KR102558533B1 - Isolator for pharmaceutical industry - Google Patents

Abstract

The present invention relates to an isolator for the pharmaceutical industry, and more particularly, to an isolator for the pharmaceutical industry developed to form a laminar flow for biological experiments with production facilities such as pharmaceutical facilities, in which chambers are installed separately and independently to prevent cross-contamination inside the chambers of experimental equipment, and outside air can be circulated and exhausted between chambers.
The present invention includes a control chamber 200 for controlling the isolator; a pre-chamber 202 through which a test object is put into an isolator and passed through to conduct a pre-experiment; Including a main chamber 204 for actually experimenting by putting the experiment object that has passed through the pre-chamber 202,
The flow of outside air is circulated from the top to the bottom of the prechamber 202 to create a laminar flow, and the outside air entering the prechamber 202 is introduced into the main chamber 204 to become a laminar flow, circulated, and then discharged to the outside of the main chamber 204, allowing the prechamber 202 and the main chamber 204 to have separate spaces for experiments and at the same time forming first and second circulation holes to have a laminar flow, thereby preventing cross-contamination. It is characterized in that it is installed to prevent.
As such, the isolator for pharmaceutical industry of the present invention has the effect of preventing internal contamination and cross-contamination by forming laminar flow inside the chamber so as to achieve ISO CLASS 5, and securing excellent exhaust performance capable of uniformly discharging laminar flow. It has the effect of securing.

Description

Isolator for pharmaceutical industry

The present invention relates to an isolator for the pharmaceutical industry, and more particularly, to an isolator for the pharmaceutical industry developed to form a laminar flow for biological experiments with production facilities such as pharmaceutical facilities, in which chambers are installed separately and independently to prevent cross-contamination inside the chambers of experimental equipment, and outside air can be circulated and exhausted between chambers.

An isolator generally refers to a sealed chamber allowing the handling of objects requiring an isolated environment.

Sealed structures with filtration systems that allow the handling of harmful and toxic substances, arranged so that the user can insert his hand into the glove and perform tasks inside the chamber.

All exhaust air leaving the isolator is filtered with a high efficiency particulate air filter or HEPA, thereby removing harmful toxic powdery bacteria and viruses.

The isolator provides an aseptic environment to protect products and materials from the external environment.

Inside the sealed isolator without destroying the aseptic environment of the materials, internal pressures of positive, neutral, and negative pressures are formed, and it includes a rapid transfer port (RTP) and a pass box, and is installed so that materials are rapidly transferred.

The pass box is installed so that the material is used to pass in and out of the isolator, but it has a disadvantage that it is difficult to create a uniform laminar flow, so an isolator for the pharmaceutical industry is not provided, and an isolator for the pharmaceutical industry is required.

Korean Patent Publication No. 10-2012-0122889 (published on November 7, 2012) Korean Patent Publication No. 10-10-2022-0130217 (published on September 26, 2022)

The present invention has been made to solve the above problems, and to form a laminar flow inside the chamber to achieve ISO CLASS 5 to prevent internal contamination and cross-contamination and at the same time to secure uniform exhaust performance. Its object is to provide an isolator for the pharmaceutical industry.

An object of the present invention is to provide an isolator for the pharmaceutical industry for forming a laminar flow and uniformly discharging air by being installed so that air is sucked in from the upper part of the chamber, moved to the inner lower part of the chamber, moved upward through the rear duct part, and uniformly discharged to the outside.

The purpose of the present invention is to maintain a pre-chamber of -25Pa and a main chamber of -50Pa, a wind speed in the chamber of 0.25 ± 0.05m/s, and cleanliness in the chamber of ISO Class 5.

The object and the technical problem to be achieved by the present invention are not limited to the technical problem described above. Therefore, other technical problems not mentioned will be clearly understood by those skilled in the art from the following description.

The present invention includes a control chamber 200 for controlling the isolator;

a pre-chamber 202 through which a test object is put into an isolator and passed through to conduct a pre-experiment;

Including a main chamber 204 for actually experimenting by putting the experiment object that has passed through the pre-chamber 202,

The flow of outside air is circulated from the top to the bottom of the prechamber 202 to create a laminar flow, and the outside air entering the prechamber 202 is introduced into the main chamber 204 to become a laminar flow, circulated, and then discharged to the outside of the main chamber 204, allowing the prechamber 202 and the main chamber 204 to have separate spaces for experiments and at the same time forming first and second circulation holes to have a laminar flow, thereby preventing cross-contamination. It is characterized in that it is installed to prevent.

In the present invention, an exhaust chamber 206 is further provided on the rear side of the main chamber 204 so that the outside air introduced from the main chamber 204 is circulated in a laminar flow and discharged to the outside by the exhaust fan unit 148. It is preferable.

The main chamber 204,

a lattice-shaped lower frame 124 formed at a lower portion;

a stop chamber 130 installed above the lower frame 124;

It is preferable to include an upper chamber 134 installed above the intermediate chamber 130 and having an air supply unit 138 .

As such, the isolator for pharmaceutical industry of the present invention has the effect of preventing internal contamination and cross-contamination by forming laminar flow inside the chamber so as to achieve ISO CLASS 5, and securing excellent exhaust performance capable of uniformly discharging laminar flow. It has the effect of securing.

1 is a perspective view showing the structure of an isolator for the pharmaceutical industry of the present invention
2 and 3 are exploded perspective views showing the structure of the pharmaceutical industry isolator of the present invention
Figure 4 is a front view showing the structure of the pharmaceutical industry isolator of the present invention
Figure 5 is a rear view showing the structure of the pharmaceutical industry isolator of the present invention
Figure 6 is a left side view of Figure 4 of the present invention
Figure 7 is a right side view of Figure 4 of the present invention
Figure 8 is a front cross-sectional view showing the structure of the isolator for pharmaceutical industry of the present invention
Figure 9 is a side cross-sectional view showing the structure of the isolator for pharmaceutical industry of the present invention
10 and 11 are diagrams showing the laminar circulation flow of the isolator of the present invention.

Objects, other objects, features and advantages of the present invention below will be easily understood through the following preferred embodiments in conjunction with the accompanying drawings. However, the present invention is not limited to the embodiments described herein and may be embodied in other forms.

Rather, the embodiments introduced herein are provided so that the disclosed content will be thorough and complete and the spirit of the present invention will be sufficiently conveyed to those skilled in the art.

The present invention includes a control chamber 200 for controlling the isolator; a pre-chamber 202 through which a test object is put into an isolator and passed through to conduct a pre-experiment; It includes a main chamber 204 for actually experimenting by putting an experiment object that has passed through the free chamber 202, but circulates the flow of outside air from the top to the bottom of the free chamber 202 to create a laminar flow, and the outside air entering the free chamber 202 flows into the main chamber 204 to make a laminar flow, circulates, and then discharges the pre-chamber 202 and the main chamber 204 to the outside of the main chamber 204 It is installed to prevent cross-contamination by forming first and second circulation holes to have a laminar flow while allowing experiments to be performed with a separate space.

In the present invention, an exhaust chamber 206 is further provided at the rear surface of the main chamber 204 so that the outside air introduced from the main chamber 204 is circulated in a laminar flow and discharged to the outside by the exhaust fan unit 148. The main chamber 204 includes a grid-shaped lower frame 124 formed therein; a stop chamber 130 installed above the lower frame 124; An upper chamber 134 installed above the intermediate chamber 130 and having an air supply unit 138 is included.

In addition, in the present invention, it is preferable to maintain the pre-chamber -25Pa, the main chamber -50Pa, the wind speed in the chamber to 0.25 ± 0.05m/s, and the cleanliness in the chamber to ISO Class 5.

Embodiments described and illustrated herein also include complementary embodiments thereof.

In this specification, singular forms also include plural forms unless specifically stated otherwise in a phrase. Elements referred to as 'comprise' and/or 'comprising' used in the specification do not exclude the presence or addition of one or more other elements.

Hereinafter, specific embodiments of the isolator for the pharmaceutical industry of the present invention will be described.

1 is a perspective view showing the structure of an isolator for the pharmaceutical industry of the present invention, FIGS. 2 and 3 are exploded perspective views showing the structure of the isolator for the pharmaceutical industry of the present invention, Figure 4 is a front view showing the structure of the isolator for the pharmaceutical industry of the present invention, Figure 5 is a rear view showing the structure of the isolator for the pharmaceutical industry of the present invention, Figure 6 is a left side view of FIG.

And, Figure 8 is a front cross-sectional view showing the structure of the isolator for pharmaceutical industry of the present invention, Figure 9 is a side cross-sectional view showing the structure of the isolator for pharmaceutical industry of the present invention.

10 and 11 are diagrams showing the laminar circulation flow of the isolator of the present invention.

Referring to the isolator for the pharmaceutical industry of the present invention with reference to FIGS. 1 to 11, as shown in FIGS. 1 to 3, the isolator 100 of the present invention includes a control chamber 200, a pre-chamber 202, a main chamber 204, and an exhaust chamber 206.

In the isolator 100 of the present invention, the pre-chamber is -10Pa to -50Pa, the main chamber is -100Pa to -180Pa, the wind speed in the chamber is 0.25±0.05m/s, and the cleanliness in the chamber is ISO Class 5.

The control chamber 200 is installed in the vertical direction, the pre-chamber 202 is installed on the right side of the control chamber 200, the main chamber 204 is installed on the right side of the pre-chamber 202, and the exhaust chamber 206 is installed on the rear side of the main chamber 204.

The controller 108 is installed in the lower part of the control chamber 200 installed as described above, and the display unit 110 is installed in the front of the middle part of the control chamber 200 .

A door part 118 is provided on the front part of the pre-chamber 202, a first circulation hole is formed on the right-side part, and the main chamber 204 is installed on the right part of the pre-chamber 202.

A second circulation hole is formed on the left side of the main chamber 204 and an exhaust chamber 206 is installed on the rear side of the main chamber 204 .

The first circulation hole and the second circulation hole may communicate with each other to receive air supplied from the outside to form a laminar flow.

The air received from the upper direction from the first circulation hole is circulated in the horizontal direction through the second circulation hole and circulated to the main chamber 206 .

Next, the exhaust chamber 206 is connected to the rear part of the main chamber 204, and the air supplied through the pre-chamber 202 and the main chamber 204 is sent through the exhaust chamber 206 and the air introduced from the lower direction through the second circulation hole to the rear direction, and then circulated upward through the exhaust chamber 206 and discharged upward.

As described above, the air entering through the pre-chamber 202 is sent downward and again to the main chamber 204, and then sent from the main chamber 204 to the exhaust chamber 206, and is sent upward from the exhaust chamber 206 to form a laminar flow.

More specifically, the control chamber 200 has a lower frame 102 formed in a horizontal and vertical lattice shape at the lower end, an intermediate chamber 104 is installed on the upper portion of the lower frame 102, and an upper chamber 106 is installed on the upper portion of the intermediate chamber 104.

A controller 108 is installed on the inner side of the lower frame 102, and a display unit 110 is installed on the front side of the middle chamber 104.

In the pre-chamber 202 installed on the right side of the control chamber 200, a horizontally and vertically lattice lower frame 112 is installed at the lower end, an exhaust duct 114 is installed on the upper surface of the lower frame 112, an intermediate chamber 116 is installed on the upper portion of the lower frame 112, and a door unit 118 is installed on the front of the intermediate chamber 116.

An upper chamber 120 is installed above the middle chamber 116 .

The upper chamber 120 is formed in an inverted shape with the front and upper surfaces closed and the rear part open, and an air supply fan unit 122 is provided in the upper chamber 120.

The air supply fan unit 122 draws in external air and supplies it to the pre-chamber 202 to form a laminar flow.

Meanwhile, the main chamber 204 has a lower frame 124 formed at its lower end.

The lower frame 124 is formed in a grid shape connected vertically and horizontally.

An intermediate chamber 130 is installed on the upper portion of the lower frame 124, a door unit 132 is installed on the front side of the intermediate chamber 130, and an upper chamber 134 is installed on the upper portion of the intermediate chamber 130.

As described above, the second circulation hole 131 is formed on the left side of the intermediate chamber 130, and the second circulation hole 131 is preferably installed to be connected to the aforementioned first circulation hole 117.

And, the main chamber 204 has an air supply filter 136 inside and includes an air supply unit 138.

Subsequently, as shown in FIG. 2, the exhaust chamber 206 is installed on the rear surface of the main chamber 204 to exhaust the laminar flow formed in the pre-chamber 202 and the main chamber 204. The exhaust chamber 206 includes a rear duct 140, an intermediate chamber 142, a rear connection duct 144, an upper chamber 146, and an exhaust fan unit 148.

The rear duct 140 is connected to the rear part of the middle chamber 130 of the main chamber 204, and a rear connection duct 144 connected upward is connected to the upper part of the rear duct 140. An upper chamber 146 is installed on the upper part of the rear connection duct 144, and an exhaust fan unit 148 is installed in the upper chamber 146.

4 to 7, in the isolator 100 of the present invention, a control chamber 200, a pre-chamber 202, and a main chamber 204 are installed side by side facing the front, and a controller 108 is installed in the control chamber 200 to control the isolator 100.

The pre-chamber 202 has a door 118 for inserting a test object into the isolator 100, and the door 118 is opened and closed to insert the test object into the chamber.

The main chamber 204 is disposed as a chamber space on the inner side of the main chamber 204 to actually experiment by opening the door 132 of the main chamber 204 and inserting the experiment object into the pre-chamber 202 .

The exhaust of the pre-chamber 202 is moved to the exhaust duct 114 through the air supply fan unit 122, and is exhausted together through the rear duct 140 and the exhaust fan unit 148 connected to the rear end of the main chamber 204 in the exhaust duct 114.

The exhaust chamber 206 is interlocked with the main chamber 204, and the air supplied from the main chamber 204 is introduced from the upper direction and supplied downward to form a laminar flow.

Meanwhile, FIGS. 8 and 9 are cross-sectional views showing the structure of the isolator 100 of the present invention. A controller 108 is installed at the lower part of the control chamber 200 to prevent cross-contamination and test the test object using a PLC to control the test object, and the display unit 110 is installed at the middle portion of the control chamber 200.

An intake duct 114 is installed in the lower frame 112 formed below the pre-chamber 202, and an air supply fan unit 122 is installed in the upper chamber 120.

A first duct 126 and a second duct 128 are provided on the lower frame 124 formed below the main chamber 204, and a first cartridge 127 is installed in the first duct 126. A second cartridge 129 is installed in the second duct 128.

The intermediate chamber 130 is used as a laboratory chamber, and an air supply filter 136 is installed on the ceiling of the intermediate chamber 142 .

The air supply filter 136 is preferably a HEPA filter.

In addition, an exhaust fan unit 148 is installed on the upper ceiling of the main chamber 134, and an air supply unit 138 is installed on the upper ceiling of the exhaust chamber 206.

As shown in the cross-sectional side view of FIG. 9 , an upper chamber 134 is formed in the main chamber 204 and an air supply unit 135 for supplying outside air is provided in the upper chamber 134 .

An intermediate chamber 130 is formed under the air supply unit 135, a second duct 128 is installed under the intermediate chamber 130, and a rear duct 140 is connected and installed on the right side of the second duct 128.

An intermediate chamber 142 and a rear connection duct 14 are connected to the upper part of the rear duct 140, and an upper chamber 146 is connected and installed to the upper part of the rear connection duct 144. An exhaust fan unit 148 for discharging laminar flow air to the outside is installed in the upper chamber 146.

The air supplied through the air supply unit 135 forms a laminar flow and is discharged to the outside air by the exhaust fan unit 148 .

10 and 11 are diagrams showing the front supply air flow and the rear supply air flow forming laminar flow of the isolator of the present invention.

First, FIG. 10 is a diagram showing the flow of the front air supply of the isolator 100 of the present invention. First, the outside air entering through the pre-chamber 202 is supplied from the rear side in parallel in the horizontal direction, then enters from the top vertically and is discharged downward.

At this time, FIG. 11 is a view showing the flow of the supply air at the rear of the isolator 100 of the present invention. It flows downward into the pre-chamber 202, moves horizontally to the left through the first duct 126 and the second duct 128 of the main chamber 204, is exhausted upward through the exhaust chamber 206 at the rear, and flows in from the top through the air supply unit 138 of the main chamber 204. After moving downward, the outside air passes through the exhaust fan unit 148 through the rear duct 140 of the exhaust chamber 206 and is discharged to the outside air.

The technical problems to be achieved in the present invention are not limited to the above-mentioned technical problems, and other technical problems not mentioned above can be variously implemented by those skilled in the art from the description below. Technical changes within these ranges will be said to be within the scope of the present invention.

100: isolator 102: lower frame
104: stop chamber 106: upper chamber
108: controller 110: display unit
112: lower frame 114: exhaust duct
116: stop chamber 118: door unit
120: upper chamber 122: air supply fan unit
124: lower frame 126: first duct
128: second duct 130: stopping chamber
132: door unit 134: upper chamber
136: air supply filter 138: air supply unit
140: rear duct 142: stop chamber
144: rear connection duct 146: upper chamber
148: exhaust fan unit
200: control chamber 202: pre-chamber
204: main chamber 206: exhaust chamber

Claims (3)

a control chamber 200 for controlling the isolator;
a pre-chamber 202 through which a test object is put into an isolator and passed through to conduct a pre-experiment;
Including a main chamber 204 for actually experimenting by putting the experiment object that has passed through the pre-chamber 202,
The flow of outside air is circulated from the top to the bottom of the prechamber 202 to create a laminar flow, and the outside air entering the prechamber 202 is introduced into the main chamber 204 to become a laminar flow, circulated, and then discharged to the outside of the main chamber 204, allowing the prechamber 202 and the main chamber 204 to have separate spaces for experiments and at the same time forming first and second circulation holes to have a laminar flow, thereby preventing cross-contamination. installed to prevent
An exhaust chamber 206 is further provided on the rear side of the main chamber 204 so that the outside air introduced from the main chamber 204 is circulated in a laminar flow and discharged to the outside by the exhaust fan unit 148,
The main chamber 204,
a lattice-shaped lower frame 124 formed at a lower portion;
a stop chamber 130 installed above the lower frame 124;
An upper chamber 134 installed above the intermediate chamber 130 and having an air supply unit 138,
The exhaust chamber 206 is connected to the rear part of the main chamber 204, and the air supplied through the pre-chamber 202 and the main chamber 204 is sent from the lower direction through the second circulation hole through the exhaust chamber 206 to the rear direction, and then circulated upward through the exhaust chamber 206 to be discharged upwardly,
The air entering through the pre-chamber 202 is sent downward, sent again to the main chamber 204, and then sent again from the main chamber 204 to the exhaust chamber 206, and sent upward in the exhaust chamber 206. An isolator for pharmaceutical industry, characterized in that it forms a laminar flow by discharging it.


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