TW201310031A - Tester capable of continuously measuring temperature rising/dropping of textile - Google Patents

Abstract

Disclosed is a tester capable of continuously measuring temperature rising/dropping of textile, suitable for simultaneously comparing the temperature alteration of at least two textiles to be tested. The tester capable of continuously measuring temperature rising/dropping of textile includes a temperature source apparatus capable of changing the temperature of textiles to be tested, a temperature sensing module, a retaining apparatus for samples to be tested, and a frame. The temperature sensing module is capable of continuously inspecting and recording the temperature alteration of textile to be tested. The temperature source apparatus, the temperature sensing module, and the retaining apparatus for samples to be tested are installed in the frame, such that the temperature source apparatus allows the textile to be tested to produce an effect of temperature rising or dropping, and to continuously inspect the temperature alteration of the textile to be tested via the temperature sensing module, thereby developing the effect of simultaneously comparing the temperature alterations of plural textiles to be tested.

Description

Tester for continuous measurement of fabric temperature rise and fall

The invention relates to a tester, in particular to a tester capable of continuously measuring the temperature rise and fall of a fabric.

As the earth heats up, the temperature rises every summer. Therefore, the textile industry is dedicated to the development of various functional fabrics to meet the different needs of users for heat dissipation, cooling, daylight shielding or warmth.

A method of assessing whether a fabric to be tested has an instant cooling effect is proposed. The touch feeling of warmth or coolness (Q-max) is a feeling of cooling when the human body touches the fabric to be tested, and the instantaneous heat loss on the skin surface is felt. . In this way, a fabric of a size of 20 cm×20 cm is placed on a cold plate at a constant temperature of 25° C., and a hot plate of 35° C. is placed flat on the fabric to be tested, and the hot plate is measured at the same time. The heat removed through the fabric to be tested in 0.2 seconds is in units of watt/cm ² .

Since the method uses heat conduction to compare the heat of the fabric to be tested in an instant, it is impossible to know the heat absorption and heat dissipation effect of the fabric to be tested in a high temperature or low temperature environment for a long time, and cannot be simultaneously performed. Comparison of multiple pieces of fabric to be tested.

Accordingly, it is an object of the present invention to provide a tester having a continuous measure of the temperature rise and fall of the fabric while simultaneously comparing the temperature changes of the plurality of fabrics to be tested.

Therefore, the present invention can continuously measure the temperature rise and fall of the fabric, and is suitable for simultaneously comparing the change of the temperature of at least two fabrics to be tested, and the tester for continuously measuring the temperature rise and fall of the fabric comprises changing the temperature of the fabric to be tested. The temperature source device, a temperature sensing module, a fixture to be tested, and a frame.

The temperature sensing module can continuously detect and record the temperature change of the waiting fabric, and the temperature source device, the temperature sensing module, and the fabric fixing device to be tested are disposed on the frame body.

The effect of the invention is that the temperature source device can generate the temperature rise or the temperature drop of the waiting fabric, and the temperature sensing module continuously detects the temperature change of the fabric under waiting, and simultaneously generates a plurality of comparisons. The effect of the temperature change of the workpiece to be tested.

The above and other technical contents, features and advantages of the present invention will be apparent from the following detailed description of FIG.

Before the present invention is described in detail, it is noted that in the following description, similar elements are denoted by the same reference numerals.

Referring to Figure 1, the present invention can continuously measure the temperature rise and fall of the fabric, and is suitable for simultaneously comparing the changes of the temperatures of the two fabrics 1 and 2 to be tested.

The first preferred embodiment of the tester for continuously measuring the temperature rise and fall of the fabric comprises a temperature source device 3 for changing the temperature of the fabric 1 and 2, a temperature sensing module 4, a shielding member 5, and a waiting device. The workpiece fixing device 6 and a frame body 7.

The temperature sensing module 4 includes a temperature sensing unit 41 and a data processing unit 42 . The data processing unit 42 has a display element 421 . The waiting fabric 1 and 2 are fixed to the DUT fixture 6.

The temperature source device 3, the shielding member 5, the device to be tested 6 and the temperature sensing unit 41 of the temperature sensing module 4 are disposed on the frame body 7, and the device to be tested fixture 6 and the shielding member 5 are disposed. The temperature source device 3 is disposed between the temperature sensing device 4 and the temperature sensing unit 41 of the temperature sensing module 4, and the shielding member 5 is disposed between the temperature source device 3 and the device under test fixture 6.

The temperature sensing unit 41 of the temperature sensing module 4 can instantly detect the temperature change of the waiting fabric 1 and 2, and transmit the sensed group of data to the data processing unit 42, the data of the temperature sensing module 4 The processing unit 42 can continuously record the data transmitted by the temperature sensing unit 41 at different times, and process the data into a graph, which is then presented by the display element 421.

In the first preferred embodiment, the waiting fabrics 1 and 2 are respectively a functional fabric and a standard fabric, and the fixture fixing device 6 includes a hollow frame, and the temperature source device 3 is a heat temperature. The element 31 is a halogen lamp, whereby the difference in the heat insulating effect of the fabrics 1 and 2 is awaited when the sunlight is irradiated on the waiting fabrics 1, 2. The temperature sensing unit 41 is an infrared thermal imager. The data processing unit 42 is a computer. The infrared thermal imager is electrically connected to the computer through a transmission line. The display element 421 is a display. It is worth mentioning that the thermal element 31 can be a projection lamp, and the temperature sensing unit 41 can also transmit the data to the data processing unit 42 by wireless transmission, and the display element 421 can also be a projector. .

When the tester for continuously measuring the temperature rise and fall of the fabric is used, the user first places the waiting fabrics 1 and 2 side by side and fixes them on the frame of the device to be tested 6, and then adjusts the shield 5 The position is such that the shield member 5 does not block the temperature source device 3 from illuminating the waiting fabrics 1, 2. The temperature sensing unit 41, the data processing unit 42, and the power of the display element 421 of the temperature sensing module 4 are turned on, so that the temperature sensing unit 41 of the temperature sensing module 4 can pass through the hollow of the device to be tested 6 The frame starts to detect and record the temperature change of the lower surface of the waiting fabric 1 and 2. It should be noted that the temperature source device 3 and the temperature sensing unit 41 should respectively align with the boundary of the waiting fabrics 1, 2, so that the frame Waiting for the measured fabrics 1, 2 to be uniformly heated at the same time, and simultaneously detecting the temperature change of the waiting fabrics 1, 2, as shown in Annex 1, is an infrared thermal image obtained by the computer measuring the infrared thermal imager. (As shown in the upper left figure), after processing, the instantaneous temperature of the two sampling points is displayed separately (as shown in the upper right figure), and the temperature change of the sampling points in the continuous time state is displayed by the graph (as shown in the lower left figure). At this time, the power of the thermostat element 31 has not been turned on, and the temperature of the standard fabric can be measured to be 26.7 ° C, and the temperature of the standard fabric and the functional fabric are not significantly different from the graph.

Finally, the power of the thermostat element 31 is turned on to increase the temperature of the waiting fabrics 1, 2, as shown in the attachment 2, indicating that the temperature of the standard fabric and the functional fabric increases with the irradiation time, and at this time, The temperature of the standard fabric was measured to be 43.9 ° C, and the temperature and temperature rise rate of the standard fabric and the functional fabric were significantly different from the chart, thereby, the present invention can continuously measure the temperature rise and fall of the fabric. A simple comparison of the effect of waiting for the difference in the insulation effect of the fabrics 1 and 2 is achieved.

Alternatively, the power of the thermostat element 31 can be turned off again, and the temperature of the fabric 1 and 2 is returned to room temperature. As shown in FIG. 3, the temperature of the standard fabric and the functional fabric is gradually decreased. The temperature of the standard fabric was measured to be 33.4 ° C, and it was shown by the graph that the temperature of the standard fabric and the temperature of the functional fabric and the temperature drop rate were significantly different, thereby comparing the difference in the heat dissipation effect of the fabrics 1 and 2 waiting for the test.

In this way, the user can continuously observe the temperature change of the waiting fabrics 1 and 2 by the display element 421 of the temperature sensing module 4, thereby generating an effect of simultaneously comparing the temperature changes of the waiting fabrics 1 and 2.

It is worth mentioning that when the user wants to replace the waiting fabric 1 and 2, only the position of the shielding member 5 needs to be adjusted, so that the shielding member 5 blocks the temperature source device 3 from being irradiated to the waiting fabric 1, 2 and the The temperature sensing unit 41 produces an effect of simple operation.

Referring to FIG. 2, a second preferred embodiment of the present invention is similar to the first preferred embodiment, and the main difference is that the waiting fabrics 1, 2 are a functional fabric and a standard fabric, respectively. The temperature source device 3 is a cold temperature element 32, which is a nitrogen cold source, and the temperature of the waiting fabrics 1 and 2 is lowered by opening the cold temperature element 32, as shown in Annex 4 and Annex 5. , indicating that the temperature of the functional fabric and the standard fabric decreases as the cooling time increases, and the temperature of the functional fabric is respectively measured to be 0.5 ° C and -1.9 ° C, and the standard fabric and the functional fabric are shown by a graph. The temperature and the temperature drop rate are also significantly different, whereby the tester for continuously measuring the temperature rise and fall of the fabric of the present invention achieves a simple comparison of the effect of waiting for the difference in the cooling effect of the fabrics 1 and 2. Alternatively, the cold temperature element 32 can be turned off to return the temperature of the waiting fabrics 1, 2 to room temperature, thereby simulating the difference in the cooling effect of the fabrics 1 and 2 in the cold weather.

Thus, the second preferred embodiment can achieve the same purpose and effect as the first preferred embodiment described above, and can also produce a simple operation effect by rapidly changing different temperature source devices 3, and can generate temperature. The effect of the rise or temperature drop test.

Referring to FIG. 3 and FIG. 4, a third preferred embodiment of the present invention is similar to the first preferred embodiment, and the main difference is that the waiting fabrics 1 and 2 are respectively a functional fabric and a standard. a fabric, the temperature sensing unit 41 of the temperature sensing module 4 and the hot temperature element 31 are on the same side of the device to be tested 6, and the thermal element 31 is obliquely irradiated to the device to be tested 6 to make the temperature The component 31 does not block the temperature sensing unit 41 of the temperature sensing module 4 from detecting the temperature of the upper surface of the fabric 1 and 2.

Therefore, the third preferred embodiment can achieve the same purpose and effect as the first preferred embodiment, and the temperature sensing unit 41 of the temperature sensing module 4 can detect the waiting fabric 1 and 2. The upper surface temperature, thereby simulating the difference between the heat absorption and the heat dissipation effect of the fabrics 1 and 2 while simulating the sunlight to the test fabrics 1, 2, and generating different test modes, as shown in Annex 6, The temperature of the functional fabric and the standard fabric increases as the irradiation time increases, and the temperature of the functional fabric is measured to be 43.7 ° C, respectively, and the temperature and temperature of the standard fabric and the upper surface of the functional fabric are shown by a graph. The rising speed also produces a significant difference, whereby the tester for continuously measuring the temperature rise and fall of the fabric of the present invention achieves a simple comparison of the difference in the heat absorption and heat dissipation effects of the fabric 1 and 2.

Alternatively, the temperature sensing unit 41 of the temperature sensing module 4 and the thermal temperature element 31 are on the opposite side of the device to be tested 6, as shown in FIG. 5, whereby the temperature sensing unit of the temperature sensing module 4 41 can detect the temperature of the lower surface of the fabric 1 and 2, and achieve the same purpose and effect as described above. It is worth noting that the above test method can compare the temperature difference between the upper surface and the lower surface of the same fabric to be tested, thereby understanding the heat insulation and heat dissipation effect of the fabric to be tested. For example, thicker fabrics and thinner fabrics have better insulation effect, so the upper and lower surface temperatures are different at the beginning of the test, but the upper surface temperature is similar to that of the thinner fabric; For example, a fabric with a thin fabric has a small difference in temperature between the upper and lower surfaces, but the overall temperature is relatively low, so that the functional fabric has better heat insulation effect and less heat absorption. , more heat, thus achieving a lower overall temperature.

In summary, the present invention can continuously measure the temperature rise and fall of the fabric, and the following effects and advantages can be obtained, so that the object of the present invention can be achieved:

1. The present invention uses the temperature sensing module 4 to continuously observe the temperature changes of the waiting fabrics 1, 2, and produces an effect of simultaneously comparing the temperature changes of the waiting fabrics 1, 2.

2. The present invention can adjust the position of the shielding member 5 so that the shielding member 5 blocks the temperature source device 3 from being irradiated to the waiting fabric 1 and 2 and the temperature sensing unit 41, and can replace the waiting fabric 1 and 2 It produces the effect of simple operations.

3. The present invention utilizes the temperature source device 3 as a heat source element 31 or a cold source element 32, which can be quickly replaced to produce a simple operation, and which can perform a temperature rise or temperature drop test.

4. The present invention measures the temperature sensing unit 41 of the temperature sensing module 4 and the temperature source device 3 on the same side or opposite side of the device to be tested 6, and the temperature source device 3 obliquely reflects the device to be tested. The device 6 is fixed to produce a different test mode.

The above is only the preferred embodiment of the present invention, and the scope of the invention is not limited thereto, that is, the simple equivalent changes and modifications made by the scope of the invention and the description of the invention are All remain within the scope of the invention patent.

1. . . Fabric to be tested

2. . . Fabric to be tested

3. . . Temperature source device

31. . . Hot temperature element

32. . . Cooling element

4. . . Temperature sensing module

41. . . Temperature sensing unit

42. . . Data processing unit

421. . . Display component

5. . . Shield

6. . . DUT fixture

7. . . Frame

1 is a front elevational view of a first preferred embodiment of a tester for continuously measuring the temperature rise and fall of a fabric according to the present invention;

2 is a front elevational view of a second preferred embodiment of the tester for continuously measuring the temperature rise and fall of the fabric according to the present invention;

3 is a front elevational view of a third preferred embodiment of the tester for continuously measuring the temperature rise and fall of the fabric according to the present invention;

Figure 4 is a side view of the third preferred embodiment; and

Figure 5 is a side elevational view of the third preferred embodiment illustrating the temperature sensing unit of a temperature sensing module and a thermal element on the opposite side of the device to be tested.

Annex 1: The test result of the two fabrics to be tested when the power supply of the thermal element is not turned on according to the first preferred embodiment of the present invention.

Attachment 2: The test result of the fabric to be tested when the power supply of the thermal element is turned on according to the first preferred embodiment of the present invention.

Annex 3: The test result of the two fabrics to be tested when the power supply of the thermal element is turned off according to the first preferred embodiment of the present invention.

Annex 4: Test result of two fabrics to be tested when a cold temperature element is opened in the second preferred embodiment of the present invention.

Annex 5: Test result of two fabrics to be tested when a cold temperature element is continuously opened in the second preferred embodiment of the present invention.

Annex 6: The test result of the two fabrics to be tested when the power of the thermostat element is turned on according to the third preferred embodiment of the present invention.

1. . . Fabric to be tested

2. . . Fabric to be tested

3. . . Temperature source device

31. . . Hot temperature element

4. . . Temperature sensing module

41. . . Temperature sensing unit

42. . . Data processing unit

421. . . Display component

5. . . Shield

6. . . DUT fixture

7. . . Frame

Claims (6)

The utility model relates to a tester capable of continuously measuring the temperature rise and fall of a fabric, which is suitable for simultaneously comparing the change of the temperature of at least two fabrics to be tested, and the tester for continuously measuring the temperature rise and fall of the fabric comprises: changing the temperature of the temperature of the fabric to be tested a source device; a temperature sensing module capable of continuously detecting and recording the temperature change of the fabric to be tested; a fixture to be tested; and a frame, the temperature source device, the temperature sensing module, and the to be tested A fixture is disposed on the frame. The tester for continuously measuring the temperature rise and fall of the fabric according to the first aspect of the patent application, wherein the temperature sensing module comprises a temperature sensing unit and a data processing unit. The tester for continuously measuring the temperature rise and fall of the fabric according to the second aspect of the patent application, wherein the data processing unit has a display element. The tester for continuously measuring the temperature rise and fall of the fabric according to the first aspect of the patent application, wherein the temperature source device is a hot temperature element or a cold temperature element. The tester for continuously measuring the temperature rise and fall of the fabric according to any one of claims 2 to 4, wherein the fixture fixing device is disposed at the temperature source device and the temperature sensing of the temperature sensing module Between units. The tester for measuring the temperature rise and fall of the fabric according to the third aspect of the patent application, wherein the temperature source device is a hot temperature element, and the temperature sensing unit of the temperature sensing module and the temperature source device are The same side of the fixture to be tested.