KR100616063B1 - Infrared radiation glass lid for vacuum centrifugal concentrator - Google Patents

Abstract

A heat radiation glass lid for a vacuum centrifugal concentrator is disclosed. The glass lid is for opening and closing the chamber of the vacuum centrifugal concentrator. The glass lid is made of a transparent upper plate glass 10 and a lower plate glass 20. A transparent heating wire applied to the upper plate glass 10 for heat radiation in the infrared or far infrared region. The transparent heating conductor thin film 21 coated on the reflective thin film 11, the lower plate glass 20, and the transparent heating conductor thin film 21 are formed at the edges of the predetermined region so as to generate heat in a predetermined area corresponding to the chamber of the vacuum source concentrator. It has the electrode conductor thin film 22 arrange | positioned, Comprising: It is the electric conductor 50 which can be taken out from this electrode conductor thin film and can apply external power. When the transparent heating conductor thin film generates heat by applying power, most of the heat is transmitted to the lower glass because it partially reflects the transparent heat reflecting thin film of the upper glass, and is radiated from the lower glass to the sample in the chamber in infrared form. That is, the sample in the chamber is directly heated and vaporized by infrared or far infrared rays, which is a form of radiant energy, which is effective for high thermal efficiency and shortening concentration time of the vacuum centrifugal concentrator. In addition, since both the upper plate and the lower plate glass transmit visible light, it is possible to observe the sample in the chamber.

Vacuum Concentrator, Chamber, Lid, Infrared, Radiation, Vaporization

Description

Infrared radiation glass lid for vacuum centrifugal concentrator}

1 is a perspective photograph showing a state in which the lid is open with a vacuum centrifugal concentrator having a lid to which the present invention is applied.

Figure 2 is a side photograph showing a closed state of the vacuum centrifugal concentrator with a lid to which the present invention is applied.

Figure 3 is a cross-sectional view showing the internal structure of the heat radiation glass lid for vacuum centrifugal concentrator according to an embodiment of the present invention.

Figure 4 is a plan view by partially cutting the inner thin film pattern of the top glass constituting the glass lid shown in FIG.

FIG. 5 is a plan view partially showing an inner thin film pattern of the lower plate glass constituting the glass lid shown in FIG. 3; FIG.

Figure 6 is a cross-sectional view showing the internal structure of the heat radiation glass lid for a vacuum centrifugal concentrator according to another embodiment of the present invention.

Explanation of symbols on the main parts of the drawings

10,10 ': top glass 11: transparent heat reflection thin film

12: light shielding film 20,20 ': lower glass

21: transparent heat generating conductor thin film 22: electrode conductor thin film

The present invention is provided to open and close the chamber of the vacuum centrifugal concentrator, and relates to a heat radiation glass lid for a vacuum centrifugal concentrator for radiating heat rays in the infrared or far infrared region with respect to a sample in the chamber.

There is a vacuum centrifugal concentrator among laboratory equipments in various fields such as physics, food, environment, medical and biotechnology. The vacuum centrifugal concentrator is used to obtain a concentrated sample by evaporating the solvent or impurities of the solute of the liquid sample sampled in the course of the experiment in a short time, and also used as a centrifuge for the purpose of separating only the components.

In general, the vacuum centrifugal concentrator has a chamber which is hermetically sealed by a lid, and in such a state is evacuated by the exhaust pump in a vacuum state. A liquid sample tube holder is rotatably installed in the chamber, and the tube holder is usually connected to a motor mounted under the chamber and can be driven at a high speed. When a liquid sample is rotated at a high speed in a chamber evacuated in a vacuum state, the solvent is evaporated and exhausted while the solute is centrifuged from the solvent of the liquid sample by the rotation to obtain a desired concentrated sample.

For efficient experimentation, it is necessary to shorten the concentration time of the vacuum centrifugal concentrator, which requires a means of applying vaporization heat to a temperature suitable for the solvent of the liquid sample. Looking at the related art in this regard, a structure in which an electric heater made of an electric resistance heating element is attached to a chamber outer circumferential wall is disclosed in Japanese Patent Laid-Open Publication No. 2003-0013353 by the inventor, and another type is disclosed in Patent Publication No. 2001-0053884. Disclosed is a structure in which an electric heater is attached to a bottom surface of a chamber of a vacuum centrifuge. As such, when the electric heater attached to the outer surface of the chamber generates heat, the chamber is heated by heat conduction, and the liquid sample is heated and vaporized by convection as the room temperature inside the chamber rises. As is well known, since convection is carried through a medium such as air, the effect of heat transfer by convection in a chamber evacuated in vacuum is very low. In other words, shortening the concentration time by attaching the electric heater to the outer surface of the chamber is not preferable because the heat loss is large.

In this regard, US Patent 5,211,808 proposes a method of applying vaporization heat to microwaves. The microwave can directly heat the liquid sample in the chamber with radiant energy, thus achieving high thermal efficiency. However, microwaves have a problem in that their use is limited, such as destroying sample components due to arc generation, depending on the sample components. In addition, the apparatus for generating microwaves is large and complex, which is disadvantageous in miniaturization and low cost of equipment.

On the other hand, the lids of laboratory equipment, including vacuum centrifugal concentrators, are generally made of glass plates, in order to allow observation of samples in the chamber. In this case, the glass plate should be provided with a metal screen to shield the microwaves from leaking to the outside, so that the sample concentrated in the chamber by the metal screen cannot be observed.

An object of the present invention is to provide a heat-radiating glass lid of a vacuum centrifugal concentrator that can shorten the concentration time of the sample with a high thermal efficiency by radiating the heat rays of the infrared or far infrared region with respect to the sample in the chamber of the vacuum centrifugal concentrator.

Another object of the present invention is to reduce the concentration time of the sample with a high thermal efficiency by radiating the heat rays of the infrared or far infrared region with respect to the sample in the chamber of the vacuum centrifugal concentrator, so that the sample in the chamber can be easily observed. It is to provide a heat radiation glass lid.

Heat-radiating cap of the vacuum centrifugal concentrator according to the present invention to achieve the above objects, to open and close the chamber of the vacuum centrifugal concentrator, and consists of a top plate and a bottom plate to combine two transparent glass plates at intervals up and down, the top plate And heat radiation means for radiating heat rays in the infrared or far-infrared region between the lower panes toward the inside of the chamber.

The heat radiation means between the upper plate and the lower plate glass is connected to a transparent heating conductor thin film coated on the upper surface of the lower plate glass, a pair of electrode conductor thin films coated on the transparent heating thin film, and a pair of electrode conductor thin films, respectively. It may be implemented as an electrical lead drawn out to allow the power to pass through between the upper plate and the lower plate glass.

Here, preferably, the lower side surface of the upper plate glass is coated with a transparent heat reflecting thin film through which visible rays are transmitted while reflecting the heating wire generated from the transparent heat generating thin film of the lower plate glass and radiating upward.

Also preferably, the electrode conductor thin film may be disposed at an edge of the predetermined region such that the transparent heating conductor thin film generates heat only in a predetermined region corresponding to the chamber opening of the vacuum centrifugal concentrator, and the upper glass corresponds to the predetermined region. It may be colored in a light shielding film so as to be transparent in one part but opaque in the other part.

The heat radiation means between the upper plate and the lower plate glass is also applied to the lower surface of the upper plate glass in order to apply the transparent heat reflecting thin film as described above, the transparent heating conductor thin film and the electrode conductor thin film in order to draw the electrical conductor as described above. Can be implemented.

Hereinafter, with reference to the drawings showing preferred embodiments of a heat radiation glass cap for a vacuum centrifugal concentrator according to the present invention.

1 and 2 are attached to the photographic drawing of the vacuum centrifugal concentrator to which the present invention is applied. In these figures, reference numeral 1 denotes a main body case of a vacuum centrifugal concentrator, and 2 denotes a heat radiation glass lid according to the present invention. The glass lid 2 is rotatably supported to open and close the chamber 4 opened on its upper surface by hinges 3 and 3 'connecting between one side edge and one edge of the upper surface of the main body case 1. . The seal frame 5 is enclosed by the opening edge of the chamber 4, and when the glass lid 2 is closed, the inside of the chamber 4 is sealed by the seal frame 5 in the airtight state (FIG. 2). Reference). A liquid sample tube holder 6 is installed in the chamber 4, and the tube holder 6 is mounted in the main body 1 and can be rotated at high speed by a driving means such as an invisible motor. In front of the main body case (1), a power switch, knobs for adjusting the speed and vacuum pressure, key buttons for temperature selection and setting functions, a temperature display board, and a vacuum gauge are installed. In addition, an exhaust pump, a power supply, and a control circuit are installed inside the main body case 1 together with the above-mentioned driving means. Such a conventional structure is well shown in the above-mentioned Patent Publication No. 2003-0013353 by the present inventor. .

3 shows one embodiment of the preferred form of the glass lid 2 according to the invention described above. As shown in Figure 3, the glass lid consists of a top plate glass 10 and a bottom plate glass 20 using two transparent glass plates. Between the edges of the upper glass 10 and the lower glass 20, the spacer 30 for maintaining the gap and the buffer 40 for absorbing shock is interposed.

The upper glass 10 has a function of allowing the lower surface thereof, that is, the surface facing the lower glass 20 to be coated with the transparent heat reflection thin film 11, to allow visible light to pass through and to reflect the heat rays in the infrared or far-infrared region. The transparent heat reflection thin film 11 reflects the heat rays generated from the heat radiation means implemented on the lower plate glass 20 to be described later to radiate upwards to reduce heat loss, and transmit visible light to the inside of the lower chamber. Allow sample to be observed. The composition and coating technique of the transparent heat reflection thin film 11 are conventional, and are well represented, for example, in Japanese Patent Laid-Open No. 93-12609, registered patent No. 1997-0000383, and the like. The top glass 10 also has a light shielding film 12 that blocks visible light by coloring with an opaque paint over the remaining area of the transparent heat reflection thin film 11 except for approximately the center area 11a. . The light shielding film 12 absorbs intense sunlight coming from outside, for example, laboratory light or window, to reduce eye fatigue, and thus to better observe the sample in the chamber through the central region 11a. To do it. For reference, the central region 11a corresponds approximately in position and size to correspond to the opening of the chamber described above.

The lower plate glass 20 has a heat radiating means for radiating heat rays of the above-described infrared ray region (including a far infrared ray region), and is formed on the upper side thereof, that is, the transparent heating conductor applied to the side facing the upper plate glass 10. The thin film 21 and the electrode conductor thin film 22 apply | coated on this transparent heat generating conductor thin film 21 are provided. The transparent heat generating conductor thin film 21 is a conductor through which visible light transmits, and generates heat with Joule heat during electric conduction to emit a large amount of heat rays. The composition and coating technology of such a transparent heating conductor thin film are conventional, and are well represented, for example, in Japanese Patent Application Laid-Open Publication Nos. 93-12609 and 94-25969, Korean Patent Nos. 0150720 and 0150721.

The electrode conductor thin film 22 is for drawing an electric conductor 50 as both conductors to connect an external power source. The electric conductor 50 is made of a coated insulated wire, which is connected to the electrode conductor thin film 22 by soldering, and passes through the spacer 30 and the buffer material 40 between the upper and lower glass plates 10 and 20 to the outside. Then, it is drawn out from the outside, and is drawn back into the main body case from the outside and connected to the power supply circuit side through the above-described control circuit mounted inside the main body case. Referring to FIG. 5, a transparent heating conductor thin film 21 is applied to the entire surface of the lower plate glass 20, and the pair of electrode conductor thin films (edges) of the transparent heating thin film 21 are formed at the edges of the central area 21 a. 22) is arranged. This is a method capable of minimizing heat loss as effective heat radiation, and corresponds to the chamber as described above, so that the current is energized only in the central region 21a so as to generate heat.

When power is applied to the electrode conductor thin film 22, the central region 21a of the transparent heating conductor thin film 21 is energized to generate heat. The heat generated in this way is radiated in all directions, the heat radiated upwards reflects the transparent heat reflection thin film 11 of the upper plate glass 10 to the lower plate glass 20 side, so that most of the heat is lower plate glass 20. The lower glass 20 is radiated to infrared rays (including a far infrared region). The emitted infrared radiation is radiated into the chamber and transmitted directly to the liquid sample in the chamber. The infrared rays, especially the far-infrared region, which are transmitted in this way, resonate with water molecules, and thus have a large thermal effect, thereby acting as an effective vaporization heat. Since the infrared or far-infrared radiation amount is controlled by an applied power source, the heat of vaporization at an appropriate temperature can be adjusted according to the liquid sample.

Next, Figure 6, unlike the previous embodiment, applies the heat radiation means to the upper plate glass 10 ', the lower plate glass 20' relates to an embodiment using a common glass plate. On the lower side of the upper plate glass 10 ', the transparent heat reflection thin film 11, the light shielding film 12, the transparent heat generating thin film 21, and the electrode conductor thin film 22 as described above are sequentially coated. The electric conductor 50 connected by soldering to the electrode conductor thin film 14 is drawn out, and each function is substantially the same as in the previous embodiment.

As is well described in the above embodiments, the heat radiation glass lid for the vacuum centrifugal concentrator according to the present invention radiates infrared or far infrared rays, which is a form of radiant energy, to the chamber, preventing the loss of leakage to the outside, and the liquid sample Because it is directly radiated to, it vaporizes the liquid sample with high thermal efficiency. Therefore, the present invention is effective to shorten the concentration time of the vacuum centrifugal concentrator, and in particular, since it uses heat rays in the infrared or far-infrared region as heat of vaporization, it can be applied to most sample components.

The present invention also uses a glass plate that reflects the heat rays in the infrared region and transmits visible light, so that the heat of vaporization can be applied without affecting the human body, and the sample in the chamber can be observed, thereby enhancing the experimental effect. Therefore, it is effective to provide a good quality concentrated sample.

In addition, according to the present invention, unlike the existing electric heater or microwave generating device is applied to the heat radiation means to the lid, it is possible to use the efficient space of the chamber, which is advantageous for miniaturization of the equipment, and also easy to manufacture and assembly the equipment Can also lower the price.

Claims (8)

A lid for opening and closing the chamber of the vacuum centrifugal concentrator, which is composed of a top plate and a bottom plate of two transparent glass plates spaced up and down, and between the top plate and the bottom plate glass, a heat ray in the infrared or far infrared region toward the inside of the chamber. Heat-radiating glass lid for vacuum centrifugal concentrator, characterized in that provided with a heat radiation means for radiating. The method according to claim 1, wherein as a heat radiation means between the upper and lower plate glass, a transparent conductive transparent heating conductor thin film coated on the upper surface of the lower plate glass, and an conductive electrode conductor thin film coated on the transparent heating thin film and its Heat-radiating glass lid for vacuum centrifugal concentrator, characterized in that the electrical conductor is connected to the electrode conductor thin film is drawn to be connected to the external power source. 3. The heat radiation-emitting glass for a vacuum centrifugal concentrator according to claim 2, wherein the electrode conductor thin film is arranged at an edge of the predetermined region so that the transparent heating thin film generates heat only in a predetermined region corresponding to the chamber opening of the vacuum centrifugal concentrator. Lid. 3. The vacuum according to claim 2, wherein the lower surface of the upper glass is coated with a transparent heat reflecting thin film which reflects a heating wire generated from the transparent heating conductor thin film of the lower glass and radiates upward, while transmitting visible light. Heat-radiating glass lid for centrifugal concentrator. The heat-radiating glass lid for a vacuum centrifugal concentrator according to claim 1 or 4, wherein the top glass has an opaque colored light shielding film in the remaining portions except for a predetermined region corresponding to the chamber opening of the vacuum centrifugal concentrator. The transparent heat ray reflecting thin film according to claim 1, wherein the heat ray radiating means is a transparent heat ray reflecting thin film applied to the lower surface of the upper plate glass to reflect the heat ray and transmit visible light, and a transparent and conductive transparent heating conductor thin film coated on the transparent heat ray reflecting film. A heat-radiating glass lid for a vacuum centrifugal concentrator, comprising: an electrically conductive electrode thin film coated on a transparent heating conductor thin film; and an electric conductor connected to the electrode conductive thin film and drawn out to be connected to an external power source. 7. The heat radiation-emitting glass for a vacuum centrifugal concentrator according to claim 6, wherein the electrode conductor thin film is disposed at an edge of the predetermined region so that the transparent heating conductor thin film generates heat only in a predetermined region corresponding to the chamber opening of the vacuum centrifugal concentrator. Lid. The heat-radiating glass lid for a vacuum centrifugal concentrator according to claim 6 or 7, wherein the top glass has an opaque colored light shielding film in the remaining portions except for a predetermined region corresponding to the chamber opening of the vacuum centrifugal concentrator.

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