KR20220080810A - Apparatus for evaluating thermal characteristics of OLED materials - Google Patents

Abstract

The present invention provides a thermal stability evaluation device for materials for OLED. The apparatus for evaluating thermal stability for materials for OLEDs includes: a body in which an internal space is formed; a material storage unit disposed at a lower portion of the inner space of the main body, storing a deposition material, and having distribution holes formed at an upper end of which the deposition material is heated and circulated to the outside; a heating unit configured to heat the deposition material stored in the material storage unit to a set heating temperature; a collecting unit installed on a side wall of the inner space of the main body so as to be disposed above the material storage unit, and collecting the dispersing deposition material; and a monitoring unit installed in the main body and visually monitoring the deposition material stored in the material storage unit.

Description

Thermal stability evaluation device capable of collecting a large number of materials for OLED {Apparatus for evaluating thermal characteristics of OLED materials}

The present invention relates to a thermal stability evaluation device capable of collecting a large number of materials for OLED.

In general, the organic deposition material for OLED is heated to the deposition temperature (evaporation temperature of the material to obtain a thin film deposition rate of about 0.03 to 0.3 nm/s) for a long time in the evaporation source during the deposition process. Physical and chemical changes over time, such as isomerization, phase transition, and thermal decomposition, may affect the quality of the manufactured OLED device.

And in developing new materials, it is necessary to accurately understand their long-term thermal stability.

Accordingly, it is required to develop a technology capable of conducting thermal stability evaluation of various deposition materials within one device in an environment that achieves actual deposition conditions before the actual deposition process of various deposition materials is performed.

Republic of Korea Patent Registration No. 10-1988394

The present invention has been devised to solve the above problems, and a first object of the present invention is to deposit different types of materials by forming an actual deposition environment, and for materials for OLED that can individually collect the deposited materials To provide a thermal stability evaluation device.

In addition, a second object of the present invention is to provide a thermal stability evaluation device for OLED materials capable of monitoring the heating state of the deposition material and the remaining amount of the deposition material in real time while the deposition material is heated.

The objects of the present invention are not limited to the above-mentioned objects, and other objects and advantages of the present invention not mentioned may be understood by the following description, and will be more clearly understood by the examples of the present invention. It will also be readily apparent that the objects and advantages of the present invention may be realized by the means and combinations thereof indicated in the appended claims.

In order to achieve the above object, the present invention provides a thermal stability evaluation device capable of collecting a plurality of materials for OLED.

The thermal stability evaluation device capable of collecting the plurality of OLED materials includes: a body in which an internal space is formed;

a material storage unit disposed at a lower portion of the inner space of the main body, storing a deposition material, and having distribution holes formed at an upper end of which the deposition material is heated and circulated to the outside;

a heating unit configured to heat the deposition material stored in the material storage unit to a set heating temperature;

a collecting unit installed on a side wall of the inner space of the main body so as to be disposed above the material storage unit, and collecting the dispersing deposition material; and,

and a monitoring unit installed in the main body and visually monitoring the deposition material stored in the material storage unit.

Here, the material storage unit,

a storage body having a storage space inside which the deposition material is stored;

It is formed to protrude upwardly from the upper end of the storage body so as to communicate with the storage space, and it is preferable to include a plurality of distribution pipes forming the distribution holes.

And the heating unit,

a coil member disposed to surround the periphery of the side and lower portions of the material storage unit, the coil member having a heating coil disposed therein;

It is preferable to provide a constant current to the heating coil to provide a current providing device for heating the heating coil.

In addition, the material storage unit is provided with a cooling unit,

The cooling unit,

a cooling member having a cooling water circulation passage formed therein;

A cooling water supply unit connected to the cooling member to circulate cooling water having a predetermined cooling temperature through the cooling water circulation passage,

The cooling member is

Preferably, it is arranged to surround the circumference of the coil member.

In addition, the body part,

A weight measuring unit for measuring the weight of the deposition material stored in the material storage unit is provided,

The weight measurement unit,

It is preferable that the load cell is connected to the lower end of the storage body and measures the weight of the deposition material.

In addition, the collecting unit,

a fixing plate fixed to the side wall of the inner space of the main body so as to be disposed on the upper part of the material storage part, protruding to be positioned on the upper part of the material storage part, and having a collection guide hole;

A rotating plate having a plurality of seating holes that are rotatably disposed to form a rotational center on the fixed plate, are formed at regular intervals along a circumference, and are sequentially aligned with the collection guide hole as they are rotated;

a plurality of collecting members seated in the plurality of seating holes and having a deposition surface formed therein;

Provided with a rotating machine for rotating the rotating plate,

The rotator,

Preferably, the rotation plate is rotated so that the plurality of seating holes are sequentially aligned with the collection guide holes.

In addition, the plurality of collecting members,

It is formed of a transparent material, and is gradually expanded from the upper end to the lower side, and the deposition surface is preferably formed inside.

In addition, the collecting unit,

A collection guide is further provided,

The collection guide unit,

A fixing member and a collection guide plate,

The lower end of the fixing member is fixed to the side of the storage body and installed to stand,

It is preferable that one end of the collecting guide plate is fixed to the upper end of the fixing member, and the other end is disposed obliquely along the bottom surface of the rotating plate so that the collecting guide hole is exposed to the distribution holes.

In addition, the fixing member,

It is preferable that it is composed of a multi-stage pipe so that the lifting position can be variably adjusted.

In addition, the monitoring unit,

a lifting bar that is erected so that the lower end thereof is positioned above any one of the distribution holes;

a camera installed at the lower end of the lifting rod;

Provided with an elevator for raising and lowering the lifting rod,

Preferably, the lifting rod is lowered by the operation of the elevator, and the camera is installed at the lower end of the lifting rod and inserted into the storage space of the storage body through the distribution hole.

As described above, the present invention has the effect of depositing different types of materials by forming an actual deposition environment and individually collecting the deposited materials.

In addition, the present invention has the effect of monitoring the heating state of the deposition material and the remaining amount of the material in real time while the deposition material is heated.

In addition to the above-described effects, the specific effects of the present invention will be described together while describing specific details for carrying out the invention below.

1 is a perspective view showing the inside of a thermal stability evaluation device according to the present invention.
Figure 2 is a perspective view showing the inside of the thermal stability evaluation device in a state in which the monitoring unit according to the present invention is installed.
3 is a cross-sectional view showing an example of the configuration of the material storage unit according to the present invention.
4 is a perspective view showing a weight measuring unit according to the present invention.
5 is a perspective view showing a configuration in which a collecting unit according to the present invention is disposed.
6 is another perspective view showing a configuration in which the collecting unit according to the present invention is disposed.
7 is a perspective view showing a fixing plate according to the present invention.
8 is a perspective view showing a rotating plate according to the present invention.
9 is a perspective view showing the coupling relationship between the fixed plate and the rotating plate according to the present invention.
10 is a perspective view showing a monitoring unit according to the present invention.
11 is a perspective view showing an example in which the monitoring unit according to the present invention is disposed on the upper part of the heating unit.
12 is a view showing an example in which the fixing member according to the present invention can be lifted.
13 is a view showing an example in which the inclination angle of the collecting guide plate according to the present invention can be adjusted.

Hereinafter, with reference to the drawings, embodiments of the present invention will be described in detail so that those of ordinary skill in the art to which the present invention pertains can easily implement them.

The present invention may be embodied in many different forms and is not limited to the embodiments described herein.

In order to clearly explain the present invention, parts irrelevant to the description are omitted, and the same reference numerals are assigned to the same or similar components throughout the specification.

In the following, the provision or arrangement of an arbitrary component on the “upper (or lower)” or “top (or below)” of the substrate means that any component is provided or disposed in contact with the upper surface (or lower surface) of the substrate. means that

Further, it is not limited to not include other components between the substrate and any components provided or disposed on (or under) the substrate.

The following describes a thermal stability evaluation device capable of collecting a plurality of materials for OLED of the present invention with reference to the accompanying drawings.

1 is a perspective view showing the inside of the thermal stability evaluation device according to the present invention, Figure 2 is a perspective view showing the inside of the thermal stability evaluation device in a state in which the monitoring unit according to the present invention is installed.

1 and 2 , the thermal stability evaluation device according to the present invention includes a body part 100, a material storage part 200, a heating part 300, a collecting part 400, and a monitoring part ( 500) consists of

Each of the above configurations will be described.

body part (100)

The body part 100 according to the present invention is formed in a box shape in which an inner space is formed. It is preferable that a vacuum is formed inside the body part 100 . The body part 100 is formed of a material having heat resistance.

The main body 100 has a door (not shown). The door may have an opening/closing structure of a rotation type or a sliding type.

material storage unit 200

3 is a cross-sectional view showing an example of the configuration of the material storage unit according to the present invention.

Referring to FIG. 3 , the material storage unit 200 according to the present invention is disposed at the bottom of the internal space of the body unit 200 .

The material storage unit 200 has a storage space formed therein.

The material storage 200 has a storage body 210 and a plurality of distribution pipes 220 .

The storage space is formed inside the storage body 210 . A predetermined amount of a predetermined deposition material to be evaluated is stored in the storage space.

Here, the upper end of the storage body 210 may include a cover 211 to open and close the storage space by opening and closing the cover 211 . The cover 211 may be maintained in a closed state through a separate locking device.

The plurality of distribution pipes 220 are formed at the upper end of the storage body 210, and are formed to protrude upward at a predetermined distance from each other.

The plurality of distribution pipes 210 may be formed of a cylindrical tube or a polygonal tube.

The plurality of distribution pipes 210 are connected to each of the distribution holes 210a formed at the upper end of the storage body 210 . The distribution holes 210a communicate with the storage space.

The plurality of distribution holes 210a may be formed in a shape that is gradually opened from the bottom to the top.

A slip layer on which a deposition material is not deposited may be further coated on the inner periphery of each of the plurality of distribution pipes 220 .

In addition, a monitoring pipe 230 is formed to protrude from the upper end of the storage body 210 at a position spaced apart from the plurality of distribution pipes 220 . The configuration of the monitoring tube 230 will be described later.

heating unit 300

Referring to FIG. 3 , the heating unit 300 according to the present invention is disposed to surround the side and lower circumferences of the material storage unit 200 , and a coil member 310 in which a heating coil 311 is disposed. and a current provider 320 for heating the heating coil 311 by providing a constant current to the heating coil 311 .

The current provider 320 is driven under the control of the controller 600 .

The heating coil 311 is heated according to the received current. Accordingly, the storage body 210 is heated, and the deposition material stored in the storage space of the storage body 210 is heated.

The storage body 210 may include a temperature sensor 610 that measures the temperature in the storage space and transmits it to the controller 600 .

Accordingly, the control unit 600 may drive the heating unit 300 to achieve a set heating temperature so that the deposition material is vaporized.

Also, the material storage unit 200 has a cooling unit 240 .

Cooling unit 240

Referring to FIG. 3 , the cooling unit 240 according to the present invention includes a cooling member 241 having a cooling water circulation passage 241a formed therein, and cooling water connected to the cooling member 241 to achieve a predetermined cooling temperature. It has a cooling water supply 242 that circulates through the circulation passage (241a).

The cooling water supply 242 is driven under the control of the controller 600 .

Here, the cooling member 241 is disposed to surround the circumference of the coil member 310 .

Accordingly, the storage body 210 may be cooled to a predetermined temperature by circulating the cooling water at a predetermined cooling temperature.

The control unit 600 may stop driving the heating unit 200 and drive the cooling unit 240 when the weight of the deposition material reaches the reference weight by the weight measurement unit 700 to be described later. .

Weight measuring unit (700)

4 is a perspective view showing a weight measuring unit according to the present invention.

1 to 4 , a weight measuring unit 700 for measuring the weight of the deposition material stored in the material storage unit 200 is installed in the body unit 100 .

The weight measurement unit 700 is connected to the lower end of the storage unit body 210 and includes a load cell 730 for measuring the weight of the deposition material.

A hole 101 is formed in the bottom of the main body 100 positioned below the storage body 210 .

A load cell 730 is disposed on the side of the hole 101 . The load cell 730 is electrically connected to the control unit 600 .

The storage body 210 includes four supports 710 extending downward.

The upper ends of the supports 710 are connected to the lower edge of the storage body 210 .

The supports 710 are installed through the cooling unit 240 and the heating unit 200 described above. That is, it is preferable that the cooling unit 240 and the heating unit 200 have through-holes through which the supports 710 pass.

The lower ends of the supports 710 are fixed to one support plate 720 .

The support plate 720 is fixed to the upper end of the load cell 730 described above.

Accordingly, the load cell 730 may measure the weight of the deposition material stored in the storage body 210 .

At this time, the control unit 600 is set to perform zero-point adjustment with respect to the weight of the storage body 210 .

collection unit (400)

5 is a perspective view showing a configuration in which a collecting unit according to the present invention is disposed, FIG. 6 is another perspective view showing a configuration in which a collecting unit according to the present invention is disposed, FIG. 7 is a perspective view showing a fixing plate according to the present invention, and FIG. 8 is a perspective view showing the rotating plate according to the present invention, Figure 9 is a perspective view showing the coupling relationship between the fixed plate and the rotating plate according to the present invention.

5 to 9 , the collecting unit 400 according to the present invention is fixed to the sidewall of the inner space of the body unit 100 so as to be disposed on the material storage unit 200, and the material storage unit It protrudes so as to be positioned on the upper part of the 200, and is rotatably disposed to form a center of rotation on the fixed plate 410 and the fixed plate 410 having a collection guide hole 411 formed thereon, and is formed at regular intervals along the circumference. , a rotating plate 420 having a plurality of seating holes 421 that are sequentially aligned with the collection guide holes 411 as they are rotated, and seated in the plurality of seating holes 421, and the deposition surface therein It is composed of a plurality of collecting members 430 formed and a rotating machine 440 for rotating the rotating plate 420 .

The rotator 440 includes a motor shaft 441 and a motor 442 for rotating the motor shaft 441 . The motor 442 rotates the motor shaft 441 under the control of the controller 600 .

The motor shaft 441 is erected and extended by a predetermined length from the upper end of the main body 100 to the inner space.

The lower end of the motor shaft 441 is connected to the center of the above-described rotating plate 420 .

The rotating plate 420 is rotated according to the rotation of the motor shaft 441 .

Accordingly, the rotator 440 may rotate the rotating plate 420 such that the plurality of seating holes 421 are sequentially aligned with the collection guide holes 411 in positions.

In addition, the plurality of collecting members 430 are made of a transparent material, and gradually expand from the top to the bottom, and the deposition surface is formed inside.

Each of the plurality of collecting members 430 is formed in a cone shape. A rod 431 of a certain length is formed at the upper vertex of each collecting member 430 . The rod 431 may serve as a grip.

A lower end of each of the plurality of collecting members 430 forms a circular edge and is seated on a step formed around the seating hole 421 .

In addition, the collection unit 400 according to the present invention further includes a collection guide unit 450 .

The collection guide 450 includes a fixing member 451 and a collection guide plate 452 .

The lower end of the fixing member 451 is fixed to the side of the storage body 210 and installed. The fixing member 451 is formed in a plate shape.

One end of the collecting guide plate 452 is fixed to the upper end of the fixing member 451 , and the other end is along the bottom of the rotating plate 420 so that the collecting guide hole 411 is exposed to the distribution holes 210a. placed obliquely.

Accordingly, the fixing member 451 is erected and installed, so that the collection guide plate 452 is fixed to the upper end of the fixing member 451 and is inclined at a predetermined angle.

The collection guide plate 452 is disposed under the fixing plate 410 , and an upper end thereof is disposed so that the aforementioned collection guide hole 411 is exposed on the upper portion of the storage body 210 .

In addition, an auxiliary fixing member 454 on a plate is erected on the upper end of the storage body 210 .

The auxiliary fixing member 454 is formed in a plate shape.

The lower end of the auxiliary fixing member 454 serves to partition the plurality of distribution pipes 220 to be exposed to the collection guide hole 411 of the fixing plate 410 .

Accordingly, the plurality of distribution pipes 220 are exposed to the collection guide hole 411 through a space between the fixing member 451 and the auxiliary fixing member 454 .

monitoring unit 500

10 is a perspective view illustrating a monitoring unit according to the present invention, and FIG. 11 is a perspective view showing an example in which a monitoring unit according to the present invention is disposed on an upper portion of the heating unit.

Referring to FIGS. 10 and 11 , the monitoring unit 500 according to the present invention includes a lifting rod 510 that is erected so that the lower end is positioned above the monitoring tube 230 , and a lower end of the lifting rod 510 . It consists of a camera 520 installed in the and an elevator 530 for elevating the lifting rod 510 . A transparent quartz tube 511 with a rounded end is formed at the lower end of the lifting rod 510 . The camera 520 is disposed inside the quartz tube 511 .

A locking member 540 is installed between the lifting rod 510 and the quartz tube 511 .

The lifting rod 510 is lowered by the operation of the elevator 530 , and the camera 520 is installed at the lower end of the lifting rod 510 and a monitoring hole 231 formed in the storage unit body 210 . It may be possible to insert into the storage space of the storage body 210 through the.

The elevator 530 may employ other devices including a lifting cylinder capable of elevating the lifting rod 510 .

The elevator 530 raises and lowers the elevator rod 510 under the control of the controller 600 .

A monitoring pipe 230 that is connected to the monitoring hole 231 and extends along the upper portion protrudes from the upper end of the storage body 210 .

Accordingly, when the elevator 530 lowers the lifting rod 510 , the camera 520 installed at the lower end of the lifting rod 510 stores the storage body 210 through the monitoring tube 230 and the monitoring hole 231 . exposed to space.

In addition, the camera 520 may visually capture the amount of the deposition material stored in the storage space and the vaporization state of the deposition material during vaporization, and transmit it to the controller 600 for real-time monitoring.

In addition, it is preferable that the lower end of the lifting rod 510 is formed in a round shape, the camera 520 is installed inside the lower end forming the round shape, and the round lower end of the lifting rod 510 is formed of a transparent material.

In addition, although not shown in the drawings, an opening/closing door or valve for opening and closing the monitoring hole when the lifting rod is drawn in and out may be installed in the monitoring pipe.

12 is a view showing an example in which the fixing member according to the present invention can be lifted.

An example in which the height of the fixing member according to the present invention can be adjusted will be described with reference to FIG. 12 .

Referring to FIG. 12 , a support member 250 having a sliding groove 251 formed thereon is installed at an upper end of the storage body 210 according to the present invention.

A lower end of the fixing member 451 may be inserted into the sliding groove 251 .

Gear teeth 451a are formed on one side of the fixing member 451 .

A gear 252 meshed with the gear tooth 451a in a gear manner is installed on the support member 250 . The center of the gear 252 is connected to the rotation shaft 253a of the gear motor 253 . The gear motor 253 rotates the rotation shaft 253a in forward and reverse directions under the control of the controller 600 .

As the gear 252 rotates in a forward/reverse direction, the fixing member 451 may be moved up and down while being inserted into the sliding groove, so that an elevation position may be adjusted.

Accordingly, the lifting position of the collecting guide plate 452 fixed to the upper end of the fixing member 451 may also be adjusted.

13 is a view showing an example in which the inclination angle of the collecting guide plate according to the present invention can be adjusted.

13, the upper end of the fixing member 451 and the lower end of the collecting guide plate 452 are connected to each other through a hinge shaft (H).

The hinge shaft H is connected to the first rotation shaft 453a of the first rotation motor 453 . The first rotation motor 453 rotates the first rotation shaft 453a under the control of the controller 600 .

Accordingly, the collection guide plate 452 is rotated according to the rotation of the first rotation shaft 453a. Accordingly, the inclination angle of the collecting guide plate 452 may be variably adjustable.

Through the above configuration and action, the present invention has the effect of forming an actual deposition environment and depositing different types of materials and individually collecting the deposited materials.

In addition, the present invention has the effect of monitoring the heating state of the deposition material and the remaining amount of the material in real time while the deposition material is heated.

The present invention is not limited to the specific preferred embodiments described above, and without departing from the gist of the present invention as claimed in the claims, anyone with ordinary skill in the art to which the invention pertains can implement various modifications Of course, such modifications are intended to be within the scope of the claims.

100: body part
200: material storage unit
300: heating part
400: collection unit
500: monitoring unit
600: control unit
700: weight measurement unit

Claims (10)

a body portion in which an inner space is formed;
a material storage unit disposed at a lower portion of the inner space of the main body, storing a deposition material, and having distribution holes formed at an upper end of which the deposition material is heated and distributed to the outside;
a heating unit configured to heat the deposition material stored in the material storage unit to a set heating temperature;
a collecting unit installed on a side wall of the inner space of the main body so as to be disposed on the material storage unit, and collecting the dispersing deposition material; and,
a monitoring unit installed in the main body and visually monitoring the deposition material stored in the material storage unit;
Thermal stability evaluation device for materials for OLED, characterized in that it comprises a.
The method of claim 1,
The material storage unit,
a storage body having a storage space inside which the deposition material is stored;
Thermal stability evaluation device for materials for OLED, characterized in that it is formed to protrude upward from the upper end of the storage body so as to communicate with the storage space, and includes a plurality of distribution pipes forming the distribution holes.
3. The method of claim 2,
The heating unit,
a coil member disposed to surround the side and lower circumferences of the material storage unit, and a heating coil disposed therein;
Thermal stability evaluation device for materials for OLED, characterized in that it provides a constant current to the heating coil, comprising a current providing device for heating the heating coil.
4. The method of claim 3,
The material storage unit is provided with a cooling unit,
The cooling unit,
a cooling member having a cooling water circulation passage formed therein;
A cooling water supply unit connected to the cooling member to circulate cooling water having a predetermined cooling temperature through the cooling water circulation passage,
The cooling member is
Thermal stability evaluation device for materials for OLED, characterized in that it is arranged to surround the circumference of the coil member.
3. The method of claim 2,
The body part,
A weight measuring unit for measuring the weight of the deposition material stored in the material storage unit is provided,
The weight measurement unit,
Thermal stability evaluation device for materials for OLED, characterized in that it is a load cell connected to the lower end of the storage body to measure the weight of the deposition material.
3. The method of claim 2,
The collection unit,
a fixing plate fixed to the sidewall of the inner space of the main body so as to be disposed on the upper part of the material storage part, protruding to be positioned on the upper part of the material storage part, and having a collection guide hole;
A rotating plate having a plurality of seating holes that are rotatably disposed to form a rotational center on the fixed plate, are formed at regular intervals along a circumference, and are sequentially aligned with the collection guide hole as they rotate;
a plurality of collecting members seated in the plurality of seating holes and having a deposition surface formed therein;
Provided with a rotating machine for rotating the rotating plate,
The rotator,
Thermal stability evaluation device for materials for OLED, characterized in that the rotation plate is rotated so that the plurality of seating holes are sequentially aligned with the collection guide holes.
7. The method of claim 6,
The plurality of collecting members,
Thermal stability evaluation device for materials for OLED, characterized in that formed of a transparent material, gradually extending from the top to the bottom, and the deposition surface is formed inside.
7. The method of claim 6,
The collection unit,
A collection guide is further provided,
The collection guide unit,
A fixing member and a collection guide plate,
The lower end of the fixing member is fixed to the side of the storage body and installed to stand,
One end of the collecting guide plate is fixed to the upper end of the fixing member, and the other end is obliquely disposed along the bottom surface of the rotating plate so that the collecting guide hole is exposed to the distribution holes. Thermal stability evaluation for materials for OLED Device.
9. The method of claim 8,
The fixing member is
Thermal stability evaluation device for materials for OLED, characterized in that it is composed of multi-stage pipes and the lifting position can be variably adjusted.
9. The method of claim 8,
The monitoring unit,
a lifting bar that is erected so that the lower end thereof is positioned above any one of the distribution holes;
a camera installed at the lower end of the lifting rod;
Provided with an elevator for raising and lowering the lifting rod,
Thermal stability evaluation for OLED materials, characterized in that the lifting rod is lowered by driving the elevator, and the camera is installed at the lower end of the lifting rod and inserted into the storage space of the storage body through the distribution hole Device.

Images