KR200440849Y1 - Resistivity sensor combining unit - Google Patents

Abstract

Interposed between the resistivity sensor and the union tee to couple both, and including a union nut, a back ferrule and a front ferrule, which are sequentially fitted to the resistivity sensor, wherein the back ferrule is sheared. The resistivity sensor fastening device which is fitted to the part and the rear end thereof is fitted to the union tee, and a part of the front ferrule is deformed by screwing the union tee and the union nut to couple with the resistivity sensor by pressing the resistivity sensor. Is initiated.

Combine, fastener, ferrule, ferrule, union nut, strain, crimp, pressurized

Description

Resistivity sensor coupling unit

1 is an exploded cross-sectional view showing a fastening device according to the prior art.

2 is an exploded cross-sectional view of the resistivity sensor fastening device according to the present invention.

FIG. 3 is an enlarged view illustrating the back ferrule and the front ferrule of FIG. 2 in detail.

4 is a cross-sectional view of the coupling of the resistive sensor fastening device according to the present invention.

The present invention relates to a resistivity sensor fastening device, and more particularly, to a resistivity sensor fastening device which can minimize the loss in the manufacturing process due to assembly and processing failure by simplifying the fastening method.

A resistivity sensor is a component for determining the purity of a coolant required for the semiconductor industry and is designed to be used in various types of coolant. In particular, it has high precision and can be used at both high and low temperatures, and needs to be easily installed and assembled in a narrow space.

1 is an exploded cross-sectional view showing a fastening device according to the prior art.

As shown, at the front end of the resistivity sensor 100, a coupling screw 120 is formed to couple to the nut 12 for connection with the wiring 10, and a male screw having a larger diameter in the middle portion thereof. 110 is formed. In addition, a female screw 210 is formed at the front end of the run tee 200.

Here, to couple the resistivity sensor 100 and the runner 200, the nut 12 and the coupling screw 120 are screwed in a state in which the wire 10 is inserted in the front end of the resistivity sensor 100. Subsequently, the male screw 110 is wound with a Teflon tape, and then screwed with the female screw 210 formed at the front end of the runner 200.

According to this configuration, there is a problem that the process proceeds slowly because the Teflon tape has to be wound during fastening.

In addition, there is a problem that a defect occurs continuously due to the difference in the tightening strength of the operator during assembly.

Moreover, since wiring is fastened in a connector manner, there is a possibility of malfunction due to poor contact.

Accordingly, the present invention is presented to solve the above problems, an object of the present invention is to provide a resistive sensor fastening device that is easy to assemble to minimize the loss in the manufacturing process due to assembly and processing failure.

Another object of the present invention is to provide a resistive sensor fastening device for preventing the occurrence of defects due to the constant assembly reproducibility according to the operator.

Another object of the present invention is to provide a resistive sensor fastening device for minimizing contact failure between the wiring and the resistive sensor.

Other objects, features and advantages of the present invention will be clearly understood through the embodiments described below.

The object is interposed between the resistivity sensor and the union tee to couple both, and includes a union nut, a back ferrule and a front ferrule that are sequentially fitted to the resistivity sensor, A resistivity sensor coupled with the resistivity sensor by inserting a back ferrule into the front end portion and inserting the rear end portion into the union tee and a portion of the front ferrule by the screwing of the union tee and the union nut to compress the resistivity sensor. Achieved by a fastening device.

According to this configuration, since the ferrule is mounted without any separate work such as winding a separate Teflon tape, the work becomes simple, and the reproducibility of the assembly is constant according to the operator, so that no assembly defect or product defect occurs. In particular, since the wiring is made integrally with the resistivity sensor, there is no malfunction due to poor contact.

Preferably, the outside of the rear end of the back ferrule and the inside of the front end of the front ferrule may be tapered to correspond to each other, and the outside of the front ferrule and the inside of the front end of the union tee may be tapered to correspond to each other.

Preferably, the back ferrule and the front ferrule may have a ring shape, and the diameter of the back ferrule and the front ferrule may be inserted into contact with an outer surface of the resistivity sensor.

In addition, a groove for accommodating a part of the deformed front panel may be formed at a predetermined position of the resistivity sensor.

Hereinafter, with reference to the accompanying drawings will be described an embodiment of the present invention.

2 is an exploded cross-sectional view of the resistivity sensor fastening device according to the present invention, Figure 3 is an enlarged view showing in detail the back and front ferrule of FIG. 4 is a cross-sectional view of the coupling of the resistive sensor fastening device according to the present invention.

2, the resistivity sensor fastening device according to the present invention is interposed between the resistivity sensor 1100 and the union tee 1500 to serve to couple both.

The resistivity sensor fastening device includes a union nut 1200, a back ferrule 1300, and a front ferrule 1400 that are sequentially inserted into the resistivity sensor 1100.

In the resistivity sensor 1100 of the present invention, wiring is integrally manufactured to prevent malfunction due to a poor contact from the beginning. In addition, a groove 1110 is formed at a predetermined position in the middle, and thus, the rear end portion of the front ferrule 1400 is pushed into the groove 1110 to be coupled with the resistivity sensor 1100 as described below.

Looking at these structures in detail, the stepped portion is formed and the screw is formed inside the union nut 1200 so that the back ferrule 1300 can be caught. In addition, referring to FIG. 3, the back ferrule 1300 and the front ferrule 1400 have a ring shape, and their diameters are inserted into contact with the outer surface of the resistivity sensor 1100.

Preferably, the rear end outer portion 1310 of the back ferrule 1300 is tapered at an angle, and the front end inner portion 1410 of the corresponding front ferrule 1400 is tapered at approximately the same angle.

In addition, the outside of the front ferrule 1400 is tapered at a predetermined angle, and the corresponding inner side 1510 of the front end of the union tee 1500 is tapered at approximately the same angle.

The back ferrule 1300 and the front ferrule 1400 having such a structure are fitted to the front end of the front ferrule 1400 while the rear end of the back ferrule 1300 is accommodated in the union nut 1200, and the front ferrule 1400. The rear end of the) is sequentially inserted into the front end of the union tee 1500, the union tee 1500 is fitted to the union nut 1200 and screwed.

The assembly method of the resistivity sensor fastening device of such a structure is demonstrated.

First, the union nut 1200, the back ferrule 1300, and the front ferrule 1400 are sequentially inserted into the resistivity sensor 1100. At this time, the resistivity sensor 1100 is fixed with a jig so that the union nut 1200 is fitted to a predetermined position.

As described above, the back ferrule 1300 is fitted to the front ferrule 1400 which is caught on the step of the union nut 1200 and inserted into the back, and the tapered portion of the rear end outer 1310 of the back ferrule 1300 is front. The tapered portions of the front end 1414 of the ferrule 1400 are fitted to the tapered portions.

At this time, the rear end of the front ferrule 1400 is positioned in the groove 1110 of the resistivity sensor 1100 formed by the jig, and the front ferrule 1400 is forcedly coupled to the back ferrule 1300. The rear end is deformed in the form of finely crushed in the center direction and the deformed part is pushed into the groove 1110 part.

Then, after inserting the resistivity sensor 1100 into the union tee 1500, check that the end of the resistivity sensor 1100 is at the center position P of the union tee 1500, and tighten the union nut 1200 to tighten the union tee 1500. ) And screw.

As described above, when the union nut 1200 is tightened while the taper portion formed on the outer side of the front ferrule 1400 is coupled to the taper portion formed on the inner side of the front end portion 1510 of the union tee 1500, the union tee 1500 ) Pressurizes the front ferrule 1400, whereby the front ferrule 1400 is further deformed and pushed into the groove 1110 of the resistivity sensor 1100. Accordingly, the bonding force with the resistivity sensor 1100 is further increased.

As described above, according to the present invention there is an advantage that the operation is simple because only the ferrule is mounted without a separate operation such as winding a separate Teflon tape. In addition, the reproducibility of the assembly is constant according to the operator, so that no assembly defects or product defects occur. In particular, since the wiring is made integrally with the resistivity sensor, there is no malfunction due to poor contact.

The resistivity sensor fastening device of the present invention can be variously modified or modified by those skilled in the art from the above-described structure, and such changes and modifications fall within the scope of the present invention, unless they depart from the scope of the present invention.

According to the present invention, there is an advantage that the operation is simple because only the ferrule is mounted without a separate operation such as winding a separate Teflon tape.

In addition, the reproducibility of assembly is constant according to the operator, so that no assembly defects or product defects occur.

In particular, since the wiring is made integrally with the resistivity sensor, there is no malfunction due to poor contact.

Claims (5)

Interposed between the resistivity sensor and the union tee, A union nut, a back ferrule, and a front ferrule, which are sequentially fitted to the resistivity sensor, Receiving grooves are formed along a surface outer periphery at a predetermined position of the resistivity sensor The back ferrule is fitted to the front end of the front ferrule and the union tee is inserted to the rear end of the front ferrule, whereby the union tee is partially deformed by screwing with the union nut. And the deformed front panel portion is received in the receiving groove to couple the resistive sensor by compressing the resistivity sensor. The method according to claim 1, The resistivity sensor fastening device, characterized in that the rear end of the back ferrule and the front end of the front ferrule is tapered to correspond to each other. The method according to claim 1 or 2, Resistive sensor fastening apparatus characterized in that the outer side of the front ferrule and the inner side of the front end of the union tee tapered to correspond to each other. The method according to claim 1, The back ferrule and the front ferrule are ring-shaped, the diameter of the resistivity sensor fastening device, characterized in that the fitting is in contact with the outer surface of the resistivity sensor. delete

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