DE10021950A1 - Thermal stability indicator has state change sensor enclosed by thermal storage material whose mass can be varied, adjusted, with indicator arrangement connected to sensor on its surface - Google Patents

Abstract

The device consists of a sensor (4) whose state changes if the temperature exceeds or falls below the threshold and an indicator arrangement (3) connected to the sensor that changes its nature, especially its color, on contacting the sensor. The sensor is enclosed by a thermal storage material (1) whose mass can be varied and adjusted and that carries the indicator arrangement on its surface.

Description

The invention relates to a device for displaying the exceeding or falling below Limit temperature on a product, consisting of a sensor that detects when over or If the temperature falls below the limit, it changes its physical state and one indicator means related to the sensor, which upon contact with the sensor its nature, especially color, changes.

Temperature-sensitive products can have their quality-determining properties lose if they exceed or fall below temperature limits are exposed. Such products can be materials, technical textiles, chemical Products but also biological products such as biomaterial, food or Medication. The quality characteristics of such a product are up to its intended use only by storage at a certain Temperature or a certain temperature range (the temperature profile) to back up. There are findings on temperature for the individual product limits. Only if a critical temperature value exceeds an impermissible time Dwell time has an effect, a reduction in the quality of the product is to be expected. In order to a so-called shelf life limit has been exceeded, which leads to an irreversible Damage to original quality properties. Such quality-reducing Properties can show up in a change in hardness, elasticity,  Fragility and a., so that, for example, the resistance behavior of such temperature-sensitive products against later mechanical stress is adversely affected. This is true for semi-finished products such as. B. prepregs for Manufacture of fiber composite materials can be used. Prepregs are made with resin pre-impregnated fiber fabrics. Such prepregs only unfold with the process of Curing their final properties, which is achieved by chemical crosslinking of the Molecular chains take place. A basic storage of such prepregs Room temperature could not stop the curing process in the long run. First with cooling of the prepreg below a limit temperature is a deactivation of the chemical conversion processes in the material. The cooling corresponds to preservation of the desired product quality with regard to later processing of a prepreg.

A variety of such temperature sensitive products is below that Store at room temperature, d. H. they have to be cooled. From the manufacturer to the This cold chain is allowed to act up to the end producer or the end consumer (Storage and transport) should not be interrupted, otherwise with a Deterioration in the quality properties is to be expected, d. H. the product is degraded or spoiled with food. There is often one on the product Quality deterioration due to interruption of the cold chain is not due to visual inspection detect. That is disadvantageous. Direct evidence of improper storage directly  on the temperature-sensitive product is very often difficult, complex and expensive.

DE 83 25 136 U1 describes a device for displaying the over or under exceeding a predetermined limit temperature and consists of a meltable Substance whose melting point is equal to or close to the specified temperature - the sensor - and an absorbent substance - the indicator - the fusible Sensor on or next to the absorbent indicator in a compact and solid form Physical state, for example in the solidified state, is attached. Now the If the specified limit temperature is exceeded, this sensor melts. The one from the solidified sensor during the melting of liquid is easy to move absorbed by the indicator, the absorbent substance, which thereby Properties is changed. The easiest way to change the nature of the Indicator is a change in color. The sensor is therefore the substance that by moving to the indicator on which it causes the indication. task according to DE 83 25 136 U1, it is to design display devices so that they normal temperatures can be manufactured, stored and transported, and only later when the specified limit is exceeded or fallen short of Limit temperature maintain their display capability. The well-known technical solution has however, the disadvantage that when a limit is exceeded or undershot Limit temperature a permissible dwell time of the product in an impermissible Temperature cannot be taken into account.  

There is a permissible time the product stays at a critical one Temperature not taken into account. This applies in particular to the use of products who, due to their large physical mass, experience greater sluggishness when Show temperature changes, so that a longer stay at a critical Temperature would be possible and permissible.

The object of the invention is, at an interface of a cold chain between producers, Dealer and end producer or end consumer the recognizability of a quality reduction due to previous, impermissible temperature influence of a Product to improve further.

The task is solved according to the characteristic features of the Claim 1.

The sensor picked up by the device is of a thermal type Surround storage media. The thermal storage medium is capable accordingly its mass delayed absorption or release of thermal energy. This Delay is considered a dwell time. The mass of the thermal The storage medium is dimensioned in such a way that it is an equivalent for a permissible one Residence time of the product mass outside of a permissible temperature profile. The Mass of the thermal storage medium is changeable and to a mass value adjustable, which represents a desired dwell time.  

According to one embodiment, the storage means carries this on its surface Indicator means, which a connection between Indicator means and sensor enables.

The storage medium can be on the product surface or on a packaging for the Product attached. However, there is also the possibility that the storage means is formed by the product itself and accommodates the sensor and indicator means.

Is the product formed by a prepreg for the production of fiber composite In this special case, the sensor can be under the surface of the material Prepregs can be integrated and via a connection channel with one on the surface the indicator means attached to the prepreg.

The device according to the invention has the advantage that each product individually, i. H. can be individually thermally monitored. The dwell time of a product at Unter Breaking the cold chain outside the permissible temperature profile is possible using the Storage means and its dimensions can be set so that none Damage to the product occurs. The device enables a small, volume-saving design and is inexpensive to manufacture. Where is the product enables, its mass can be used advantageously as a storage means. The device has the advantage that it is independent of an energy supply and manipulation of the indicator is hardly possible.

An embodiment of the invention is shown in the drawing and in the following described in more detail. It shows

Fig. 1 shows a schematic structure of a thermal durability indicator.

Fig. 1 shows the basic structure of a device for indicating the exceeding or falling below a limit temperature on a product. This device is a so-called thermal durability indicator. The thermal durability indicator consists of a storage means 1 with a cavity 2 inside the storage means, an indicator means 3 and a sensor 4 . The indicator means 3 is attached to the surface of the storage means 1 and communicates with the cavity 2 via a connecting channel 5 . The room 2 contains the sensor 4 . Get the sensor with the indicator means 3 .

The indicator means 3 can be, for example, a known litmus paper. This litmus paper is attached to a visible location of the storage medium 1 . The attachment is such that no damage to the indicator means 3 is possible for the application in question. The sensor is located in close proximity to the indicator. The cavity 2 with the sensor 4 is preferably located in the middle of the storage medium 1 . The storage means 1 is preferably a solid body with a defined thermal conductivity, which envelops the sensor 4 . The cavity 2 of the storage medium 1 encloses the sensor 4 . The cavity 2 has a possibility of contact with the indicator means 3 . This contact option is, for example, a connecting channel 5 , which connects the cavity 2 with the indicator means 3 as a bore. To manufacture the cavity 2 , the storage medium 1 can advantageously be manufactured from two individual parts A and B, which are positively connected to one another during the final production of the storage medium 1 . The sensor 4 forms the thermally sensitive medium, which causes a change in the color of the indicator means 3 when a permissible temperature is exceeded or undershot. The sensor 4 can, for example, be a medium that a phase transition, for. B. experienced from solid to liquid. For example, 2-dodecanol from the group of alkanols could be mentioned as the medium. Above about 5 ° C, 2-dodecanol becomes liquid and the indicator agent 3 can then, for. B. discolor litmus paper by passing through the connecting channel 5 . According to another embodiment, a mixture of 1-hexadecanol and tetradecane could also be used. In particular, with shorter chain alcohols, discrete lower limit temperatures (than the room temperature) can be monitored.

By mixing z. B. different alcohols and alkanes could be set to any limit temperature via different proportions. The discoloration of the indicator means 3 is irreversible. The irreversible discoloration of the indicator means is tamper-proof and allows the one-time exceeding of the permissible temperature limit for the product to be displayed visibly.

The color change generated by the sensor 4 on the indicator means 3 is the visible sign that the maximum permissible storage temperature of a product has been exceeded and the product may no longer be used. The indicator means 3 could also be designed, for example, in the form of a lettering "goods spoiled".

The storage means 1 simulates the maximum permissible heat absorption by the product before there is a loss of quality. It is a thermal storage medium because it is able to absorb, store and release thermal energy from the environment. The absorption or release of the thermal energy takes place with a delay in a defined time, the dwell time. As a storage means 1 z. B. a defined volume of metal, e.g. B. aluminum that works due to its thermal storage capacity as a kind of time delay. The geometry, material and body mass of the storage medium can be used to define how long a limit temperature may be exceeded or undershot before it is displayed by the indicator means 3 by means of the thermally sensitive sensor 4 . The mass of the storage means 1 can be geometrically designed so that it can be adapted to the mass of a product. The mass build-up of the storage medium 1 E could, for example, take place in layers, each layer surrounding the sensor 4 having to be detachable from the layer underneath. Depending on the consumption of the product, the mass of the storage medium could thus be influenced and the permissible dwell time controllable. There is also the possibility of forming the storage means 1 from a liquid which can be stored in a chamber with a drain valve. The mass of the liquid can be changed by means of a drain valve.

The indicator agent 3 (e.g. litmus paper) is plated with the thermally sensitive sensor 4 (e.g. 2-dodecanol). The sensor 4 is integrated in the storage means 1 . This device, also called the thermal durability indicator, can be mounted directly on the product to be monitored.

If the shelf life indicator is integrated into the outer packaging of the product, the heat absorption behavior of the entire product to be monitored, including the outer packaging, can be simulated by dimensioning the storage means 1 .

An advantageous use of the shelf life indicator arises during manufacture of fiber composite materials. Such fiber composites are, for example used in aircraft construction. It must be in the manufacture of components for Aircraft made of fiber composite materials consistently exceed their quality standard the entire manufacturing phase is secured. A prepreg is one with resin pre-impregnated fiber fabric. Prepregs are stacked in different layers The layers are placed in different orientations to each other can. These prepregs are completely saturated with resin in a mold and the resin is cured in a special oven under vacuum. The curing takes place in an autoclave. The manufactured by the prepreg process Fiber composite materials must meet the high levels known for aircraft construction Possess quality standard. It is therefore the quality of the  Fiber composite material over the entire manufacturing process with certainty to exclude. For this purpose, prepregs for the period of Intermediate processing held in a certain temperature profile to be undesirable to avoid beginning hardening. Prepregs are in a temperature range stored at approx. -20 ° C. In the meantime processing a prepreg this is usually processed or assembled at room temperatures. there the cold chain is briefly interrupted within a permissible dwell time. It is It is very important for the final producer to know whether an intermediate editing of the Prepregs have suffered permanent quality damage to the injured To be able to exchange prepreg for an undamaged one. The thermal Shelf life indicator offers this information possibility considering one interruption of the cold chain for the permissible dwell time Intermediate processing.

Claims (5)

1. Device for indicating the exceeding or falling below a limit temperature on a product, consisting of a sensor which changes its physical state when the temperature exceeds or falls below a limit and an indicator means connected to the sensor, which changes its nature when it comes into contact with the sensor , in particular color, changes, characterized in that the sensor ( 4 ) is surrounded by a thermal storage means ( 1 ), the mass of which is changeable and adjustable. 2. Device according to claim 1, characterized in that the storage means ( 1 ) carries on its surface the indicator means ( 3 ) and by means of a connecting channel ( 5 ) there is a connection between indicator means ( 3 ) and sensor ( 4 ). 3. Device according to one of claims 1 and 2, characterized in that the storage means ( 1 ) is attached to the product surface or an outer packaging for the product. 4. Device according to one of claims 1 and 2, characterized in that the storage means ( 1 ) is formed by the product itself. 5. Device according to one of the preceding claims, wherein the product is formed by a prepreg for the production of fiber composite materials, characterized in that the sensor ( 4 ) is integrated under the surface of a prepreg and via a connecting channel ( 5 ) with one on the surface of the prepreg attached indicator means ( 3 ) is connected.