving medium causing color change therein after operation. The actuating means has a second reservoir connected between the first reservoir and the moving medium, whereby after operation the liquid moves at a relatively high speed from the first reservoir to the second reservoir and then relatively slow along the length of the moving medium. Let's move on.

This patent is characterized by a visible indication of the life of the product, but during operation, the liquid, which becomes the developing material, moves in the liquid conduit and then comes into contact with the moving medium and operates in the longitudinal direction, so that the path of the liquid is dualized for accurate time. The elapsed rate cannot be measured, and the placebo seal is installed in a state of blocking the liquid conduit so that the actuating means (plate type) serving as the first reservoir is operated by a constant force and destroyed. However, this placebo seal has the disadvantage that it is often inadvertently broken and liquids come out when the moving medium is operated in the first reservoir by means of actuation. Therefore, this time indicator is also difficult to pinpoint when to expose the cooling environment.

In view of these points, it is desirable if the threshold temperature indicator has an operating mechanism capable of confirming the accuracy of the operation from the point of use to the automatic point of view so that the situation of the management from the time of shipment of the product to the point of conversion can be known.

In addition, it is very desirable to use not only easy to use, but also a simple structure that can be applied to small frozen and refrigerated products and at the same time mass production.

In view of this point, the main object of the present invention is to provide an accurate temperature sensing display by having a single body and having an operation button filled with a developing material member and a developing medium member having a double working path of the developing material member. The present invention relates to a precise critical temperature indicator and a method of manufacturing the same.

It is still another object of the present invention to provide a precision critical temperature indicator and a method for manufacturing the same, which allow arbitrary control of the contact between the operation button filled with the developing material member and the developing medium member formed in a separated state.

Still another object of the present invention is to provide a structure that allows the development material member and the deployment medium member to be separated easily before use, so that a large amount of automatic production is possible and the handling is easy to handle so that it can be stored and stored at room temperature, and a manufacturing method thereof. It is about providing.

According to one embodiment of the invention, the precision critical temperature indicator is provided with an operation button made of a molded layer to receive a development material in the center and protrude in a hemispherical shape in the center and to form a plurality of display windows in an arc around the operation button A development material member enabling a temperature display, a boundary layer positioned between the development material member and the development medium member and forming a speed control window for controlling the movement speed of the development material and a development passage connected to the speed control window of the development material. And a development medium member, wherein a plurality of display windows at predetermined positions of the development material member are moved along the movement path on the development medium member coupled to both sides thereof while the development material member is guided and filled by the operation button to the speed control window. To indicate the threshold temperature detection.

In the adhesive layer positioned between the developing material member and the boundary layer, no adhesive is applied to the portion corresponding to the operation button and the speed control window, and the developing material member is a microporous film, and the development passage of the developing material is folded with the speed control window. The speed control window is hot-pressed in a circular ring shape with a display area formed adjacent to the development passage on a diameter line.

According to an embodiment of the present invention, the manufacturing method of the precision critical temperature indicator is a development medium formed of a sealing sheet consisting of a plurality of base layers, such as a silver foil, a printing sheet for displaying the temperature, the development medium is made of a microporous film A plurality of boundary layer sheets having a member sheet and a speed control window formed separately are prepared, and these sheets are thermally fused based on a heat-adhesive portion forming a development passageway of the developing material, and the sheets are combined into a single sheet. Applying an adhesive to all parts except the inner circular part of the development passage of the development material and the display window on the boundary layer, and thermally fusion bonding a sheet of a plurality of development material members having a hemispherical shaping layer containing the development material on the adhesive layer. It consists of

According to still another embodiment of the present invention, the precision critical temperature indicator stores the development material therein and includes an operation button formed of a molded layer protruding in a hemispherical shape at the center, and extending the development material horizontally by a predetermined distance from the operation button of the molding layer. A moving passage which enables the flow of the circumference, and a plurality of display windows in an arc around the operating button and a buffer portion formed of a compartment that temporarily connects to the moving passage and temporarily receives the developing material against the force of pressing the operation button and buffers the function. Developing material member consisting of a; A boundary layer positioned directly below the upper developing material member and forming a speed control window connected to a moving passage of a medium formed in the buffer part; A development medium member comprising a microporous film formed of a heat-adhesive portion except for a development passage extending from the movement passage; A printed layer printed in green on a portion of the speed control window, blue on a display area of the display windows, yellow on both sides of the display window, and red on the other display window; It is composed of a base layer which is located at the bottom and seals so that the operation time and the critical temperature are displayed on the display window formed at the top.

The developing material member has display windows cast in a circular or rectangular shape around the periphery of the operation button, and a moving passage having the same shape as the display window in which the developing material flows horizontally extending from the operating button toward the outlet. Consists of one or more compartments, which are connected to the passageway to receive the development material first and cushion against the force of pushing the actuation button.

According to another embodiment of the present invention, the manufacturing method of the precision critical temperature indicator is formed of a sealing sheet consisting of a plurality of base layers, such as a silver foil, a printing sheet for displaying the temperature, the medium development is made of a microporous film A plurality of boundary layer sheets each having a development medium member sheet and a speed control window are separately prepared, and these sheets are thermally fused based on a heat-adhesive portion that forms a development passageway of the development material, and are mated into a single sheet. An operation button consisting of a forming layer which applies adhesive to all parts except the inner circular part of the developing passage of the developing material and the display window on a plurality of boundary layers, and stores the developing material in the center and protrudes in a hemispherical shape at the center, and the operation of the forming layer. A movement passage extending horizontally from the button to allow the flow of the developing material, the movement A seat of a plurality of developing material members, consisting of a plurality of display windows in a circular arc around an operating button and a buffer portion consisting of a compartment, which is connected to a passageway and temporarily receives the developing material against a force of pressing the operating button and buffers the function. Is thermally fused onto the adhesive layer.

The present invention is to keep the development material member and the deployment medium member in the normal isolation and control the force applied to the development material of the operation button in use to guide the medium to the deployment passage or to buffer the buffer portion in the shape of the deployment passage of the deployment medium member As a result, the critical temperature display can be delayed controlled and it is not necessary to cool below the critical temperature before use.

The present invention will be described in detail with reference to the accompanying drawings.

According to one embodiment of the invention, as shown in Figures 2 and 3, the precision critical temperature indicator 20 is formed of a single body, the development material member 30 is located on the top. The developing material member 30 is made of synthetic resin such as PET or PVC, and has an operating button 32 formed of a molding layer A having a developing material 31 therein and protruding in a hemispherical shape at the center thereof. A plurality of display windows, i.e., a left display window 33 formed at regular intervals to the left based on the display window 38, and a right display window 34 formed at regular intervals to the right around the operation button 32; It is possible to display the temperature developed in both directions.

An adhesive member 40 composed of an adhesive layer B is applied to a lower portion of the developing material member 30 to bond the intermediate member 50 composed of the boundary layer C to be described later. The adhesive member 40 is formed as a space 41 to which the adhesive is not applied to a portion corresponding to the operation button 32 and the speed control window 51 to function as a movement path of the development material 31.

 The intermediate member 50 is located between the development medium member 60, which will be described later, is formed as a movement path of the deployment material 31, and a speed control window 51 for adjusting the movement speed is formed at one corner thereof.

The developing medium member 60 is formed of a obtainable microporous film which is transparent by the developing material 31 and the developing passage 61 which connects the developing material 31 to the speed control window 51 in the operation button 32. The display portions 62 which become a ring-shaped shape and a final development site which becomes a destination of the development passage 61 on one side of the speed control window 51 on the diameter line and the other side are partitioned and then hot pressed.

The precision critical temperature indicator 20 further includes a printing member 70 serving as the printing layer E. The printing member 70 is green and left and right display windows 33 in accordance with the portion of the speed control window 51. And blue on the development passage 61, which becomes the display portion region of 34, yellow on both sides of the display windows 36 and 37 on the final deployment portion, and red on the display window 35 of the display portion 62 of the final deployment portion. It is configured to print in color to indicate the time of operation and the critical temperature indication. This printing member 70 may be formed on a sealing member 80 which is a separate layer or which becomes the base layer F described later.

The developing material member 30 may be made of a synthetic resin such as transparent PET or PVC, and the intermediate member 50 may be made of PE or EVA.

The precision critical temperature indicator 20 is operated as shown in FIG. 4 and is first attached to a frozen or refrigerated product to be operated (1). As the operation button 32 is pressed, the deployment material 31 moves along the space 41 formed as a movement path, and passes through the speed control window 51, so that the deployment medium member 60 becomes transparent. The green display window 38 printed on the lower printing member 70 appears to indicate the start of operation (2). Thereafter, the developing material 31 is applied to both ends of the developing passage 61 to move in both directions of the developing passage 61 to start developing (3). The developing material 31 is then developed over time so that the left and right display windows 33 and 34 are displayed in blue (3) and (4). In the subsequent development process, the display windows 36 and 37 are displayed in yellow (5) to warn, and further red display in the display window (35) indicates that the frozen and refrigerated products are in a dangerous range. (6), it is possible to display the temperature from the time when the operation of the precision threshold temperature indicator 20 to the final step.

Such precision critical temperature indicator 20 is a sealing sheet consisting of a plurality of sealing members 80, a printing member sheet consisting of a plurality of printing members 70 for temperature display, the medium development passage is made of a microporous film Intermediate sheet sheets comprising a developing medium sheet having a plurality of developing medium members having 61 and a plurality of boundary layers C having the speed control window 51 formed thereon are prepared, and these sheets are formed into a developing material ( 31 is thermally fused based on the heat-adhesive portion forming the development passage 61 of 31) and mated into a single sheet, wherein the mating sheet has an interior of the deployment passage 61 of the deployment material 31 on a plurality of intermediate members 50. Applying the adhesive to all parts except the circular part and the display window, and thermally fusion bonding the sheet composed of the plurality of developing material members 30 having the hemispherical molding layer containing the developing material 31 on the adhesive layer. .

According to another embodiment of the present invention, the precision critical temperature indicator 20 is composed of a single body as shown in FIGS. 5 and 6. Since the precise critical temperature indicator 20 is the same as that of the first embodiment except for the developing material member 30, the description thereof is omitted and the developing material member 30 will be mainly described.

The developing material member 30 has an operating button 32 made up of a forming layer A which accommodates the developing material 31 therein and protrudes in a hemispherical shape at the center thereof, and has an arc shape around the operating button 32. A plurality of display windows, that is, the left display window 33 and the warning display window 36 formed at regular intervals to the left, the right display window 34 and the warning display window 37 and the danger display window formed at regular intervals to the right ( 35) to enable temperature display in both directions. The actuating button 32 is provided with a moving passage 31a adjacent to it and extending horizontally therefrom to enable the flow of the deploying material and connected to the moving passage 31a and pressing the operating button 32. A buffer portion 39 is formed, which is a compartment for temporarily accommodating the developing material 31 with respect to the buffer function.

On the other hand, the inside of the operation button 32 may be filled with a developing material 31, preferably mixed with an ink having a fat-soluble pigment, in this embodiment a transparent developing material such as fatty acid ester is used.

Therefore, the developing material member 30 causes the primary material to flow into the buffer portion 39 that becomes the empty space compartment via the moving passage 31a at the pressure according to the pressing of the operation button 32, wherein the buffer portion 39 functions to cushion a part of the pressure. Here, the movement passage 31a is formed of a placebo portion between the operation button 32 and the buffer portion 39 having a small contact area and is easily separated.

The manufacturing method of such a precision critical temperature indicator is also made of a sealing sheet consisting of a plurality of sealing members 80, a printing member sheet consisting of a plurality of printing members 70 for temperature display, a microporous film, and a development material ( 31. An intermediate member sheet including a development medium sheet having a plurality of development medium members 60 having a development passage 61 formed therein and a plurality of boundary layers C having separately formed a speed control window 51 is prepared. These sheets are thermally fused to a single sheet based on a heat-adhesive portion forming the deployment passageway 61 of the deployment material 31, and the deployment material 31 is disposed on a plurality of intermediate members 50 in the registration sheet. A sheet of a plurality of developing material members 30 having a hemispherical shaping layer for applying the adhesive to all the portions except the inner circular portion and the display window of the developing passage 61 and containing the developing material 31 is formed on the adhesive layer. Heat fused to It composed of planes.

1 is an exploded perspective view showing an example of the prior art in detail;

2 is an overall perspective view showing a precision critical temperature indicator according to an embodiment of the present invention,

3 is a cross-sectional view showing the components of the precision critical temperature indicator individually in cross section according to an embodiment of the present invention;

Figure 4 is a cross-sectional view showing the operating state by pressing the operation button when using the precision critical temperature indicator according to an embodiment of the present invention,

5 is an overall perspective view showing a precision critical temperature indicator according to another embodiment of the present invention;

6 is a side cross-sectional view of a precision critical temperature indicator according to another embodiment of the present invention;

7 is a side cross-sectional view showing the operation of a precision critical temperature indicator according to another embodiment of the present invention;

<Simple description of main drawing code>

20: precision critical temperature indicator 30: developing material member 40: adhesive member

50: intermediate member 60: development medium member 70: printing member

80: sealing member 31: developing material 32: operation button

33, 34, 36, 37, 38, 35: display window 39: buffer part 51: speed control window

Claims (7)

In precision critical temperature indicator, It is provided with an operation button 32 made of a molding layer (A) that accommodates the development material in the center and protrudes in a hemispherical shape in the center, and forms a plurality of display windows 33 to 38 in the circumferential arc of the operation button 32. Developing material member 30 that enables the temperature display, A boundary layer (C) positioned between the developing material member (30) and the developing medium member (60) and forming a speed control window (51) for controlling the moving speed of the developing material (31); And a development medium member 60 having a development passage 61 connected to the speed control window 51 of the development material 31. The developing material member 30 is guided and filled by the operation button 32 to the speed control window 51 and moves along the moving path on the developing medium member 60 coupled with both sides thereof, while the developing material member 30 is moved. Precision threshold temperature indicator, characterized in that for displaying the threshold temperature detection through a plurality of display windows (33 ~ 38). The method of claim 1, The adhesive layer (B) located between the developing material member (30) and the boundary layer (C) does not apply adhesive to a portion corresponding to the operation button 32 and the speed control window (51),  The developing material member 30 is a microporous film which is transparent by the developing material. The development passage 61, which is a movement path of the development material 31, becomes a space 41 which is in contact with the speed control window 51, and the development path 61 on the diameter line of the speed control window 51. Precision critical temperature indicator, characterized in that the hot pressing in the form of a ring with the display area 62 formed adjacent. The method of claim 1, The precision critical temperature indicator further includes a printing member 70 serving as the printing layer E, which is composed of green and display windows 33 and 34 at the portion of the speed control window 51. Precision threshold temperature indicator, characterized in that the display portion is configured to display the operating time and the threshold temperature by printing blue, yellow on both sides of the display window (36), (37), the display window (35) in red. In the manufacturing method of the precision critical temperature indicator, Prepare a sealing sheet made of silver foil and consisting of a plurality of base layers, a printing sheet for displaying a temperature, a sheet of developing medium member formed of a developing medium made of a microporous film, and a plurality of boundary layer sheets separately formed with a speed control window. and, These sheets are thermally fused to a single sheet based on a heat-adhesive portion forming a deployment passageway of the developing material, In the mating sheet, adhesive is applied to all parts except the inner circular part and the display window of the developing passage of the developing material on the plurality of boundary layers, A method of manufacturing a precision critical temperature indicator, characterized in that the sheet consisting of a plurality of developing material member having a hemispherical shaped layer for containing the developing material is thermally fused onto the adhesive layer. In precision critical temperature indicator, Extending the development material by horizontally extending a predetermined distance horizontally from the operation button 32 made of a forming layer (A), which accommodates the developing material 31 therein and protrudes in a hemispherical shape at the center, and the operating button 32 of the forming layer (A). A movement passage 31a for enabling the flow of the 31, a compartment connected to the movement passage 31a and configured to temporarily receive the deployment material 31 with respect to a force for pressing the operation button 39 to cushion the function. A developing material member 30 composed of a plurality of display windows 33 to 37 in an arc shape around the buffer portion 39 and the operation button 31; A boundary layer (C) positioned below the developing material member (30) and forming a speed control window (51) connecting the developing material (31) from the buffer portion (39) to the developing passage (61); A development medium member 60 made of a microporous film formed of a heat-adhesive portion except for the development passage 61 extending from the movement passage 31a; Printed layer printed in green on the speed control window 51, display area consisting of display windows 33 and 34, yellow on both sides of display windows 36 and 37, and red on display window 35 (E); Precision threshold temperature indicator, characterized in that the display is formed at the bottom of the base layer (F) to seal the operating time and the critical temperature display on the display window (33 ~ 37) formed on the top. The method of claim 5, The developing material member 30 extends toward the outlet in the center horizontally from the display windows 33 to 37 and the operating button 32 which have a circular or rectangular shape around the periphery of the operating button 32. A buffer consisting of a moving passage 31a having the same shape as that of the display windows 33 to 37 and one or more compartments connected to the moving passage 31a and accommodating the primary deployment material and functioning as a buffer against the force of pressing the operation button. Precision critical temperature indicator, characterized in that consisting of 39. In the manufacturing method of the precision critical temperature indicator, Prepare a sealing sheet made of tinfoil and consisting of a plurality of base layers, a printing sheet for displaying a temperature, a sheet of developing medium member formed of a medium developing part made of a microporous film, and a plurality of boundary layer sheets separately forming a speed control window. and, These sheets are thermally fused to a single sheet based on a heat-adhesive portion forming a deployment passageway of the developing material, In the mating sheet, adhesive is applied to all parts except the inner circular part and the display window of the developing passage of the developing material on the plurality of boundary layers, An operation button comprising a forming layer having a development material in the center and having a hemispherical shape protruding at the center, and a moving passage extending a predetermined distance horizontally from the operation button of the forming layer to enable the flow of the development material. On the adhesive layer, a sheet of a plurality of developing material members composed of a plurality of display windows in an arc shape around the operating button and a buffer portion configured to temporarily receive the developing material against a force for pressing the operating button and acting as a buffer. Method for producing a precision critical temperature indicator, characterized in that the step of heat fusion.

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