JP6034975B2 - Test method and test system for submerged pressure resistance of bimetal waterproof thermostat - Google Patents

Description

The present invention relates to the field of pressure resistance testing of thermostats, and more particularly, to a soaking pressure resistance test method and system for a bimetal-element waterproof thermostat.

In the conventional technology, when a thermostat pressure test is performed, the thermostat is placed in a V-shaped groove and the thermostat is placed in the air. When the pressure tester detects that the thermostat product is defective, the pressure tester issues an alarm. The worker can judge that the product is defective based on the alarm. In order to improve the detection speed, there are a plurality of thermostat samples to be detected in the V-shaped groove, and the worker cannot visually determine which product is defective in the plurality of thermostat samples. Therefore, it is difficult to quickly and accurately distinguish a defective thermostat from a good thermostat, which is disadvantageous for improving production efficiency.

For this reason, the conventional technology has room for improvement and development.

In contrast to the above-described drawback of low detection efficiency in the prior art, it is a technical object of the present invention to provide a test method and a test system for the submerged pressure resistance performance of a bimetal waterproof thermostat. According to the test method, a defective thermostat exhibits remarkable flashover, flash, and other phenomena in water, thereby quickly distinguishing a defective thermostat from a good thermostat.

The present invention uses the following technical solutions in order to solve the technical problems.

A method for testing a submerged pressure resistance performance of a bimetal waterproof thermostat, which includes the following steps.

A. A step of immersing the thermostat body in a first metal container in which water is accommodated, and immersing the metal terminal portion of the thermostat lead in a second metal container in which water is accommodated.

B. A step of bringing a grounding clip connected to a pressure tester into contact with the first metal container, and a test probe of a test bar connected to the pressure tester being brought into contact with the second metal container.

C. The step of determining that the thermostat body immersed in the first metal container is defective when detecting the flash of the thermostat body in the first metal container.

The step B further includes adjusting the leak current of the withstand voltage tester to 1 milliampere and adjusting the test voltage of the withstand voltage tester to AC power 2100V.

Before the step A, it is further included to put pure water or distilled water into the first metal container and the second metal container.

Before the step A, a first insulating groove for storing the first metal container is further placed under the first metal container, and a second metal container is stored under the second metal container. Including placing an insulating groove.

Or, in a submersible pressure resistant test system used for a bimetal waterproof thermostat, a pressure resistant tester, a test bar and a grounding clip connected to each of the pressure resistant testers, and a first metal container for housing the thermostat body And a second metal container for housing the metal terminal portion of the thermostat conductor,

When the ground clip is brought into contact with the first metal container, the test probe of the test bar is brought into contact with the second metal container, and the flash of the thermostat body in the first metal container is detected, It is determined that the thermostat body immersed in the first metal container is defective.

The test system further includes a first insulation groove for housing the first metal container under the first metal container, and a second insulation for housing the second metal container under the second metal container. Including placing a groove.

The current of the withstand voltage tester is adjusted to 1 milliampere, and the test voltage of the withstand voltage tester is adjusted to 2100 V AC.

The water in the first metal container and the second metal container is pure water or distilled water.

The water in the first metal container and the second metal container is pure water or distilled water.

According to the test method and test system of the submerged pressure resistance performance of the bimetal waterproof thermostat provided by the present invention, the test probe is used to immerse the metal terminal portion of the thermostat body and the thermostat conductor in a metal container in which water is accommodated. When the pressure resistance test of the thermostat is performed in contact with the water, the defective thermostat causes the flashover or flash to appear in the water, and the phenomenon of flashover or flash Can be observed very remarkably. Workers can detect defective thermostats as good ones very quickly, improving the thermostat production efficiency.

FIG. 1 is a step flow chart of a relatively preferred embodiment of the test method for the submerged pressure resistance performance of the bimetal waterproof thermostat of the present invention. FIG. 2 is a schematic diagram showing the structure of a test system for submerged pressure resistance used in the bimetal waterproof thermostat of the present invention.

In order to make the objects, technical solutions and advantages of the present invention clearer and clearer, the present invention will be described in more detail with reference to the drawings. It should be noted that the specific examples described here are merely used to explain the present invention, and the present invention is not limited thereto.

Referring to FIG. 1, FIG. 1 is a step flow chart of a preferred embodiment of the test method of the submerged pressure resistance performance of the bimetal waterproof thermostat of the present invention.

First, in step 101, water is poured into the first metal container and the second metal container. In this preferred embodiment, the material of the first metal container and the second metal container is made of stainless steel, and in actual production, the manufacturer can make the metal container another material as necessary. It is only necessary that can be conducted. Also, it should be noted that the water injected into the metal container is pure water or distilled water. The water depth is preferably 70 mm to 80 mm. Further, in order to ensure the reliability of the result of detecting the thermostat by ensuring the conductivity of the water in the stainless steel container, the water in the stainless steel container needs to be replaced every 8 hours.

In step 102, the thermostat body is immersed in a first metal container in which water is stored, and the metal terminal portion of the thermostat conductor is immersed in a second metal container in which water is stored. That is, the worker can bend 7 to 10 products to an angle of about 45 degrees so that the thermostat main body and the metal terminal portion of the conductive wire are completely immersed in water.

In step 103, the pressure resistance tester is activated. That is, the power switch of the withstand voltage tester is turned on, and the withstand voltage tester uses a conventional technique, and detailed description thereof is omitted here.

In step 104, the preset switch of the withstand voltage tester is turned on and the leakage current is adjusted. That is, after turning on the preset switch, the operator checks whether or not the leak current is within a predetermined range, and in the preferred embodiment, sets the leak current to 1 milliampere. When the leakage current is not 1 milliampere, an operator adjusts the leakage current by twisting the preset switch with a screwdriver.

In step 105, the switch of the withstand voltage test bar connected to the withstand voltage tester is turned on and the test voltage is adjusted. That is, the switch of the test bar is turned on, and it is checked whether or not the test voltage matches a predetermined numerical value. In this preferred embodiment, the test voltage reference is set to AC 2100V. When the test voltage does not match the reference, the operator manually twists the voltage adjustment switch and adjusts the voltage to a predetermined value, that is, AC voltage 2100V.

After adjusting the pressure tester data, step 106 is entered where the grounding clip contacts the first metal container. Among them, the grounding clip is connected to a pressure tester.

In step 107, the test probe contacts the second metal container.

In step 108, if a defective product is found, it is immediately isolated. That is, when it is detected that the thermostat body in the first metal container is flashed, flashover, or the thermostat body is broken down, the thermostat body immersed in the first metal container is Judged as defective.

In step 109, the thermostat that has passed the detection is dried.

In the process of performing the above steps, the time for immersing the thermostat body and the metal terminal portion of the thermostat conductor in the first metal container or the second metal container is 60 seconds.

That is, when detecting whether or not the thermostat is a good product, a voltage is applied to the test bar, so that all the water contained in the metal container can conduct electricity, and the pressure resistance of the thermostat is poor. The thermostat immersed in water is broken down by the voltage of the test probe. The effect of the breakdown is that the portion of the defective thermostat located in the water expresses flashover or flash, and the worker can use the flashover or flash. ), It is possible to determine which thermostat is defective very quickly, thereby improving the detection efficiency of the thermostat.

In a specific application, a first insulating groove for storing the first metal is further provided under the first metal container, and a second insulating for storing the second metal is provided under the second metal container. It is preferable that a groove is provided. Since the water in the metal container is at high pressure, water may flow out of the cup during the detection process, and when the operator removes the tested thermostat from the metal container, water with high voltage in the metal container is also present. It is taken out and easily injured humans, and by installing an insulating groove to store the metal container under the metal container, water in the metal container can flow into the insulating groove regardless of whether it flows out or taken out, Does not hurt humans. Of course, an insulating groove may be provided under the first metal container and the second metal container.

A submerged pressure resistance test system for a bimetal waterproof thermostat, which will be described in detail below with reference to FIG. 2 for a submerged pressure resistance test system for a bimetal waterproof thermostat provided by the present invention. FIG. 2 is a view showing the structure of a preferred embodiment of a test system for submerged pressure resistance used in the bimetal waterproof thermostat of the present invention.

In FIG. 2, a test system 201 for submerged pressure resistance performance used in a bimetal waterproof thermostat includes a pressure resistance tester 202, and the pressure resistance tester is a conventional technique, and thus detailed description thereof is omitted here. Furthermore, a test bar 205 and a grounding clip 206 connected to the pressure tester 202, a first metal container 203 for storing a thermostat body, and a second metal container 204 for storing a metal terminal portion of a thermostat conductor are included.

The ground clip 206 is brought into contact with the first metal container 203, the test probe of the test bar is brought into contact with the second metal container 204, and the flash of the thermostat main body in the first metal container 203 is detected. Then, the thermostat body immersed in the first metal container 203 is determined to be defective.

The test system for the submerged pressure resistance performance of the thermostat further includes a first insulating groove for storing the first metal placed under the first metal container 203, and the second metal placed under the second metal container 204. A second insulating groove is included. Among them, the effect of installing the insulating groove is to prevent the water in the metal container from flowing out and coming into contact with humans during the detection process, and to avoid hurting workers. Of course, an insulating groove may be provided under the first metal container and the second metal container.

The leak current of the withstand voltage tester 202 is adjusted to 1 milliampere, and the test voltage of the withstand voltage tester is adjusted to 2100 V AC.

In addition, pure water or distilled water is put into the first metal container and the second metal container.

More preferably, the submerged pressure resistance performance test system used in the bimetal waterproof thermostat can further measure whether or not the insulation resistance of the thermostat meets the requirements, and when testing the immersion resistance performance of the thermostat, the test of the insulation resistance tester is performed. A bar test probe is brought into contact with the second metal container. As a result, it is determined whether or not the pointer of the insulation resistance tester is within the specified range. If it is within the range, the sample is determined to be acceptable, and if it is not within the specified range, the sample is determined. Is determined to be rejected.

When this preferred embodiment is applied to the detection of a thermostat, that is, when detecting the insulation resistance of the thermostat, when the number indicated by the pointer is 500 MΩ or more, it is determined that the thermostat to be detected is acceptable and is less than 500 MΩ. Sometimes it is determined that the thermostat to be detected is rejected.

As described above, according to the present invention, when the thermostat main body and the metal terminal portion of the thermostat conductor are immersed in a metal container in which water is contained, the ground clip is brought into contact with the metal container in which the metal terminal portion of the thermostat conductor is placed by the test probe. When there is a defective thermostat sample in contact with the metal container in which the thermostat body is placed, the defective thermostat will show a flashover or flash phenomenon in the water during work. As a result, a defective thermostat is quickly separated from a good thermostat, thereby improving production efficiency.

The present invention is not limited to the above-described embodiments, and those skilled in the art can make modifications or variations based on the above description, and all these modifications or variations are included in the protection scope of the present invention.

Claims (8)

Steps A to C below
A. A step of immersing the thermostat body in a first metal container in which water is stored, and immersing the metal terminal portion of the thermostat lead in a second metal container in which water is stored
B. A step of bringing a grounding clip connected to a pressure tester into contact with the first metal container, and a test probe of a test bar connected to the pressure tester being brought into contact with the second metal container
C. When a flash phenomenon is detected in the thermostat body in the first metal container, the thermostat body immersed in the first metal container is determined to be defective. Test method for water pressure resistance of bimetal waterproof thermostat. 2. The bimetal waterproof thermostat according to claim 1, wherein the step B further includes a step of adjusting a leakage current of the withstand voltage tester to 1 milliampere and adjusting a test voltage of the withstand voltage tester to an AC voltage of 2100 V. 3. Test method for submerged pressure resistance. The submerged pressure resistant performance of the bimetallic waterproof thermostat according to claim 1, further comprising putting pure water or distilled water into the first metal container and the second metal container before the step A. Test method. Before the step A, a first insulating groove for storing the first metal container is placed under the first metal container, and a second metal container for storing the second metal container is placed under the second metal container. The test method of the submerged pressure resistance performance of the bimetallic waterproof thermostat according to claim 1, further comprising placing two insulating grooves. A pressure tester, a test bar and a grounding clip connected to each of the pressure testers, a first metal container for storing a thermostat body, and a second metal container for storing a metal terminal portion of a thermostat conductor,
When the grounding clip is brought into contact with the first metal container, the test probe of the test bar is brought into contact with the second metal container, and the flash of the main body of the thermostat in the first metal container is detected, the first metal A test system for submerged pressure resistance performance of a bimetal waterproof thermostat characterized in that the thermostat body immersed in the container is determined to be defective. The test system includes:
A first insulating groove that is installed under the first metal container and that houses the first metal container;
6. The test system for submerged pressure resistance performance of a bimetal waterproof thermostat according to claim 5, further comprising a second insulating groove that is installed under the second metal container and that accommodates the second metal container. . 6. The test system for a submerged pressure resistance performance of a bimetal waterproof thermostat according to claim 5, wherein a leakage current of the withstand voltage tester is adjusted to 1 milliampere, and a test voltage of the withstand voltage tester is adjusted to an AC voltage of 2100V. 6. The test system for submerged pressure resistance performance of a bimetallic waterproof thermostat according to claim 5, wherein water in the first metal container and the second metal container is pure water or distilled water.