KR101266467B1 - Receiving station with secondary capsule cap separator - Google Patents

Abstract

PURPOSE: A receiving station is provided to simply separate a capsule cap by hitting a specific part of a capsule cap automatic separator when the capsule cap is not separated from the capsule cap automatic separator. CONSTITUTION: A receiving station comprises a supply part(10) which comprises a sample, a capsule body(B) with an open upper par, and a capsule module(M) including a capsule cap(C) sealing the capsule body; a transfer part(20) clamping and transferring the capsule module; a cap-automatic separator(30) automatically separating the capsule cap from the transferred capsule module; a housing(40) which has a supply part, transfer part, and a capsule cap automatic separator; and a secondary capsule cap separator(50) which separates the capsule cap by being selectively operated with the capsule cap automatic separator.

Description

RECEIVING STATION WITH SECONDARY CAPSULE CAP SEPARATOR}

The present invention relates to a device for separating the cap of the carrier containing the sampled molten metal for component analysis in the production of special steel, and more specifically, by separating the non-separated carrier cap from the automatic separator cap separator by adding a simple configuration And a receiving station having an auxiliary feeder cap separator.

In the process of manufacturing special steel, sampling is carried out in the molten metal in order to know the composition of the steel and then transferred to the component analysis chamber.

As shown in FIG. 1, the sampled molten metal is transported in a carrier module (M). The transfer module (M) includes a sample (S) in which molten metal is contained, a transfer body (B) in which the sample (S) is embedded, and a transfer cap (C) for sealing an upper portion of the transfer body (B). Include.

The carrier cap (C) is formed so that its lower part is inserted into the carrier body (B) to seal the carrier body (B) containing the sample (S), and the neck portion (N) is the carrier body. It is not inserted into (B) but protrudes outward.

2 is a view showing the appearance of a receiving station.

As shown in Figure 2, the component analysis room is provided with a receiving station (1), the carrier module containing the sample is a component analysis room through an air shooter using a high-pressure blower station (blower station) equipment Is transferred to the receiving station 1.

The transported transporter module is clamped by the robot and transferred to the transporter cap automatic separator. In the transporter cap automatic separator, the transporter module is pulled up and down to separate the transporter cap from the body, and then tilted at the sample inlet. It flows down to the analyst, which is then cut, processed and sent to the analyzer for analysis and production.

However, in the process of the robot transporting the transporter module arriving at the receiving station and removing the transporter cap from the transporter cap automatic separator, if the transporter cap is not separated, the process returns to the production process where the sample is sent back. There is a problem that the component analysis is delayed and the production efficiency is lowered.

It should be understood that the foregoing description of the background art is merely for the purpose of promoting an understanding of the background of the present invention and is not to be construed as adhering to the prior art already known to those skilled in the art.

In order to solve this conventional problem, the present invention provides a simple method of applying the cap of the cap by separating the cap of the automatic separator from the outside of the receiving station. It is an object of the present invention to provide a receiving station having a detachable auxiliary transporter cap separator.

Receiving station having an auxiliary transporter cap separator according to the present invention for achieving this object, the sampler, the carrier body is open at the top so that the sample can be contained, and inserted into the upper portion of the carrier body A supply unit to which a transporter module including a transporter cap to seal the transporter body arrives; A transfer unit for clamping and transporting the transporter module in the supply unit; A feeder cap automatic separator for automatically separating the feeder cap by receiving the feeder module transferred from the transfer unit; A housing in which the supply part, the transfer part, and the automatic feeder cap separator are built in; And an auxiliary feeder cap separator installed to penetrate from the outside to the inside of the housing to selectively operate the feeder cap automatic separator to separate the feeder cap.

The automatic feeder cap separator has a body fixing part for fixing the transporter body, a cap fixing part positioned on the body fixing part to fix the transporter cap, and coupled to an upper surface of the cap fixing part. It includes a drive unit for providing, one end of the auxiliary transporter cap separator is characterized in that in contact with the cap fixed portion selectively.

The auxiliary transporter cap separator has a push rod through the housing, one end of which is in contact with the cap fixing part with the housing located inside, and the other end of which is located outside the housing; It characterized in that it comprises a return spring for mediating the other end of the housing.

The auxiliary feeder cap separator further includes a pipe guide having a center through which the push rod can be fitted, and a fixing flange extending in a circumferential direction at one end of the pipe guide, wherein the fixing flange is an outer side of the housing. Is fixedly coupled to and connected to the other end of the push rod via the return spring, the pipe guide is characterized in that located on the inside of the housing.

A transparent observation window is provided on one side of the housing, and an impact head is fitted to both ends of the push rod to protect the push rod, and one surface of the impact head is flat.

The present invention has the advantage that can solve the problem of delayed component analysis of molten steel, productivity is reduced by returning the unseparated transporter cap back to the production process due to the above technical configuration.

1 is a view showing a typical transmitter module,
2 is a view showing the appearance of a general receiving station;
3 shows a receiving station with an auxiliary feeder cap separator of the present invention;
4 is a view showing the automatic feeder cap separator of the present invention,
5 shows an auxiliary carrier cap separator of the present invention;
6 is a view showing the mounting state of the auxiliary carrier cap separator of the present invention,
7A to 7B are views illustrating the auxiliary carrier cap of the present invention from inside and outside of the housing.

Hereinafter, with reference to the accompanying drawings will be described a receiving station having an auxiliary carrier cap separator according to a preferred embodiment of the present invention.

As shown in Figures 3, 4 and 5, the receiving station provided with the auxiliary feeder cap separator of the present invention, the supply unit 10, transfer unit 20, automatic feeder cap separator 30, housing 40 and auxiliary carrier cap separator 50.

Supply unit 10 is provided on one side of the receiving station, the sample containing the sampled molten steel (S, see FIG. 1), the carrier body (B) is open at the top so that such a sample is contained, It is the point where the transmitter module M including the transmitter cap C which is inserted in the upper part of this transmitter body B, and closes the transmitter body B arrives.

The transporter module M arrived at the supply unit 10 is clamped by the transport unit 20 and supplied to the transporter cap automatic separator 30. The transfer unit 20 may be provided using various means, and may use an automatic robot capable of clamping the carrier module (M).

Auto-capillary separator 30 is located in the upper part of the body fixing part 32 and the body fixing part 32 for fixing the sender body (B), the upper end of the sender cap (C) The cap fixing portion 34 and the driving unit 36 coupled to the upper surface of the cap fixing portion 34 to lift the upper fixing portion.

The cap fixing part 34 is provided with a recess for inserting the capper cap C on the bottom thereof, and the cap cap C is slid and inserted, and at the same time, the cap fixing part 34 is lifted. Cap (C) is formed to be caught in the groove to be separated from the carrier body (B). To this end, the groove is formed to be able to engage the neck portion (N) provided in the transfer cap (C).

The driving unit 36 may be provided in various forms such as a lifting cylinder.

The supply unit 10, the transfer unit 20, the automatic feeder cap separator 30 and the auxiliary feeder cap separator 50 are all provided inside the housing 40.

As shown in Figures 5 and 6, the main transporter cap separator 50 of the present invention, when the carrier cap (C) is unseparated from the automatic transporter cap separator 30, the operator A mechanism for manually removing the transfer cap (C), which is activated when the automatic transfer cap cap 30 is not working properly.

The auxiliary carrier cap separator 50 includes a push rod 52 and a return spring 54.

The push rod 52 penetrates the housing 40, one end of which is positioned inside the housing 40, and selectively contacts the cap fixing part 34, and the other end of which is located outside the housing 40. When the user determines that the transfer cap (C) is unseparated from the automatic transfer cap (30), the user hits the other end of the push rod (52) located outside the housing (40) to the cap fixing portion (34). By transmitting the impact, the transmitter cap C (see FIG. 4) can be separated from the carrier body B (see FIG. 4).

At this time, the other end of the push rod 52 and the housing 40 are connected via the return spring 54 so that the push rod 52 is restored to its original position. When hitting the other end of the push rod 52, the return spring 54 is compressed, by the restoring force push rod 52 is returned to the war position.

The auxiliary feeder cap separator 50 further includes a pipe guide 56 having a center formed therethrough to guide the push rod 52, and a fixing flange 58 extending in a circumferential direction at one end of the pipe guide 56. In addition, the fixing flange 58 is fixedly coupled to the outside of the housing 40 is preferably connected to the other end of the push rod 52 via the return spring 54, the pipe guide 56 is inside the housing 40 It is preferable to be located at.

A transparent observation window 42 is provided at one side of the housing 40, and shock heads are fitted at both ends of the push rod 52 to protect the push rod 52, and impact heads 52a and 52b. It is preferable that one surface of) is formed flat.

By forming one surface of the impact head flat, slip can be prevented from occurring when an impact is applied to the other end of the push rod 52 by means of a hammer or the like. There is an advantage that can be prevented.

The operator observes the process of removing the transfer cap, through the transparent observation window 42, and when the transfer cap is separated and the transfer body is transported by the robot, a tightening spring provided at the lower end of the transfer cap. By supplying lubricating oil or the like (see Fig. 1), the transfer cap can be smoothly separated from the transfer body.

7a to 7b is a view showing a shape coupled to the inside, the outside of the housing of the auxiliary carrier cap separator of the receiving station provided with the auxiliary carrier cap separator of the present invention.

As shown in FIG. 7A, the pipe guide 56 is in contact with the inner surface of the housing 40 inside the housing 40, and as shown in FIG. 7B, the fixing flange 58 is located outside the housing 40. Is fixed to the outer surface of the housing 40, when the operator exerts a force on the other end of the push rod 52 outside the housing 40, the push rod 52 is connected to the housing 40 through the pipe guide 56 When the inner side is moved, and the force is removed, the return spring 54 returns to its original position by using the restoring force of the return spring 54.

While the present invention has been particularly shown and described with reference to specific embodiments thereof, it will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the following claims It will be apparent to those of ordinary skill in the art.

S: sample B: sender body
C: sender cap M: sender module
10: supply part 20: transfer part
30: Plier Cap Automatic Separator
40: Housing
50: Auxiliary Transporter Cap Separator
52: push rod 54: return spring
56 pipe guide 58 fixed flange

Claims (5)

A sample (S), a carrier body (B) having an upper portion open so that the sample (S) can be contained therein, and a machine inserted into the upper portion of the carrier body (B) to seal the carrier body (B). A supply unit 10 to which a sender module M including a sender cap C arrives;
A transfer unit 20 for clamping and transporting the transporter module M in the supply unit 10;
A feeder cap automatic separator (30) for automatically separating the feeder cap (C) by receiving the feeder module (M) transferred from the transfer unit (20);
A housing 40 in which the supply part 10, the transfer part 20, and the automatic feeder cap separator 30 are embedded;
And an auxiliary transporter cap separator (50) for penetrating from the outside of the housing (40) to the inside to selectively operate with the automatic transporter cap separator (30) to separate the transporter cap (C). Receiving station with auxiliary feeder cap separator.
The method according to claim 1, wherein the automatic transfer cap cap 30 is the body fixing part 32 for fixing the carrier body (B), and the position of the carrier cap ( C) and a cap fixing portion 34 for fixing the drive unit 36 is coupled to the upper surface of the cap fixing portion 34 to provide power,
Receiving station having an auxiliary carrier cap separator, characterized in that the one end of the auxiliary carrier cap separator (50) is selectively in contact with the cap fixing portion (34).
The method of claim 2, wherein the auxiliary carrier cap separator 50,
One end of the push rod penetrating the housing 40 and one end of the housing 40 is positioned inward to selectively contact the cap fixing part 34, and the other end thereof is located outside the housing 40. 52) and a return spring (54) which mediates the other end of the push rod (52) and the housing (40).
The method of claim 3, wherein the auxiliary carrier cap separator 50,
Further comprising a pipe guide 56 having a center through which the push rod 52 can be fitted, and a fixing flange 58 extending in the circumferential direction at one end of the pipe guide 56. 58 is fixedly coupled to an outer side of the housing 40, and is connected to the other end of the push rod 52 via the return spring 54, and the pipe guide 56 is located inside the housing 40. And a receiving station, having an auxiliary feeder cap separator.
The method of claim 4,
A transparent observation window 42 is provided at one side of the housing 40, and shock heads 52a and 52b are fitted at both ends of the push rod 52 to protect the push rod 52. Receiving station having an auxiliary carrier cap separator, characterized in that one side of the impact head (52a, 52b) is formed flat.

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