KR102493416B1 - Portable pneumatic sampling device for sample collection and method using the same - Google Patents

Abstract

A portable pneumatic sampling device and method for sample sampling designed to be lightweight and miniaturized so that users can carry it easily and easily collect highly clean samples by inert gas blowing and vacuum suction. start about
A portable pneumatic sampling device for taking a sample sample according to the present invention includes a sampling body; a sample holder protruding and extending from one end of the sampling body to collect a sample in molten steel; an operation switch for controlling the supply of inert gas flowing into the sampling body from the other end of the sampling body; a regulator for adjusting the pneumatic pressure of the inert gas supplied by the operation switch; a solenoid valve for selectively controlling a blowing operation of supplying an inert gas whose pneumatic pressure is controlled by the regulator to the inside of the sampling holder and a suction operation of vacuuming a sample in the molten steel; and an ejector for collecting a sample by suctioning the molten metal in the molten steel when opened by the operation of the solenoid valve.

Description

Portable pneumatic sampling device for sample sampling and its method {PORTABLE PNEUMATIC SAMPLING DEVICE FOR SAMPLE COLLECTION AND METHOD USING THE SAME}

The present invention relates to a portable pneumatic sampling device and method for taking a sample sample, and more particularly, to a portable pneumatic sampling device and method thereof, and more particularly, to a sample sample that is lightweight and miniaturized so that the user can easily carry it and is highly clean by inert gas blowing and vacuum suction. It relates to a portable pneumatic sampling device for sample collection designed to conveniently perform sampling for and a method thereof.

In general, in the steelmaking process, various efforts are being made to improve the quality of steel. Accordingly, in order to identify and adjust physical properties of molten metal that affect the high cleanliness of molten steel, samples of molten metal are collected and analyzed.

In such a molten steel treatment process, a bubbling operation is usually performed using a bubbling lance for the purpose of separating and floating inclusions, and in the degassing process, a series of secondary refining processes to remove the gas inherent in the molten steel in the steel ladle perform complex tasks.

Therefore, in the process of refining the molten steel in the steel ladle, inevitably, for the purpose of analyzing the chemical composition of the molten steel, samples in the molten steel must be taken little by little during the work, and based on this, the component readjustment of the molten steel is performed.

At this time, a molten steel sample collection device is used for the work of collecting samples from the molten steel, which is normally performed.

However, the conventional molten steel sampling apparatus is bulky and heavy, making it difficult for workers to handle and thus exposed to risks such as safety accidents and burn hazards. In addition, due to the conventional molten steel sampling device being performed in a manner of simply scooping up a sample sample in a state in which a sample sample is simply deposited in the molten steel, it is impossible to take a sample sample of high purity.

As a related prior literature, there is Korean Patent Publication No. 10-2014-0014583 (published on February 6, 2014), which describes a sampling and temperature measuring device and a method thereof.

An object of the present invention is a portable pneumatic sampling for sample sampling designed to be lightweight and miniaturized so that users can easily carry it while also easily performing high-clean sample collection by inert gas blowing and vacuum suction. It is to provide an apparatus and a method therefor.

To achieve the above object, a portable pneumatic sampling device for taking a sample sample according to an embodiment of the present invention includes a sampling body; a sampling holder extending and protruding from one end of the sampling body and collecting a sample in molten steel; an operation switch for controlling the supply of inert gas flowing into the sampling body from the other end of the sampling body; a regulator for adjusting the pneumatic pressure of the inert gas supplied by the operation switch; a solenoid valve for selectively controlling a blowing operation of supplying an inert gas whose pneumatic pressure is controlled by the regulator to the inside of the sampling holder and a suction operation of vacuuming a sample in the molten steel; and an ejector for collecting a sample by suctioning the molten metal in the molten steel when opened by the operation of the solenoid valve.

The inert gas includes at least one of Ar and N ₂ .

The portable pneumatic sampling device includes a flow controller for controlling the flow rate of the inert gas supplied into the sampling holder during the blowing operation; a first pressure switch for determining whether or not the inert gas whose pneumatic pressure is controlled by the regulator is supplied; a filter for filtering impurities in the sample during suction by the ejector; and a battery mounted inside the sampling body to supply power.

In addition, the portable pneumatic sampling device further includes a second pressure switch for controlling the operation of the solenoid valve when the immersion pressure of the sampling holder immersed in the molten steel is detected as a set value.

Here, when the second pressure switch is turned on, in response to a suction operation signal from the second pressure switch, the solenoid valve direction is changed toward the ejector, and the ejector suctions the molten metal in the molten steel to obtain a sample sample. to collect

When the operation switch is turned on, the ejector is set to maintain an operating state at all times while supplying an inert gas.

A portable pneumatic sampling method for taking a sample sample according to an embodiment of the present invention for achieving the above object includes the steps of (a) turning on an operation switch to supply an inert gas into the sampling body; (b) performing a blowing operation to supply an inert gas whose pneumatic pressure is controlled by a regulator into the sampling holder connected to the sampling body; (c) immersing the sampling holder into the molten steel while maintaining the blowing operation state; (d) operating a solenoid valve when the immersion pressure of the sampling holder immersed in the molten steel is detected as a set value; and (e) collecting a sample by suctioning the molten metal in the molten steel with an ejector when the solenoid valve is opened in the direction of the ejector by operation of the solenoid valve.

Here, when the second pressure switch detects a set value, the solenoid valve changes the direction of the solenoid valve toward the ejector in response to a suction operation signal, and suctions the molten metal in the molten steel to the ejector.

When the operation switch is turned on, the ejector is set to maintain an operating state at all times while supplying an inert gas.

The portable pneumatic sampling device and method for taking sample samples according to the present invention are not only easy for users to carry through lightweight and miniaturized application of a sampling body made of aluminum having a subminiature box shape, but also inert gas blowing and vacuum Since it is possible to selectively control the suction, it may be possible to conveniently perform collection of highly clean samples.

In addition, the portable pneumatic sampling device and method for taking a sample according to the present invention continue to blow inert gas into molten metal in molten steel, and then operate the second piezoelectric switch at a certain pneumatic level to drive the solenoid valve, thereby blowing By stopping the operation and changing to a suction operation to suck in the molten metal in the molten steel with vacuum pressure to collect a sample sample, a highly clean sample sample can be easily taken.

In addition, in the portable pneumatic sampling device and method for taking a sample sample according to the present invention, when the second pressure switch detects a set value, the solenoid valve automatically changes the direction of the solenoid valve toward the ejector in response to the suction operation signal. Since the conversion is performed, it is possible to always take a sample sample from the same location, so that the cleanliness of the sample sample can be constantly maintained regardless of the skill level of the operator, so that the occurrence of cleanliness deviation can be prevented in advance.

1 is a perspective view showing a portable pneumatic sampling device for taking a sample sample according to an embodiment of the present invention.
Figure 2 is a schematic diagram showing a portable pneumatic sampling device for taking a sample sample according to an embodiment of the present invention.
Figure 3 is a process flow chart showing a portable pneumatic sampling method for taking a sample sample according to an embodiment of the present invention.

Advantages and features of the present invention, and methods of achieving them, will become clear with reference to the detailed description of the following embodiments taken in conjunction with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but will be implemented in various different forms, and only these embodiments make the disclosure of the present invention complete, and common knowledge in the art to which the present invention belongs. It is provided to fully inform the holder of the scope of the invention, and the present invention is only defined by the scope of the claims. Like reference numbers designate like elements throughout the specification.

Hereinafter, a portable pneumatic sampling device and method for taking a sample according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is a perspective view showing a portable pneumatic sampling device for taking a sample according to an embodiment of the present invention, and FIG. 2 is a schematic diagram showing a portable pneumatic sampling device for taking a sample according to an embodiment of the present invention.

1 and 2, the portable pneumatic sampling device 100 for taking a sample according to an embodiment of the present invention includes a sampling body 110, a sampling holder 120, an operation switch 130, a regulator ( 140), a solenoid valve 150, an ejector 160 and a filter 170. In addition, the portable pneumatic sampling device 100 for collecting samples according to an embodiment of the present invention further includes a flow controller 175, a first pressure switch 182, a second pressure switch 184 and a battery 190. include

The sampling body 110 may have a box shape having an empty receiving space inside. At this time, the sampling body 110 preferably has a box shape having a width of 300 to 400 mm, a length of 90 to 120 mm, and a height of 60 to 80 mm. Here, a metal material may be used as the sampling body 110 . In particular, it is more preferable that the sampling body 110 is made of aluminum to reduce weight and has a thickness of 1 to 2 mm.

As such, the sampling body 110 of the present invention is made of aluminum and is thinly formed with a thickness of 1 to 2 mm, and has a box shape having a width of 300 to 400 mm, a length of 90 to 120 mm and a height of 60 to 80 mm for volume reduction. As a result, the user can easily grip and use it with one hand, so it is portable.

The sampling holder 120 protrudes and extends from one end of the sampling body 110, and serves to collect samples in molten steel. The sampling holder 120 is installed to communicate with the sampling body 110 .

The operation switch 130 is installed to control the supply of inert gas flowing into the sampling body 110 from the other end of the sampling body 110 . The operating switch 130 may be a toggle switch mounted inside the sampling body 110 and partially protruding out of the sampling body 110 so that the operator flips it up and down, but is limited thereto. It is not.

Here, the inert gas may be supplied from an inert gas supply tank (not shown) through a gas supply tube coupled to the gas inlet 105 . This inert gas may include at least one of Ar and N ₂ . In this way, when argon and nitrogen are supplied as inert gases, it is possible to remove impurities without having any effect on the composition of molten metal in molten steel, and thus it becomes possible to collect highly clean molten metal.

The regulator 140 is mounted to adjust the pneumatic pressure of the inert gas supplied by the operation switch 130 . When the operation switch 130 is turned on, the regulator 140 adjusts and outputs the inert gas supplied at a pressure of 4 to 7 bar to a pressure of 0.5 to 3 bar and supplies it to the sampling holder 120. .

The solenoid valve 150 selectively controls a blowing operation for supplying an inert gas whose pneumatic pressure is regulated by the regulator 140 to the inside of the sampling holder 120 and a suction operation for taking a sample sample in molten steel in a vacuum. fitted for At this time, the solenoid valve 150 pulls the spring with an electromagnet when the valve operates with the power supply from the battery 190, and when the power supply is cut off, the on and off are controlled on the principle that the spring elastically returns to its original position. . The blowing operation and the suction operation may be selectively controlled by the solenoid valve 150 . Accordingly, the blowing direction and the suction direction may be opposite to each other.

That is, when the solenoid valve 150 is blocked in an off state, a blowing operation is performed, and when the solenoid valve 150 is opened in an on state, the direction of the solenoid valve 150 is changed toward the ejector 160 to provide suction will perform the action.

When the ejector 160 is opened by the operation of the solenoid valve 150, it is installed to collect a sample by suctioning the molten metal in the molten steel. At this time, the ejector 160 is preferably set to maintain an operating state at all times while supplying an inert gas when the operation switch 130 is turned on.

The filter 170 serves to filter impurities in the sample during suction by the ejector 160 . The filter 170 is installed to filter foreign substances in the molten metal flowing into the sampling holder 120 during the suction operation, and an in-line filter having a filtering capacity of 0.1 to 100 μm may be used.

The flow controller 175 is mounted to control the flow rate of the inert gas supplied into the sampling holder 120 during the blowing operation. The flow rate of the inert gas supplied to the inside of the sampling holder 120 is uniformly controlled by the flow rate controller 175, thereby spraying the inert gas in a uniform amount to the molten metal in the molten steel during the blowing process. it can become possible

The first pressure switch 182 is installed to determine whether the inert gas whose pneumatic pressure is controlled by the regulator 140 is supplied. The first pressure switch 182 is installed to determine whether or not the inert gas is supplied, and activates the circuit of the battery 190 only when the inert gas is supplied by the turn-on operation of the operation switch 130, When the inert gas is not supplied due to the turn-off operation of the operation switch 130, the activation of the circuit of the battery 190 is blocked to prevent generation of leakage current in advance.

The second pressure switch 184 is mounted to control the operation of the solenoid valve 150 when the immersion pressure of the sampling holder 120 immersed in molten steel is detected as a set value.

Here, the second pressure switch 184 supplies a suction operation signal to the solenoid valve 150 to turn on the solenoid valve 150 toward the ejector 160 when detecting that the immersion pressure is less than the set value of the proper pressure, will open up When the second pressure switch 184 is turned on, the first pressure switch 182 is turned off.

In this way, in response to the suction operation signal from the second pressure switch 184, the direction of the solenoid valve 150 is changed toward the ejector 160, and the ejector 160, which is always operating when the operation switch 130 is turned on, The sample is collected by suctioning the molten metal in the molten steel.

In addition, when the second pressure switch 184 detects that the immersion pressure is equal to or less than the appropriate pressure setting value, the lighting lamp 135 provided in the sampling body 110 is set to operate. At this time, the lighting lamp 135 may light any one color of red, green, blue, yellow, and the like. Accordingly, the operator can recognize in real time that the suction operation is performed through the lit lamp 135 .

The battery 190 is mounted inside the sampling body 110 to supply power. The battery 190 supplies power used to operate the first and second pressure switches 182 and 184, the solenoid valve 150, and the like. A lithium ion battery may be used as the battery 190, but is not necessarily limited thereto.

The portable pneumatic sampling device for taking samples according to the above-described embodiment of the present invention is not only easy for the user to carry through lightening and miniaturization by applying a sampling body made of aluminum having a subminiature box shape, but also blowing inert gas And it is possible to selectively control the vacuum suction, so that it is possible to conveniently perform collection of highly clean samples.

In addition, the portable pneumatic sampling device for taking samples according to an embodiment of the present invention continues blowing inert gas into molten metal in molten steel, and then the second piezoelectric switch operates at a certain pneumatic level to drive the solenoid valve, thereby blowing By stopping the operation and changing to a suction operation to suck in the molten metal in the molten steel with vacuum pressure to collect a sample sample, a highly clean sample sample can be easily taken.

In addition, in the portable pneumatic sampling device for taking samples according to an embodiment of the present invention, when the second pressure switch detects a set value, the solenoid valve automatically changes the direction of the solenoid valve toward the ejector in response to the suction operation signal. Since the conversion is performed, it is possible to always take a sample sample from the same location, so that the cleanliness of the sample sample can be constantly maintained regardless of the skill level of the operator, so that the occurrence of cleanliness deviation can be prevented in advance.

Hereinafter, a portable pneumatic sampling method for collecting a sample sample according to an embodiment of the present invention will be described with reference to the accompanying drawings.

3 is a process flow chart showing a portable pneumatic sampling method for taking a sample sample according to an embodiment of the present invention, and will be described in conjunction with FIGS. 1 and 2.

As shown in FIGS. 1 to 3, the portable pneumatic sampling method for taking a sample according to an embodiment of the present invention includes a switch-on step (S110), a blowing step (S120), a immersion step (S130), and a pressure sensing step. (S140) and a suction step (S150).

switch on

In the switch-on step (S110), the operation switch 130 is turned on to supply an inert gas into the sampling body 110.

Here, the operation switch 130 may be a toggle switch mounted inside the sampling body 110 and partially protruding out of the sampling body 110 so that the operator flips it up and down, but is limited thereto. it is not going to be In this case, the inert gas may include at least one of Ar and N ₂ .

blowing

In the blowing step (S120), a blowing operation of supplying an inert gas whose pneumatic pressure is controlled by the regulator 140 to the inside of the sampling holder 120 connected to the sampling body 110 is performed.

Here, the regulator 140 adjusts and outputs the inert gas supplied at a pressure of 4 to 7 bar to a pressure of 0.5 to 3 bar when the operation switch 130 is turned on, and supplies it to the sampling holder 120. do.

deposition

In the immersion step (S130), the sample collection holder 120 is immersed into the molten steel while maintaining the blowing operation state.

In this step, when the blowing operation of continuously supplying argon and nitrogen, which are inert gases, is performed, it is possible to remove impurities without having any effect on the composition of the molten metal in the molten steel, thereby obtaining highly clean molten metal. things can become possible.

pressure sensing

In the pressure sensing step (S140), when the immersion pressure of the sampling holder 120 immersed in the molten steel is detected as a set value, the solenoid valve 150 is operated.

In this step, when the immersion pressure of the sampling holder 120 immersed in the molten steel is detected as a set value, the solenoid valve 150 is operated by the second pressure switch 184.

Here, when the second pressure switch 184 detects that the immersion pressure is less than the set value of the appropriate pressure, a suction operation signal is supplied to the solenoid valve 150 to turn on the solenoid valve 150 toward the ejector 160 will open up

suction

In the suction step (S150), when the solenoid valve 150 is opened in the direction of the ejector 160, a sample is collected by suctioning the molten metal in the molten steel with the ejector.

During suction by the ejector 160, impurities in the sample are filtered by the filter 170.

In this step, when the second pressure switch 184 detects the set value, the solenoid valve 150 changes the direction of the solenoid valve 150 toward the ejector 160 in response to the suction operation signal, so that the molten metal in the molten steel A sample is collected by suction by the ejector 160. To this end, it is preferable that the ejector 160 is set to maintain an operating state at all times while supplying an inert gas when the operating switch 130 is turned on.

In addition, when the second pressure switch 184 detects the set value, the lighting lamp 135 provided in the sampling body 110 is operated. At this time, the lighting lamp 135 may light any one color of red, green, blue, yellow, and the like. Accordingly, the operator can recognize in real time that the suction operation is performed through the lit lamp 135 .

If the suction operation is manually switched, since the position of the molten steel molten steel always changes, deviations in cleanliness may occur when samples are taken for each worker.

Unlike this, in the present invention, when the second pressure switch 184 detects the set value, the solenoid valve 150 responds to the suction operation signal to automatically change the direction of the solenoid valve 150 toward the ejector 160. By doing this, it is possible to minimize the work deviation regardless of the skill level of the operator.

That is, in the present invention, the pressure at an appropriate position of the molten steel becomes less than the set value according to the iron pressure of the molten steel, and at that point, it is switched to automatic suction, so it is possible to always take a sample from the same position, thereby improving the skill level of the operator Regardless of this, the cleanliness of the sample can be kept constant, so it is possible to prevent the occurrence of cleanliness deviation in advance.

In addition, the portable pneumatic sampling method for taking a sample sample according to an embodiment of the present invention may further include a switch-off step (S160) performed after the suction step (S150).

In the switch-off step (S160), the operation switch 130 is turned off.

In this way, when the operation switch 130 is turned off, the supply of inert gas is cut off, and the activation of the circuit of the battery 190 is blocked by the first pressure switch 182 to prevent leakage current in advance. be able to

Although the above has been described based on the embodiments of the present invention, various changes or modifications may be made at the level of a technician having ordinary knowledge in the technical field to which the present invention belongs. Such changes and modifications can be said to belong to the present invention as long as they do not deviate from the scope of the technical idea provided by the present invention. Therefore, the scope of the present invention will be determined by the claims described below.

100: portable pneumatic sampling device 105: gas inlet
110: sampling body 120: sample collection holder
130: operating switch 135: lighting lamp
140: regulator 150: solenoid valve
160: ejector 170: filter
175: flow regulator 182: first pressure switch
184: second pressure switch 190: battery

Claims (9)

sampling body;
a sampling holder extending and protruding from one end of the sampling body and collecting a sample in molten steel;
an operation switch for controlling the supply of inert gas flowing into the sampling body from the other end of the sampling body;
a regulator for adjusting the pneumatic pressure of the inert gas supplied by the operation switch;
a solenoid valve for selectively controlling a blowing operation of supplying an inert gas whose pneumatic pressure is controlled by the regulator to the inside of the sampling holder and a suction operation of vacuuming a sample in the molten steel; and
an ejector for collecting a sample by suctioning molten metal in the molten steel when opened by the operation of the solenoid valve;
a first pressure switch for determining whether or not the inert gas whose pneumatic pressure is controlled by the regulator is supplied;
a second pressure switch for controlling the operation of the solenoid valve when the immersion pressure of the sampling holder immersed in the molten steel is detected as a set value; and
A portable pneumatic sampling device for sampling, characterized in that it comprises a battery mounted inside the sampling body to supply power.
According to claim 1,
The inert gas is
A portable pneumatic sampling device for sampling, characterized in that it comprises at least one of Ar and N ₂ .
According to claim 1,
The portable pneumatic sampling device
a flow controller for controlling the flow rate of the inert gas supplied into the sampling holder during the blowing operation; and
a filter for filtering impurities in the sample during suction by the ejector;
A portable pneumatic sampling device for sample collection, characterized in that it further comprises.
delete According to claim 1,
When the second pressure switch is turned on,
In response to a suction operation signal from the second pressure switch, the direction of the solenoid valve is changed toward the ejector, and a sample is collected by suctioning the molten metal in the molten steel with the ejector. Pneumatic sampling device.
According to claim 5,
the ejector
A portable pneumatic sampling device for taking samples, characterized in that when the operation switch is turned on, the inert gas is supplied and maintained at all times.
A sampling method using the portable pneumatic sampling device for sample collection according to claim 1,
(a) supplying an inert gas into the sampling body by turning on the operating switch;
(b) performing a blowing operation to supply an inert gas whose pneumatic pressure is controlled by a regulator into the sampling holder connected to the sampling body;
(c) immersing the sampling holder into the molten steel while maintaining the blowing operation state;
(d) operating a solenoid valve when the immersion pressure of the sampling holder immersed in the molten steel is detected as a set value; and
(e) taking a sample sample by suctioning the molten metal in the molten steel with an ejector when the solenoid valve is opened in the direction of the ejector;
The presence or absence of supply of the inert gas whose pneumatic pressure is controlled by the regulator is determined by the first pressure switch, and when the immersion pressure of the sampling holder immersed in the molten steel is detected as a set value, the solenoid is detected by the second pressure switch. A portable pneumatic sampling method for sampling, characterized in that the operation of the valve is controlled and power is supplied by a battery mounted inside the sampling body.
According to claim 7,
When the second pressure switch detects the set value,
The portable pneumatic sampling method for taking a sample, characterized in that the solenoid valve changes the direction of the solenoid valve toward the ejector in response to a suction operation signal to suction the molten metal in the molten steel with the ejector.
According to claim 8,
the ejector
A portable pneumatic sampling method for taking a sample, characterized in that when the operation switch is turned on, the inert gas is supplied and maintained at all times.

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