KR20210049342A - Constant sampler for specimen of phthalate film - Google Patents

Abstract

The present invention relates to a fixed quantity sampler for a small specimen of a film-type sample, which can comprise: a cutting block in which on the central unit toward one end unit, a knife front end unit is placed, with a tapered section, whose external diameter decreases toward a front end, and a cutting edge surface with a preset curvature is formed on an end unit of the tapered section to sample a small specimen of phthalate film; a pressurizing discharge unit accommodated in the cutting block to be slidable in a longitudinal direction to pressurize and discharge the small specimen to the outside; and an unlocking button unit placed on a connection member connected to the cutting block to unlock the pressurizing discharge unit temporarily locked on the cutting block. According to the present invention, the fixed quantity sampler for the small specimen of the film-type sample is able to improve fixed-quantity sampling and the durability of the knife front end unit through the cutting edge surface with the preset curvature, and more precisely perform a substance analysis of film than before. An air flow is activated through an air flow groove, so the pressurizing discharge unit can slide easily from the sampler. By the operation of the unlocking button unit, the small specimen can be selectively discharged, and it can be convenient to manage samples in the whole substance analysis overall.

Description

Quantitative sampler for microscopic specimens of film-type samples {CONSTANT SAMPLER FOR SPECIMEN OF PHTHALATE FILM}

The present invention relates to a micro-specimen quantitative sampler of a film-type sample, and more particularly, to a micro-specimen quantitative sampler of a film-type sample capable of improving the quantitative sampling and durability of a knife tip.

Phthalates are also called phthalates, and their uses are very diverse and can be easily found in almost all products.

Phthalates are mainly used as plasticizers for plastics, and in particular, they have begun to be used to soften polyvinyl chloride (PVC) and improve processability. The product lines include electrical and electronic products, pharmaceuticals, paints, pigments, lubricants, binders, and surfactants. It is being used for a wide range of purposes throughout society, such as.

These phthalates have been identified as pollutants that cause environmental pollution to the environment, and recently, as they are known as environmental hormones that can cause human endocrine system disorders and hormonal disturbance problems, the use of phthalates is becoming stricter.

As a representative product line to which phthalates are applied, there are large-area films such as polarizing films, adhesive films, and wrapping papers. Therefore, it is necessary to determine whether these films are harmful components of 6 types of phthalates, which are notified in the law among phthalates, or what proportion of the harmful components are included in the film, and what chemical structure they are bound to.

However, in the case of a conventional sample cutting machine, it is not suitable for sampling the film material, and due to the decrease in durability of the device during the random extraction and repeated sampling process, the quantitative extraction is not performed over time, so precise component analysis is not performed. There is a problem that cannot be done.

In addition, even if the sample is quantitatively sampled, it is difficult to easily discharge the cut microscopic specimens because they are embedded in the cutting machine, and management of the specimen is inconvenient throughout the analysis operation.

The present invention has been proposed in order to solve the above problems, and quantitative sampling and durability of the knife tip can be improved through the cutting edge of a preset curvature, so that the component analysis of the film can be accurately performed compared to the prior art. A film type that facilitates the flow of air through the flow groove, making it easy to slide the pressurized discharge unit from the sampler, and allows the microscopic specimens to be selectively discharged by the operation of the unlocking button, making it convenient to manage the specimen throughout the component analysis work. A sampler for quantifying microscopic specimens of samples is provided.

In the quantitative sampler for fine specimens of a film-type sample according to the present invention for achieving the above object, a knife tip is provided from the center to one end, and a tapered section is provided in which the outer diameter decreases toward the tip, and the taper A cutting block in which a ground surface is formed on cutting of a predetermined curvature to sample a microscopic specimen of a phthalate film at an end of the section; A pressure discharge unit accommodated in the cutting block and provided to be slid in a longitudinal direction to pressurize and discharge the microscopic specimen to the outside; And an unlocking button part provided on a connecting member connected to the cutting block to unlock the pressure discharge part temporarily locked to the cutting block during sampling.

In the cutting block, a separation preventing step is formed in the pressure discharge unit, and the pressure discharge unit includes: a flange contacting the separation stopping step; A first pressing member provided on one side of the flange and partially exposed to the outside of the cutting block during unsampling; And a second pressing member extending from the flange to the opposite side of the first pressing member.

The pressure discharge unit further includes an elastic spring interposed between the flange and the connecting member, and the elastic spring may be disposed on an outer surface of the second pressing member.

An elastically biased convex protrusion may be provided on the flange, and a concave protrusion corresponding to the convex protrusion may be provided on the cutting block.

During sampling, the pressure discharge unit may slide and the convex protrusion may be engaged with the concave protrusion.

A first diagonal push surface portion in diagonal contact with the unlocking button portion may be provided at a front end portion of the second pressing member.

The unlocking button unit may include a push button exposed on the outer surface of the connecting member; A push member having one end connected to the push button and the other end provided with a second diagonal push surface portion in contact with the first diagonal push surface portion; And a push spring interposed between the push member and the connection member.

At least one air flow groove may be formed in the first pressing member at regular intervals along the circumferential direction and recessed inwardly along the longitudinal direction of the first pressing member.

A vertical pressing surface portion bent vertically may be provided on the front end surface of the first pressing member.

The cutting edge may have a curvature of 0.8 to 1.2, and an inner diameter formed by the tip of the cutting edge may be 1.5 to 2.5 pi.

In the quantitative sampler of a film-type sample according to the present invention, quantitative sampling and durability of the knife tip can be improved through the ground at a cutting edge of a preset curvature, so that the component analysis of the film can be accurately performed and air flow. Since the air flow is smooth through the groove, it is possible to easily slide the pressurized discharge unit from the sampler, and microscopic specimens can be selectively discharged by the operation of the unlocking button, so that the management of the specimen can be convenient throughout the component analysis operation.

1 and 2 are perspective and exploded perspective views of a micro-specimen quantitative sampler of a film-type sample according to an embodiment of the present invention.
3 is a cross-sectional view of a micro-specimen quantitative sampler of a film-type sample according to an embodiment of the present invention.
4 is a perspective view and a cross-sectional view of a cutting block in a quantitative sampler of a micro-specimen of a film-type sample according to an embodiment of the present invention.
5 is an enlarged view of the cutting edge in FIG. 4.
6 is a cross-sectional view of a pressure discharge unit in a quantitative sampler of a micro-specimen of a film-type sample according to an embodiment of the present invention.
7 is a diagram schematically showing an operating state of a micro-specimen quantitative sampler of a film-type sample according to an embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings will be described in detail an embodiment of a micro-specimen quantitative sampler of a film-type sample according to the present invention.

1 and 2 are perspective and exploded perspective views of a micro-specimen quantitative sampler of a film-type sample according to an embodiment of the present invention, and FIG. 3 is a cross-sectional view of a micro-specimen quantitative sampler of a film-type sample according to an embodiment of the present invention, 4 is a perspective view and a cross-sectional view of a cutting block in a quantitative sampler of a micro-specimen of a film-type sample according to an embodiment of the present invention, FIG. 5 is an enlarged view of the cutting edge in FIG. 4, and FIG. 6 is an embodiment of the present invention. It is a cross-sectional view of the pressurized discharge part in the quantitative sampler of the micro-specimen of the film-type sample according to this.

As shown in Figs. 1 to 6, a knife tip 101 is provided from the center to one end, and the knife tip 101 is provided with a tip. A cutting block 100 in which a tapered section 110 whose outer diameter is gradually decreased is provided, and a cutting edge surface 120 having a preset curvature is formed at an end of the tapered section 110 to sample a micro specimen of a phthalate film; A pressure discharge unit 200 accommodated in the cutting block 100 and provided to be slid in the longitudinal direction to pressurize and discharge the micro specimen to the outside; And an unlocking button part 300 provided on the connecting member 400 connected to the cutting block 100 to unlock the pressure discharge part 200 temporarily locked to the cutting block 100 during sampling. I can.

The cutting block 100 is a part for sampling a micro specimen of a phthalate film at the end of the tapered section 110. To this end, the cutting block 100 is provided with a knife tip 101 from the center to one end side, and a tapered section whose outer diameter decreases toward the tip of the cutting block 100 ( 110) can be provided.

In addition, a cutting edge 120 may be provided at the end of the taper section 110 mainly as shown in FIG. 5. The cutting edge surface 120 having a preset curvature may approach the plate surface of the film perpendicularly to sample a microscopic specimen. In this embodiment, the cutting edge surface 120 has a curvature R between 0.8 and 1.2, and preferably may be provided with a curvature of 1R.

The inner diameter formed by the front end of the cutting edge surface 120 may be 1.5 to 2.5 pi.

In the cutting block 100, a through hole 160 may be formed in the longitudinal direction, and the pressure discharge portion 200 may be disposed to pass through the through hole 160. In addition, in the center of the cutting block 100, a separation preventing stepped step 130 may be formed to prevent the pressure discharge unit 200 from being separated from the outside. The flange 220 is in contact with the separation preventing step 130 so that the movement of the pressure discharge unit 200 to the left side of the cutting block 100 may be restricted.

A concave protrusion 140 may be provided on the inner wall of the cutting block 100. The concave protrusion 140 interacts with the convex protrusion 221 provided in the pressurization discharge unit 200 to temporarily limit the sliding movement of the pressurization discharge unit 200.

The connection member 400 may be coupled to the right side of the cutting block 100, and a coupling screw thread 150 for coupling may be provided.

Through the cutting block 100, quantitative sampling and durability of the knife tip 101 can be improved, so that the component analysis of the film can be accurately performed compared to the prior art.

The pressure discharge part 200 mainly includes a flange 220 in contact with the separation preventing stepped step 130 as shown in FIGS. 1 to 3 and 6; A first pressing member 230 provided on one side of the flange 220 and partially exposed to the outside of the cutting block 100 when unsampling; And a second pressing member 240 extending from the flange 220 to the opposite side of the first pressing member 230. And an elastic spring 250 interposed between the flange 220 and the connection member 400.

The flange 220 may be caught by the separation-preventing stepped step 130 to limit the movement to the left side.

An elastically biased convex protrusion 221 is provided on the outer surface of the flange 220, and an elastic member 222 may be inserted into the convex protrusion 221. The convex protrusion 221 may temporarily limit the sliding movement of the pressure discharge unit 200 by interacting with the concave protrusion 140 of the cutting block 100.

A first pressing member 230 may be provided on the left side of the flange 220. The first pressing member 230 may be disposed to be partially exposed to the outside of the cutting block 100 in a default state. Through this, the possibility of a safety accident may be prevented in advance by blocking the exposure of the knife tip 101, particularly the ground 120 to the cutting edge.

1 and 6, the first pressing member 230 is provided at regular intervals along the circumferential direction, but at least one or more air is formed inwardly recessed along the length direction of the first pressing member 230. A flow groove 231 may be formed. The cross-sectional shape of the air flow groove 231 is preferably provided mainly in a hemispherical shape as shown in FIG. 1, and may also be provided in a slit type. The air flow groove 231 assists the sliding movement of the pressure discharge unit 200 with respect to the cutting block 100 and may enable smooth left and right sliding.

A vertical pressing surface portion 232 that is bent vertically may be provided on the front end surface of the first pressing member 230. The vertical pressing surface portion 232 is provided to be vertically at an angle of approximately 90 degrees with respect to the longitudinal direction of the first pressing member 230, and chamfering processing and the like are eliminated. After the microscopic specimen of the film is sampled through the vertical pressing surface portion 232, when the microscopic specimen is discharged to the outside, it can be easily discharged.

A second pressing member 240 is provided on the right side of the flange 220, and the elastic spring 250 may be disposed on an outer surface of the second pressing member 240.

A first diagonal push surface portion 241 in diagonal contact with the unlocking button portion 300 may be provided at a tip portion of the second pressing member 240.

On the other hand, there is a problem in that it is difficult to easily discharge the cut microscopic specimens because they are embedded in the cutting machine, and it is inconvenient to manage the specimens throughout the analysis work. Accordingly, in this embodiment, the unlocking button unit 300 may be provided. The unlocking button part 300 mainly includes a push button 310 exposed on the outer surface of the connection member 400, referring to FIG. 3; A push member 320 having a second diagonal push surface portion connected to the push button 310 and the other end contacting the first diagonal push surface portion 241; And a push spring 330 interposed between the push member 320 and the connection member 400.

When the micro specimen is sampled, the push button 310 is activated due to the pressurized discharge unit 200 sliding to the right side, and the push button 310 can be pushed to slide the pressurized discharge unit 200 to the left. Since the specimen can be ejected selectively, it can be convenient to manage the specimen throughout the component analysis operation.

The cutting block 100 may be connected to the connecting member 400 and a handle part may be connected to the connecting member 400. The handle part 500 may include a vertical handle member 510 provided to partially surround the connection member 400 and a horizontal handle member 520 disposed and coupled to the vertical handle member 510 in the horizontal direction. And. These may be coupled through the coupling bolt 530 and a washer 531 may be interposed in the middle.

Through this configuration, quantitative sampling and durability of the knife tip 101 can be improved through the cutting edge 120 having a preset curvature, so that the component analysis of the film can be accurately performed compared to the prior art, and the air flow groove 231 ), the air flow is smooth, so that the sliding of the pressurized discharge unit 200 from the sampler can be facilitated, and the micro specimen can be selectively discharged by the operation of the unlocking button unit 300, so that the specimen is managed throughout the component analysis work. Can be convenient.

7 is a diagram schematically showing an operating state of a micro-specimen quantitative sampler of a film-type sample according to an embodiment of the present invention.

Hereinafter, the operation of the micro-specimen quantitative sampler of the film-type sample according to the present embodiment will be described in detail with reference to FIGS. 1 to 7.

First, in the default state as shown in FIG. 3, the pressure discharge unit 200, in particular, the vertical pressure surface portion 232, which is the front end of the first pressing member 230, is the knife tip 101 of the cutting block 100, the cutting edge surface ( 120) may be disposed to protrude outward. Through this, the possibility of a safety accident can be prevented in advance.

Next, a sampling operation may be performed on the plate surface of the phthalate film. When the sampler is placed vertically on the plate surface and then the handle part, especially the horizontal handle part, is pressed downward, the pressure discharge part 200 elastically biased by the elastic spring 250 is slid into the cutting block 100.

At this time, while the ground 120 is exposed to the cutting, the plate surface of the film is cut. In this embodiment, the cutting edge surface 120 is provided with approximately 1R, and the curvature of the cutting edge surface 120 may be changed in consideration of factors such as a material of the film or an external environment.

Through the knife tip 101 through the cutting edge 120 as described above, a quantitative microscopic specimen of the phthalate film may be sampled.

Next, as for the pressure discharge unit 200 pushed into the inside, referring mainly to FIG. 7, the convex protrusion 221 is shaped into the concave protrusion 140, and the sliding movement (left and right movement) may be temporarily restricted. Accordingly, the cut microscopic specimen may be accommodated in the cutting block 100, in particular, the knife tip 101.

Next, the microscopic specimen can be selectively discharged. When the operator presses the push button 310, the push member 320 is pressed downward and interacts with the second diagonal push surface portion, so that the first diagonal push surface portion 241 slides to the left, and at the same time, the pressure discharge portion ( 200) is slid to the left side of the cutting block 100.

In this process, the micro specimen accommodated in the knife tip 101 can be discharged to the outside by the vertical pressing surface 232 of the first pressing member 230, and the air flow groove formed in the first pressing member 230 Since 231 is capable of air flow, the left side sliding movement of the pressurized discharge unit 200 may be smoothly possible.

Through this step configuration, since quantitative sampling and durability of the knife tip 101 can be improved, component analysis of the film can be accurately performed compared to the prior art.

In addition, the air flow is smoothed through the air flow groove 231, so that it is possible to easily slide the pressurized discharge unit 200 from the sampler.

In addition, since the micro-specimen can be selectively discharged by the operation of the unlocking button unit 300, it can be convenient to manage the specimen throughout the component analysis operation.

As described above, the present invention has been described in detail using preferred embodiments, but the scope of the present invention is not limited to specific embodiments, and should be interpreted by the appended claims. In addition, those who have acquired ordinary knowledge in this technical field should understand that many modifications and variations are possible without departing from the scope of the present invention.

100: cutting block 101: knife tip
110: taper section 120: ground at the cutting edge
130: separation preventing step 140: concave protrusion
200: pressurized discharge unit 220: flange
221: convex protrusion 222: elastic member
230: first pressing member 231: air flow groove
232: vertical pressing surface part 240: second pressing member
241: first diagonal push surface 250: elastic spring
300: unlocking button part 310: push button
320: push member 321: second diagonal push surface portion
330: push spring 400: connecting member
500: handle portion 510: horizontal handle member
520: vertical handle member 530: coupling bolt
531: washer

Claims (10)

A knife tip is provided from the center to one end, and a tapered section of which the outer diameter decreases toward the tip is provided at the tip of the knife, and a cutting edge of a predetermined curvature is formed at the end of the tapered section to sample microscopic specimens of the phthalate film. Cutting block;
A pressure discharge unit accommodated in the cutting block and provided to be slid in a longitudinal direction to pressurize and discharge the microscopic specimen to the outside; And
And an unlocking button part provided on a connecting member connected to the cutting block to unlock the pressure discharge part temporarily locked to the cutting block when sampling. The method of claim 1,
A separation preventing step is formed inside the cutting block to prevent separation of the pressure discharge unit from the outside,
The pressurized discharge unit,
A flange contacting the separation preventing step;
A first pressing member provided on one side of the flange and partially exposed to the outside of the cutting block during unsampling; And
And a second pressing member extending from the flange to the opposite side of the first pressing member. The method of claim 2,
The pressure discharge unit further comprises an elastic spring interposed between the flange and the connecting member,
The elastic spring is a microscopic specimen quantitative sampler of a film-type sample, characterized in that disposed on the outer surface of the second pressing member. The method of claim 2,
The flange is provided with a convex projection that is elastically biased,
The cutting block has a concave protrusion corresponding to the convex protrusion, characterized in that the quantitative sampler of the fine specimen of the film-type sample. The method of claim 4,
When sampling the fine specimen, the pressure discharge portion is slid and the convex protrusion is temporarily engaged with the concave protrusion. The method of claim 2,
A micro specimen quantitative sampler of a film-type sample, characterized in that a first diagonal push surface portion in diagonal contact with the unlocking button portion is provided at a front end portion of the second pressing member. The method of claim 6,
The unlocking button part,
A push button exposed on the outer surface of the connecting member; And
A push member having one end connected to the push button and the other end provided with a second diagonal push surface portion in contact with the first diagonal push surface portion; And
A micro-sample quantitative sampler of a film-type sample, comprising a push spring interposed between the push member and the connecting member. The method of claim 2,
The first pressing member is provided at regular intervals along the circumferential direction, and at least one air flow groove is formed to be recessed inward along the longitudinal direction of the first pressing member. Quantitative sampler. The method of claim 2,
A quantitative sampler of fine specimens of a film-type sample, characterized in that a vertical pressing surface portion bent vertically is formed on the front end surface of the first pressing member. The method of claim 1,
The ground on the cutting has a curvature between 0.8 and 1.2,
The inner diameter formed by the tip of the ground on the cutting edge is 1.5 ~ 2.5 pie, characterized in that the quantitative sampler of the fine specimen of the film-type sample.

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