KR101533656B1 - Connector unit and probe apparatus including the connector unit - Google Patents

Abstract

According to an embodiment of the present invention, a connector unit includes an external connector and an internal connector which is inserted in to the external connector. The external connector comprises a hollow-type external connector body which has an internal space; and a holder connection member which is connected to the external connector in parallel and is connected to the internal space. The holder connection member has a cutting part which is extended from the front end of the holder connection member to the external connector and separates the holder connection member into several parts. One end of the holder connection member having the cutting part has a fixing part which is recessed from the outside of the holder connection member and fixes one end of a compensation wire which penetrates the cutting part. The connector unit further includes a cap-shaped fixing member which connects the front end of the cut holder connection member.

Description

[0001] The present invention relates to a connector unit and a probe apparatus including the connector unit.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a connector unit and a probe apparatus including the connector unit. More particularly, the present invention relates to a connector unit for effectively connecting a probe unit and a holder unit in a probe apparatus for measuring a molten state of a molten metal, and a probe apparatus using the connector unit.

Generally, in order to produce metal products in a steel mill, the raw stone is melted at a high temperature. Since the molten state of the molten metal has a great influence on the quality of the metal product, it is necessary to accurately measure the molten state information of the molten metal during the melting operation.

The probe unit is a disposable consumption measuring sensor which is immersed in a molten metal to measure molten state information of the molten metal or to collect a sample for analyzing the composition of the molten metal.

The probe unit is connected to the holder unit through the connector unit, and the holder unit is connected to the automatic or manual lance so that the probe unit is immersed in the molten metal to measure the molten state information and then rise again.

The connector unit electrically and mechanically connects the probe unit and the holder unit, and the inner connector is configured to be inserted into the outer connector.

One end of the compensating wire penetrating the inner connector is mounted on the outer connector, and one end of the compensating wire held by the outer connector is connected to the holder unit to transmit the molten state information measured by the probe unit to the holder unit. In the holder unit, there is a connection terminal having a shape corresponding to the compensating wire that is held in the holder connecting portion.

The conventional connector unit is deformed due to its structural characteristic when the compensation wire is fixed. The deformation of the outer connector interferes with the close connection of one end of the compensating wire held by the holder unit and the outer connector, thereby causing an error in the information of the melt state.

The probe unit has to be immersed in the molten metal several times in accordance with the error of the melt state information, so that the probe unit is wasted and a metal product having a different quality from that of the probe unit is produced.

In addition, due to the structural characteristics of the conventional connector unit, there has been a problem of wasted compensating wire due to the compensation wire cutting when the compensation wire is fixed.

Korean Patent Registration No. 10-0471626 (Mar. 3, 2005)

It is an object of the present invention to provide a connector unit which effectively combines a probe unit and a holder unit and a probe apparatus including the same.

Other objects of the present invention will become more apparent from the following detailed description and drawings.

According to an embodiment of the present invention, the connector unit includes an outer connector and an inner connector inserted into the inner connector, the outer connector comprising: a hollow outer connector body having an inner space; And a holder connecting member connected in parallel with the outer connector body and having a hollow communicating with the inner space, the holder connecting member extending from the tip of the holder connecting member in the direction of the outer connector body Wherein one end of the holder connecting member is formed to be recessed from an outer surface of the holder connecting member and one end of a compensating wire penetrating the cutout is fixed to the other end of the holder connecting member, And the connector unit further comprises a cap-shaped fixing member for connecting the tips of the cut-out holder connection members to each other.

The inner connector includes: an inner connector body inserted into the inner space; And an inner connector insertion member connected to the inner connector body in parallel and inserted into the hollow.

The inner connector insertion member may be formed with a compensation wire insertion groove recessed in the longitudinal direction from the outer surface of the inner connector insertion member.

The inner connector has a shield plate closing one side of the inner connector body adjacent to the inner connector insertion member, and the shield plate may have a compensation wire insertion hole communicating with the compensation wire insertion groove.

The connector unit may further include a compensating wire passing through the compensating wire insertion hole and passing through the inner connector body and disposed along the compensation wire insertion groove and having one end fixed to the compensating wire fixing portion.

Wherein the inner connector insertion member extends from one end adjacent to the inner connector body and is parallel to the longitudinal direction of the inner connector insertion member; And an inclined surface connected to the reference surface and inclined outward from the reference surface.

Wherein the inner connector body is formed with at least one planar inner stopper surface on the outer surface of the inner connector body, and the outer connector body has an outer stopper surface in a shape corresponding to an outer surface of the inner connector body, As shown in FIG.

The outer connector body corresponds to the outer stopper surface, and the position indicator may be formed on an outer surface of the outer connector body.

The outer connector may further include a stopper protruding from the outer circumferential surface of the holder connecting member to the outer connector body and connected to the outer connector body.

According to another embodiment of the present invention, there is provided a probe unit comprising: a probe unit immersed in molten metal to measure a molten state of the molten metal; A connector unit having one end connected to the probe unit; And a holder unit to which the other end of the connector unit is connected, wherein the connector unit includes an outer connector and an inner connector inserted into the outer connector, Hollow outer connector body; And a holder connecting member connected in parallel with the outer connector body and having a hollow communicating with the inner space, wherein the holder connecting member extends from the tip of the holder connecting member in the direction of the outer connector body, Wherein the holder connecting member is provided with a cut-away portion for dividing the holder connecting member into a plurality of pieces, and one end of the holder connecting member having the cut-out portion is provided with a compensation And the connector unit further includes a cap-shaped fixing member for connecting the tips of the cut-out holder connection members to each other.

Effects of the connector unit and the probe device including the connector unit according to the embodiment of the present invention will be described as follows.

And a cap-shaped fixing member for connecting the tips of the incised holder connection members to each other to prevent the holder connection member from spreading.

The holder connecting member is prevented from being opened, and the compensating wire fixed to the compensating wire fixing portion and the connection terminal of the holder are precisely engaged and connected. Therefore, the error of the melt state information measured and transmitted from the probe unit is reduced.

The compensating wire is easily mounted on the compensating wire fixing portion through the inclined surface formed in the insertion groove of the holder connecting member.

1 is a cross-sectional view schematically showing a probe apparatus using a conventional connector unit.
2 is a perspective view schematically showing a conventional external connector and an internal connector and a conventional connector unit to which they are coupled.
3 (a) and 3 (b) are photographs schematically showing an outer connector deformation of a conventional connector unit.
Fig. 4 is a left side view (a), a front view, (c) a plan view, (d) a sectional view and (e) a right side view schematically showing an outer connector according to an embodiment of the present invention.
FIG. 5 is a left side view (a), a left side perspective view, (c) a right side perspective view, and (d) a right side view schematically showing an inner connector according to an embodiment of the present invention.
FIG. 6 is a front view (a) and a perspective view (b) of a schematic view of an inner connector with an inclined surface according to an embodiment of the present invention; FIG.
FIG. 7 is a perspective view schematically showing a connector unit according to an embodiment of the present invention, in which an outer connector, an inner connector, a compensation line insertion process, and a combination thereof are combined.
8 is a cross-sectional view schematically showing a probe apparatus using a connector unit according to an embodiment of the present invention.

The present invention relates to a hot dip galvanizing method and a hot dip galvanizing system, and embodiments of the present invention will be described with reference to the accompanying drawings. The embodiments of the present invention can be modified in various forms, and the scope of the present invention should not be construed as being limited to the embodiments described below. The embodiments are provided to explain the present invention to a person having ordinary skill in the art to which the present invention belongs. Accordingly, the shape of each element shown in the drawings may be exaggerated to emphasize a clearer description.

The probe unit is a disposable consumption measuring sensor which is used by being immersed in molten metal to obtain information of the molten metal in the production process of iron and non-ferrous metals. For the purpose of thermal management and component identification of the molten metal, the molten state information such as the temperature and oxygen amount of the molten metal is periodically measured using a probe unit, or a sample is sampled for analyzing the molten metal component.

1 is a cross-sectional view schematically showing a probe apparatus using a conventional connector unit.

As shown in Fig. 1, the probe apparatus has a structure in which a holder unit 2 is coupled to a lance 3, which is automatically or manually operated, and a probe unit 6 is mounted on the holder unit 2. [ A connector unit 1 for electrically and mechanically connecting the probe unit 6 and the holder unit 2 is positioned between the probe unit 6 used as a measuring element and the holder unit 2 fixed thereto. One end of the compensating wire 7 is connected to the probe unit 6 and is installed in the probe unit through the holder unit 2 and the connector unit 1. [

The probe unit 6 includes a temperature sensor and an arithmetic sensor, and may have a sample chamber for measuring a molten metal sample. The probe unit 6 measures the molten state information of the molten metal or measures a sample of the molten metal in such a manner that the molten metal is immersed in the molten metal and held for several seconds and then rises again. The molten state information measured at the probe unit 6 is transmitted to the transducer 4 along the compensating wire 7 and the converted information is transmitted to the operator via the instruction recorder 5. [

2 is a perspective view schematically showing a conventional external connector and an internal connector and a conventional connector unit to which they are coupled.

The conventional connector unit 1 is composed of an outer connector 11 and an inner connector 12 which are in the male and female form.

The outer connector 11 includes a hollow outer connector body 110 having an inner space and a holder connecting member 112 connected in parallel to the outer connector body 110 and having a hollow communicating with the inner space therein. The holder connecting member 112 is formed with a cutout 114 extending from the tip of the holder connecting member 112 to the outer connector body 110 to divide the holder connecting member 112 into a plurality of pieces. The holder connecting member 112 having the cut-out portion 114 is provided at one end thereof with a compensating wire fixing portion 116 which is recessed from the outer surface of the holder connecting member 112, One end of the compensating wire 7 having the hook shape protruding to the outside is fixed.

One or more compensating wire fixing portions 116 may be provided corresponding to the number of compensating wires 7 used in the probe apparatus and the cutout portions 114 are provided corresponding to the compensating wire fixing portions 116.

The inner connector 12 includes an inner connector body 120 and an inner connector insertion member 122. The inner connector body (120) is inserted into the inner space of the outer connector (11). The inner connector insertion member 122 is connected in parallel with the inner connector body 120 and inserted into the hollow of the holder connection member 112. On the outer surface of the inner connector insertion member 122, a compensation wire insertion groove 124 recessed in the longitudinal direction from the outer surface of the inner connector insertion member 122 is formed. A shield plate 128 for connecting the inner connector insertion member 122 and the inner connector body 120 is formed at one side of the inner connector body 120 and the shield plate 128 is connected to the compensation lead wire insertion groove 124 The compensation wire insertion hole 126 is formed.

The compensating wire 7 passes through the compensating wire insertion hole 126 through the inner connector body 120 and is disposed along the compensating wire insertion groove 124. One end of the compensating wire 7 disposed in the connector unit 1 is fixed to the compensating wire fixing portion 116 and the other end is connected to the probe unit 6. [ A connection terminal corresponding to one end of the compensating wire 7 fixed to the compensating wire fixing portion 116 is formed in the holder unit 2 and is connected to the compensating wire 7 fixed to the compensating wire fixing portion 116 .

3 (a) and 3 (b) are photographs schematically showing an outer connector deformation of a conventional connector unit.

A method of fixing the compensation wire 7 to the conventional connector unit 1 by an operator is as follows. The compensating wire 7 is inserted into the compensating wire insertion groove 124 through the inner connector body 110 first. The compensating wire 7 that has completely passed the tip of the holder connecting portion 112 is bent to the outside connector body side 110 through the cutout portion 114 to mount the compensating wire 7 to the compensating wire fixing portion 116 . One end of the compensating wire 7 is fixed to the compensating wire fixing portion 116 and the excess portion is cut so that the compensating wire 7 is seated in correspondence with the compensating wire fixing portion 116.

The operator performs an operation of pulling the compensation wire 7 from the side of the inner connector body 110 in order to apply a tension to the compensating wire 7 that is held in the connector unit 1 after the compensation wire 7 is fixed . The other end of the compensating wire 7 is pulled while the compensating wire 7 is fixed to the compensating wire fixing portion 116 and the compensating wire fixing portion 116 is connected to the outer connector body 110 ) Direction.

One or more cutouts 114 are formed in the holder connecting member 112 so that the tip of the holder connecting member 112 is held by the holder connecting member 112 from the compensating wire fixing portion 116, A phenomenon that the connection member 112 spreads in the outer side direction occurs.

The inner connector insertion member 122 is in intimate contact with the inner surface of the holder connection member 112 to fix the compensation wire 7 so that an external force is externally applied to the inner surface of the holder connection member 112. [ Therefore, the tip of the holder connecting member 112 is opened due to its external features and coupling characteristics.

The deformation of the holder connecting member 112 interferes with the tight coupling between the connector unit 1 and the holder unit 2. [ The molten state information measured by the probe unit 6 and the instruction recorder 5 measured by the probe unit 6 as the one end of the compensating wire 7 fixed to the compensating wire fixing portion 116 and the connection terminal of the holder unit 2 can not be tightly connected, An error occurs in the measurement value output from the sensor.

Further, when the compensating wire (7) is mounted on the connector unit (1), the compensating wire (7) for the spare wire must be cut according to the structural characteristic of the connector unit (1). (7) cutting of the redundant lead wire leads to waste of the compensating lead wire (7), resulting in an increase in the cost of measuring the melt state information using the probe device.

Fig. 4 is a left side view (a), a front view, (c) a plan view, (d) a sectional view and (e) a right side view schematically showing an outer connector according to an embodiment of the present invention.

The outer connector 20 is composed of the outer connector body 200 and the holder connecting member 210. The outer connector body 200 has an inner space 202 and the holder connecting member 210 has a hollow 216 connected to the outer connector body 200 in parallel and in communication with the inner space 202.

4A to 4E, the outer connector body 200 and the holder connecting member 210 are shown as cylindrical shapes. However, in the present invention, the outer connector body 200 and the holder connecting member 210 are not necessarily cylindrical but include all the tube shapes.

The outer surface of the holder connecting member 210 is formed with a compensating wire fixing portion 214 which is depressed from the outer surface of the holder connecting member 210. A cutout portion 212 extending from the compensating wire fixing portion 214 in a direction opposite to the outer connector body 200 to divide the holder connecting member 210 into a plurality of portions is formed. The compensating wire 40 passing through the hollow 216 of the holder connecting member 210 is mounted on the compensating wire fixing portion 214 via the cutout portion 212.

The number of compensation wires 40 used in the connector unit 50 is determined according to the type of the measurement sensor used in the probe unit 6. [ 4 (a) to 4 (e), four incised portions 212 are arranged in an equiangular arrangement (? ₁ ), but the present invention is not limited thereto. One or more compensating wire fixing portions 214 may be provided corresponding to the number of compensation wires 40 used in the probe apparatus and the cutout portions 212 are provided corresponding to the compensating wire fixing portions 214.

The holder connecting member 210 further includes a cap-shaped fixing member 220 connecting the tips of the holder connecting member 210 to each other. The fixing member 220 is connected to the tip end of the holder connecting member 210 to prevent the distal end of the holder connecting member 210 from being opened. Therefore, the widening phenomenon of the conventional connector unit 1 is improved, and one end of the compensating wire 50 is tightly connected to the connecting terminal of the holder unit 2. [

The outer connector 20 further includes an outer connector body 200 and a stopper 230 projecting from the outer circumferential surface of the holder connecting member 210 and connected to the outer connector body 200. Figure 4 but showing the stopper 3 is an isometric arrangement (θ _2), is not necessarily be limited in this respect. The stopper 230 designates the insertion position of the holder unit 2 and the connector unit 50 to help the connector unit 50 be correctly connected to the holder unit 2. [

FIG. 5 is a left side view (a), a left side perspective view, (c) a right side perspective view, and (d) a right side view schematically showing an inner connector according to an embodiment of the present invention.

The inner connector 30 includes an inner connector body 300 inserted into the inner space 202 and an inner connector insertion member 310 connected in parallel to the inner connector body 300 and inserted into the hollow 216 .

5A to 5D, the inner connector body 300 and the inner connector insertion member 310 are shown as cylindrical shapes. However, the present invention is not limited to the cylindrical shape and includes all the tube shapes.

On the outer surface of the inner connector insertion member 310, a compensating wire insertion groove 312 formed in the longitudinal direction from the outer surface of the inner connector insertion member 310 is formed. The inner connector 30 has a shield plate 304 that closes one side of the inner connector body 300 adjacent to the inner connector insertion member 312 and the shield plate 304 is connected to the compensation lead wire insertion groove 312 A compensation wire insertion hole 302 is formed.

6 is a front view (a) and a perspective view (b) schematically showing an inner connector with an inclined surface according to an embodiment of the present invention

The inner connector insertion member 310 extends from one end adjacent to the inner connector body 300 and is connected to the reference surface 314 and the reference surface 314 parallel to the longitudinal direction of the inner connector insertion member 310, And has a photo slope 330. The inclined surface 330 guides the one end of the compensating wire 40 directly through the holder connecting member 210 through the cutout 212 when the compensating wire 40 is inserted into the connector unit 50.

The compensating wire 40 can be more easily attached to the holder connecting member 210 in comparison with a method in which the compensating wire 7 is completely fixed through the tip of the existing holder inserting member 112 and again through the cutout 114 Can be fixed.

In the case of the conventional method of fixing the compensation wire 7, the compensation wire 7 of the spare wire is cut so as to be in close contact with the compensation wire fixing portion 116. [ However, in the case of using the inclined plane 330, the compensating wire 40 can be minimized to effectively prevent the compensation wire 40 from being wasted.

FIG. 7 is a perspective view schematically showing a connector unit according to an embodiment of the present invention, in which an outer connector, an inner connector, a compensation line insertion process, and a combination thereof are combined.

The connector unit 50 is a structure for inserting the inner connector 30 into the outer connector 20 and the outer connector 20 includes the fixing member 220. The compensating wire 40 passing through the compensating wire insertion hole 302 through the inner connector body 300 is seated in the compensating wire insertion groove 312 and fixed to the compensating wire fixing portion 214 through the inclined surface 330 do.

The length l ₂ of the inner connector 30 is shortened by the length l ₃ of the fixing member 220 at the length l ₁ of the outer connector 20. When the inner connector 30 is inserted into the outer connector 20 to be coupled therewith, the tip of the inner connector insertion member 301 comes into contact with the fixing member 220. Therefore, the inner connector 30 is engaged with the inside of the outer connector 20 of the connector unit 50 without a clearance.

4 and 5, at least one planar inner stopper surface 301 is formed on the outer surface of the inner connector body 300, and an inner connector body 300 (not shown) is formed on the inner surface of the outer connector body 200. [ The outer stop surface 204 having a shape corresponding to that of the outer stop surface 204 is formed. The inner stopper surface 301 and the outer stopper surface 204 are engaged with each other in a shape corresponding to each other, and the inner connector 30 is inserted into the outer connector 20 to fix the inner connector 30 so as not to move.

4, a position indicator 201 corresponding to the outer stopper surface 204 is formed on the outer surface of the outer connector body 200. As shown in Fig. This is for indicating the correct joining position of the connector unit 50 when the connector unit 50 is coupled to the holder unit 2.

8 is a sectional view schematically showing a probe apparatus using the connector unit 50 in which the inner connector 30 shown in Fig. 5 is inserted into the outer connector 20 shown in Fig. 4 and the compensating wire 40 is connected to be.

A probe unit 6 including a sensor unit 410 and a sampling unit 420 may be connected to one end of the connector unit 50 and a holder unit 2 is connected to the other end of the connector unit 50. Since the connector unit 50 of the probe apparatus of Fig. 8 includes the fixing member 220, the holder connecting member 210 is prevented from being deformed. The connector unit 50 of the probe device of FIG. 8 includes the inclined surface 330 to facilitate the operation of connecting the compensation wire 40 to the connector unit 50, and the compensation wire 40 is prevented from being wasted.

Although the present invention has been described in detail by way of examples, other forms of embodiments are possible. Therefore, the technical idea and scope of the claims set forth below are not limited to the embodiments.

1: Conventional connector unit 2: Holder unit
3: Lance 4: Converter
5: Instruction recorder 6: Probe unit
7, 40: compensation lead 11, 20: outer connector
12, 30: inner connector 50: connector unit
110, 200: outer connector body 112, 210: holder connecting member
114, 212: incision section 116, 214: compensation wire fixing section
120, 300: Inner connector body 122, 301: Inner connector insertion member
124, 312: compensation lead-in groove 126, 302: compensating lead insertion hole
128, 304: blocking plate 201: position indicator
202: inner space 204: outer stop surface
216: hollow 220: fixing member
230: stopper 301: inner stop surface
330: sloped surface 314: reference surface
410: sensor unit 420: sampling unit

Claims (10)

A connector unit comprising an outer connector and an inner connector inserted into the inner connector,
Wherein the outer connector comprises:
A hollow outer connector body having an inner space; And
And a holder connecting member connected in parallel to the outer connector body and having a hollow communicating with the inner space,
Wherein the holder connecting member comprises:
A cutout portion extending from the tip end of the holder connecting member in the direction of the outer connector body to divide the holder connecting member into a plurality of portions,
At one end of the holder connecting member having the incision part,
And a compensating wire fixing portion which is recessed from an outer surface of the holder connecting member and has one end of a compensating wire penetrating the cutout portion is fixed,
The connector unit includes:
Further comprising a cap-shaped fixing member which is arranged to surround the tip end of the cut-out holder connection member and prevents a tip end of the holder connection member from being opened. The method according to claim 1,
Wherein the inner connector comprises:
An inner connector body inserted into the inner space; And
And an inner connector insertion member which is connected to the inner connector body in parallel and inserted into the hollow. 3. The method of claim 2,
Wherein the inner connector insertion member comprises:
And a compensating wire insertion groove recessed in the longitudinal direction from the outer side surface of the inner connector insertion member. The method of claim 3,
Wherein the inner connector comprises:
And a blocking plate for closing one side of the inner connector body adjacent to the inner connector insertion member,
And the shield plate has a compensation wire insertion hole communicating with the compensation wire insertion groove. 5. The method of claim 4,
The connector unit includes:
Further comprising a compensating wire passing through the compensating wire insertion hole and passing through the inner connector body and being disposed along the compensating wire insertion groove and having one end fixed to the compensating wire fixing portion. The method of claim 3,
Wherein the inner connector insertion member comprises:
Reference planes extending from one end adjacent to the inner connector body and disposed on both sides of the insertion groove, the reference planes being parallel to the longitudinal direction of the inner connector insertion member; And
And a sloped surface that is disposed between the reference surfaces and connects the reference surfaces to each other, and has an inclined outer surface inclined from the reference surfaces. 3. The method of claim 2,
The inner connector body includes:
At least one planar inner stop surface is formed on the outer surface of the inner connector body,
The outer connector body includes:
And an outer stop surface having a shape corresponding to an outer surface of the inner connector body is formed on the inner surface of the body of the outer connector. 8. The method of claim 7,
The outer connector body includes:
And a position indicator is formed on an outer surface of the outer connector body. The method according to claim 1,
Wherein the outer connector comprises:
And a stopper protruding from the outer circumferential surface of the holder connecting member to the outer connector body and connected to the outer connector body. A probe unit immersed in the molten metal and measuring a molten state of the molten metal;
A connector unit having one end connected to the probe unit; And
And a holder unit to which the other end of the connector unit is connected,
The connector unit includes:
An outer connector and an inner connector inserted into the inner connector,
Wherein the outer connector comprises:
A hollow outer connector body having an inner space; And
And a holder connecting member connected in parallel to the outer connector body and having a hollow communicating with the inner space,
Wherein the holder connecting member comprises:
A cutout portion extending from the tip end of the holder connection member toward the outer connector body and dividing the holder connection member into a plurality of portions,
At one end of the holder connecting member having the incision part,
And a compensating wire fixing portion which is recessed from an outer surface of the holder connecting member and has one end of a compensating wire penetrating the cutout portion is fixed,
The connector unit includes:
Further comprising a cap-shaped fixing member which is arranged to surround the tip end of the cut-out holder connection member and prevents a tip end of the holder connection member from being opened.

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