CN111622542A

CN111622542A - Isolation system

Info

Publication number: CN111622542A
Application number: CN202010591316.8A
Authority: CN
Inventors: 何伟; 朱国远; 饶涛; 黄愉太
Original assignee: Shenzhen Juding Medical Device Co ltd
Current assignee: Shenzhen Ruili Medical Technology Co.,Ltd.
Priority date: 2020-06-24
Filing date: 2020-06-24
Publication date: 2020-09-04

Abstract

The embodiment of the invention discloses an isolation system, which comprises: the air exchange device comprises a closed structure, a supporting device, an air exchange device and a standby power supply, wherein the closed structure can be unfolded to form a hollow cavity, and the closed structure comprises an opening and closing mechanism which is used for communicating or isolating the hollow cavity with an external space; the supporting device can unfold the closed structure; the air interchanger is used for communicating the hollow cavity with the external space and adjusting the air pressure of the hollow cavity to be lower than that of the external space; the standby power supply can supply power to the air interchanger when the power is off so as to maintain the normal work of the air interchanger, so that the air pressure of the hollow cavity is lower than that of the external space, and the diffusion of harmful substances in the hollow cavity is effectively prevented under the condition of power failure.

Description

Isolation system

Technical Field

The invention relates to the technical field of protection, in particular to an isolation system.

Background

The harmful substances are usually transmitted through the air, and in order to prevent the diffusion of the harmful substances, the harmful substances are generally isolated from the outside in an isolating manner. The traditional isolation system prevents harmful substances from leaking through negative pressure, and because the traditional isolation system generally adopts a temporary building structure, the stability of a power supply system is poor, and the isolation system cannot work normally due to power failure and power failure.

Disclosure of Invention

The invention aims to provide an isolation system when harmful substances are prevented from diffusing along with air, so as to solve the technical problems that a power supply system in a traditional isolation system is poor in stability and the isolation system cannot work normally due to the fact that power supply faults and power failure easily occur.

In order to achieve the purpose, the technical means adopted by the invention are as follows:

an isolation system, comprising:

the sealing structure can be unfolded to form a hollow cavity and comprises an opening and closing mechanism used for communicating or isolating the hollow cavity with an external space;

a support device capable of deploying the enclosure;

the air interchanger is used for communicating the hollow cavity with the external space and adjusting the air pressure of the hollow cavity to be lower than that of the external space; and

the standby power supply can supply power to the air interchanger when the power is off.

In one embodiment, the power supply further comprises a power consumption component, and the standby power supply is connected with the power consumption component and is used for supplying power to the power consumption component when power is off.

In one of the embodiments, the power consuming components comprise one or more of a breathing unit, a lighting unit, a heating unit, a monitoring unit and a calling unit.

In one embodiment, the charging device is connected with the standby power supply and used for supplying power to the standby power supply.

In one embodiment, the system further comprises a power supply mechanism and an induction piece, wherein the power supply mechanism is connected with an external power grid and used for supplying power to the isolation system, and the induction piece is connected with the power supply mechanism and used for detecting the power supply condition of the power supply mechanism.

In one embodiment, the system further comprises a control unit, and the control unit can control a standby power supply to supply power to the isolation system when power is cut off.

In one embodiment, the support device comprises a plurality of support mechanisms, and the backup power source is disposed within one or more of the plurality of support mechanisms.

In one embodiment, the ventilation device comprises an air inlet mechanism, an air outlet mechanism and a purification mechanism, wherein the purification mechanism is used for purifying the gas passing through the air inlet mechanism and the gas passing through the air outlet mechanism;

the air inlet mechanism is used for introducing air into the hollow cavity, and the exhaust mechanism is used for exhausting the air in the hollow cavity so as to adjust that the air pressure of the hollow cavity is lower than that of the external space.

In one embodiment, the support mechanism includes bodies, at least one of the bodies is provided with the air intake mechanism, and at least one of the bodies is provided with the exhaust mechanism.

In one embodiment, the isolation system further comprises a telescoping link for driving adjacent support mechanisms toward and away from each other.

The embodiment of the invention has the following beneficial effects:

by adopting the isolation system, the standby power supply can supply power to the air interchanger when the power is off so as to maintain the normal work of the air interchanger, so that the air pressure of the hollow cavity is lower than that of the external space, and the diffusion of harmful substances in the hollow cavity is effectively prevented under the condition of power failure.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the drawings without creative efforts.

Wherein:

FIG. 1 is a front view of an embodiment of an insulation system as it is deployed.

Fig. 2 is an axial view of the isolation system shown in fig. 1.

Fig. 3 is a top view of the isolation system shown in fig. 1.

FIG. 4 is an axial view of the closure structure of the insulation system of FIG. 1.

Figure 5 is an axial view of the support assembly in one embodiment when retracted.

Fig. 6 is an enlarged view of the part a in fig. 5.

Fig. 7 is an enlarged view of the part B in fig. 5.

Fig. 8 is a schematic view of the isolation system of fig. 1 with the support device deployed in the X-direction.

Fig. 9 is a schematic view of the isolation system of fig. 1 with the support device extended in the Y direction.

FIG. 10 is a schematic view of the isolation system of FIG. 1 with the telescoping rod extended.

Fig. 11 is a schematic structural view of a first support mechanism in the isolation system of fig. 1.

Fig. 12 is a schematic structural view of a third support mechanism in the isolation system shown in fig. 1.

FIG. 13 is a schematic structural view of the first gas drive unit/the second gas drive unit in the isolation system of FIG. 1.

Fig. 14 is a schematic view of the connection strips in the insulation system of fig. 1.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

The embodiment of the present invention provides an isolation system 10 for preventing harmful substances from being transmitted through air, wherein the harmful substances include harmful gases, harmful liquids and harmful solid particles which can be transmitted along with air, mycoplasma and pathogens which can be transmitted along with air, and the harmful substances also include aerosol containing the mycoplasma and/or the pathogens. Of course, in other embodiments of the present invention, the isolation system 10 can also be used to prevent the transmission of harmful substances through other media, or other non-harmful substances, or in other situations where a negative pressure is required, and is not limited herein.

Referring now to fig. 1-14, an isolation system 10 according to the present invention will be described. An isolation system 10, comprising: the air conditioner comprises a closed structure 100, a supporting device 200, a ventilation device and a standby power supply 400, wherein the closed structure 100 can be unfolded to form a hollow cavity, the closed structure 100 is a flexible structure or a folding structure which can be composed of a plurality of splicing plates, the folding structure can be folded to reduce the size and is convenient to carry, and a certain space is reserved after the folding structure is unfolded. The closed structure 100 includes an opening and closing mechanism 110, and the opening and closing mechanism 110 is used for communicating or isolating the hollow cavity with an external space; support device 200 can expand enclosed construction 100, realize the quick of enclosed construction 100 and build, breather is used for intercommunication cavity and exterior space, and the atmospheric pressure of adjustment cavity is less than the atmospheric pressure of exterior space, the cavity is through opening and shutting mechanism 110 and exterior space intercommunication or keep apart, when opening and shutting mechanism 110 closed, the cavity can be kept apart with external space completely, effectively prevent the diffusion of harmful substance, stand-by power supply 400 can be for the breather power supply when the outage, in order to maintain breather's normal work, so that the atmospheric pressure of cavity is less than the atmospheric pressure of exterior space, effectively prevented under the outage circumstances, the diffusion of harmful substance in the cavity.

In this embodiment, the isolation system 10 further includes a power consuming component, and the backup power source 400 is connected to the power consuming component and is configured to supply power to the power consuming component when the power is cut off, so as to maintain the normal operation of the power consuming component when the power is cut off. Preferably, the power consuming components include one or more of a breathing unit, a lighting unit, a heating unit, a monitoring unit and a calling unit, and may be configured according to design requirements of the isolation system 10, and may selectively connect some of the power consuming components with the standby power supply 400 according to emergency levels, so as to ensure that the power consuming components with high priority can ensure power supply, and thus ensure stable operation of the isolation system 10. Of course, in other embodiments, the power consuming components may also include other power consuming devices such as a defibrillator, which may be selected based on the design of the isolation system 10.

In this embodiment, the isolation system 10 further comprises a charging device connected to the backup power source 400 and configured to supply power to the backup power source 400, and when the power supply is normal, store enough power for the backup power source 400 to supply the isolation system 10 when the power supply is off, and preferably, the backup power source 400 is a lithium battery.

In this embodiment, the isolation system 10 further includes a power supply mechanism and an induction element, the power supply mechanism is connected to an external power grid and is configured to supply power to the isolation system 10, the induction element is connected to the power supply mechanism and is configured to detect a power supply condition of the power supply mechanism, specifically, the isolation system 10 further includes a control unit, when the induction element detects a fault of the power supply mechanism and stops supplying power to the isolation system 10, the control unit can control the standby power supply 400 to supply power to the isolation system 10 when the power is cut off, so that when the external power supply mechanism is suddenly powered off, the standby power supply 400 can also continuously supply power to the isolation system 10 for a period of time, thereby ensuring normal operation of the isolation system 10 and avoiding function stop of the isolation system 10 due to power cut off.

Referring to fig. 1 to 4, the sealing structure 100 is a flexible structure, and the unfolded shape of the sealing structure 100 may be a rectangular parallelepiped, a cylinder, a semi-spherical body, or other shapes capable of forming a certain space. In the present embodiment, the shape of the sealing structure 100 is a rectangular parallelepiped. Specifically, the enclosure 100 includes a bottom section 120, a top section 130, and

side sections

140, 120, 130 and 140 between the bottom section 120 and the top section 130 that are unfolded to form a hollow cavity. In this embodiment, the opening and closing mechanism 110 includes two opening and closing portions 111, the two opening and closing portions 111 are closed in a magnetic attraction manner or a mechanical connection manner, and a sealing structure is further disposed between the two opening and closing portions 111 to ensure that the hollow cavity is isolated from an external space when the opening and closing mechanism is closed. The side subsection 140 also has a viewing window 141 made of transparent medium.

In this embodiment, the opening and closing mechanism 110 is a door body structure for people to get in and out, and the opening and closing portion 111 is a flexible structure, for example, the opening and closing portion 111 is a flexible curtain, and two opening and closing portions 111 are folded in a manner of deviating from each other to form a passage for getting in and out of the hollow cavity. It should be understood that in other embodiments, the top of the opening/closing portion 111 and the side away from the other opening/closing portion 111 are integrally connected to the sealing structure 100, the bottom of the opening/closing portion 111 is detachably connected to the sealing structure 100, and the connection can be achieved by a magnetic attraction manner or a mechanical connection manner, and a sealing structure is disposed between the bottom of the opening/closing portion 111 and the sealing structure 100 to ensure that the hollow cavity is isolated from the external space when closed. That is, an L-shaped connecting seam is formed between adjacent opening/closing portions 111 and the bottom of the opening/closing portion 111, and the opening/closing portion 111 is lifted along the L-shaped connecting seam to enter and exit the hollow cavity. When the opening and closing mechanism 110 is closed, the sealing structure 100 is a full sealing structure, and gas can be exchanged only through the ventilation device, so that absolute isolation of harmful substances from the outside is ensured.

In this embodiment, the support device 200 includes a plurality of support mechanisms, and the backup power supply 400 is disposed in one or more of the plurality of support mechanisms. Of course, in other embodiments, the backup power source 400 may be disposed at other positions of the isolation system 10, for example, at four corners of the hollow cavity, and may also meet the emergency power requirement.

Further, the support device 200 is capable of deploying the enclosure 100. Adjacent supporting mechanism can connect as an organic whole when being close to, and accessible magnetism is inhaled the mode or mechanical mode and is connected. The closure structure 100 can be deployed when adjacent support mechanisms are far apart. Furthermore, a telescopic rod is arranged at the top of the supporting mechanism and can be contained in the supporting mechanism. When the adjacent supporting mechanisms are far away from each other, the height of the supporting mechanisms cannot meet the requirement that when the closed structure 100 is expanded in the axial direction of the supporting mechanisms, the telescopic rods extend out of the supporting mechanisms and are locked to improve the height of the supporting mechanisms, the closed structure 100 is expanded into a final shape, and the closed structure 100 is connected with the supporting mechanisms and the telescopic rods through connecting pieces. The bottom of the support mechanism has rollers 210 to facilitate the approach and departure of adjacent support mechanisms. The roller 210 is provided with a locking portion that locks the roller 210 after the support mechanism has moved to a predetermined position, to prevent the support mechanism from moving. The presence of the rollers 210 also facilitates the overall movement of the support device 200, and the enclosure structure 100 is a flexible structure, which allows for greater overall portability of the isolation system 10 when collapsed.

In this embodiment, the supporting device 200 includes a first supporting mechanism 220, a second supporting mechanism 230, a third supporting mechanism 240 and a fourth supporting mechanism 250, the first supporting mechanism 220 and the second supporting mechanism 230 and the third supporting mechanism 240 and the fourth supporting mechanism 250 are connected through a magnetic element, an elastic element is wrapped around the magnetic element to reduce impact caused by collision during connection, and the first supporting mechanism 220 and the fourth supporting mechanism 250 and the second supporting mechanism 230 and the third supporting mechanism 240 are connected through a lock catch 260. The lock catch 260 includes a connection block 261 and a connection groove, the connection block 261 is rotatable with respect to the first/second supporting mechanisms 220/230, a connection protrusion 2611 is formed thereon to match the connection groove formed on the third/fourth supporting mechanisms 240/250, and the connection block 261 and the connection groove may be magnetically or mechanically connected. Further, the piece is inhaled to magnetism is electromagnetic, is provided with touch switch 270 on the strutting arrangement 200, can realize the outage and the circular telegram of the piece of magnetism through touch switch 270 to the magnetic attraction that the piece was inhaled to messenger disappears and forms. The elastic component is extruded and forms the elastic force after magnetic attraction forms, and when magnetic attraction disappears, under the effect of elastic force, first supporting mechanism 220 and second supporting mechanism 230 that link as an organic whole through hasp 260 and third supporting mechanism 240 and fourth supporting mechanism 250 that link as an organic whole through hasp 260 can bounce each other, conveniently expand as holistic first supporting mechanism 220 and second supporting mechanism 230 and third supporting mechanism 240 and fourth supporting mechanism 250 as a whole with the help of inertia. The piece is inhaled to magnetism produces touching touch switch 270 once after the magnetic attraction, and the magnetic attraction disappears, touches touch switch 270 once again, and the magnetic attraction produces again.

Further, the isolation system 10 further includes a telescoping connection frame 300, the connection frame 300 being used to drive adjacent support mechanisms closer together and farther apart. The connecting frame 300 comprises a first connecting frame 310 connected between the second supporting mechanism 230 and the third supporting mechanism 240, a second connecting frame 320 connected between the third supporting mechanism 240 and the fourth supporting mechanism 250, and a third connecting frame 330 connected between the fourth supporting mechanism 250 and the first supporting mechanism 220, and through the arrangement of the three groups of connecting frames 300, the supporting mechanisms which are close to each other can be far away from each other, and the far direction and distance can be limited, so that the closed structure 100 can be unfolded. As described above, when the magnetic attraction force disappears, the first and second supporting

mechanisms

220 and 230 integrated by the latch 260 and the third and fourth supporting

mechanisms

240 and 250 integrated by the latch 260 can be elastically released from each other by the elastic force, and the second linking frame 320 is extended in the X direction in fig. 8 to unfold the first and second supporting

mechanisms

220 and 230 and the third and fourth supporting

mechanisms

240 and 250 as a whole. Thereafter, the latch 260 is opened, the first link 310 is extended in the Y direction of fig. 9 to unfold the second and

third support mechanisms

230 and 240, the third link 330 is extended in the Y direction of fig. 9 to unfold the first and

fourth support mechanisms

220 and 250, and finally, each support mechanism is locked by the roller 210. In this embodiment, the connecting frame 300 is formed by a plurality of connecting rods 301 hinged end to end, and the two connecting rods 301 at the end are connected to the corresponding support mechanisms, respectively.

Further, the detecting device is used for detecting the air pressure of the hollow cavity, and the ventilation device is used for exchanging the purified air inside and outside the sealing structure 100 so as to adjust the air pressure of the hollow cavity to be lower than the air pressure of the external space. Furthermore, the ventilation device is a fresh air device with a purification function, and the ventilation device comprises an air inlet mechanism, an exhaust mechanism and a purification mechanism, wherein the purification mechanism is used for purifying the gas passing through the air inlet mechanism and the gas passing through the exhaust mechanism. The air inlet mechanism is used for introducing air into the closed structure 100, and the air outlet mechanism is used for discharging the air in the closed structure 100 so as to adjust the air pressure of the hollow cavity to be lower than that of the external space.

Specifically, the exhaust mechanism is communicated with the hollow cavity and used for adjusting the air pressure of the hollow cavity to be lower than that of the external space. The air inlet mechanism comprises a first air inlet end 225, a first air outlet end 226 and a first channel located between the first air inlet end 225 and the first air outlet end 226, a first air driving unit 500 is arranged on the first channel, the first air inlet end 225 is communicated with an input end 501 of the first air driving unit 500, the first air outlet end 226 is communicated with an output end 502 of the first air driving unit 500, and air located in an external space of the closed structure 100 is driven by the first air driving unit 500 and can enter the hollow cavity through the first channel. The exhaust mechanism comprises a second air inlet end 243, a second air outlet end and a second channel located between the second air inlet end 243 and the second air outlet end, a second air driving unit 600 is arranged on the second channel, the second air inlet end 243 is communicated with an input end 601 of the second air driving unit 600, the second air outlet end is communicated with an output end 602 of the second air driving unit 600, air located in the hollow cavity is driven by the second air driving unit 600, and the air can be discharged out of the hollow cavity through the second channel. The purification mechanism is including setting up in the first air purification net of first passageway and setting up in the second air purification net of second passageway, and first air purification net and second air purification net are the HEPA filter screen, and wherein, the second air purification net still has the disinfection function of disinfecting to guarantee that exhaust gas is free of harmful substance. Further, the hollow cavity is enabled to form negative pressure through the combined action of the air inlet mechanism and the air outlet mechanism.

As shown in fig. 14, further, a connection strip 1111 is provided at a detachable connection position of the opening and closing portion 111 and the connection position between the adjacent opening and closing portions 111, and the connection strip 1111 provided at the connection position between the adjacent opening and closing portions 111 is fixedly connected to one of the opening and closing portions 111. The connecting strip 1111 is located the circumference of the portion 111 that opens and shuts and keeps away from one side of cavity, because be the negative pressure in the cavity, connecting strip 1111 adsorbs in each junction, guarantees that the cavity is kept apart from external space, and connecting strip 1111 surface is handled in order to reduce its sliding friction power, and then reduces the portion 111 that opens and shuts and open the resistance. The connecting strip 1111 can be made of flexible materials and can deform under the action of air pressure, and the hollow cavity is further guaranteed to be isolated from the external space.

Further, the supporting mechanism comprises bodies, at least one body is provided with an air inlet mechanism, and at least one body is provided with an exhaust mechanism. At least one body is provided with an operation console, and the operation console controls the gas flow passing through the gas inlet mechanism and the gas flow passing through the gas outlet mechanism according to the gas pressure value detected by the detection device.

Specifically, the first supporting mechanism 220 includes a first body 221, an air inlet mechanism is disposed in the first body 221, the first air outlet end 226 is communicated with the hollow cavity, a roller 210 is disposed at the bottom of the first body 221, a first telescopic rod 222 capable of extending out of the top of the first body 221 is accommodated in the first body 221, an operation console is further disposed in the first body 221, the operation console includes a display screen 223, a processing unit, a receiving unit, a sending unit and a report generating unit, and the processing unit is used for controlling the air flow passing through the air inlet mechanism and the air flow passing through the air outlet mechanism according to the air pressure value detected by the detecting device. The receiving unit is used to receive external signals, such as control signals, to control the operation of the isolation system 10, data signals, including examination information of infected patients, and the like. The transmitting unit is used to transmit signals to the outside, such as operation information of the isolation system 10, monitoring data of an infected patient, and the like. The report generation unit is used to generate and export a paper report from the report outlet 224 of the first body 221, which may include status information of the isolation system 10, monitoring data of an infectious patient, or an examination report of an infectious patient, etc. over a period of time. The display screen 223 is disposed on the top end of the first body 221, and is used for displaying the air pressure value detected by the detection device, the air flow of the air intake mechanism and the air exhaust mechanism, the monitoring data of the infectious patient, or the examination report of the infectious patient, and the display screen 223 has an interactive function.

Further, the second supporting mechanism 230 includes a second body 231, the bottom of the second body 231 is provided with a roller 210, and the second body 231 accommodates a second telescopic rod 232 which can extend from the top thereof. The second body 231 is also formed with a storage groove 233 for storing articles. As shown in fig. 7, the touch switch 270 is disposed on the second body 231, and is a foot touch switch, on which a sliding prevention portion 271 is disposed and can rotate relative to the second body 231. As shown in fig. 1 to 3 and 8 to 10, the opening and closing mechanism 110 is disposed between the first supporting mechanism 220 and the second supporting mechanism 230. In order to drive the opening and closing mechanism 110 to open and close, a cross beam 280 is arranged between the first telescopic rod 222 and the second telescopic rod 232, and a driving mechanism for driving the opening and closing mechanism 110 to open and close is arranged on the cross beam 280.

Further, the third supporting mechanism 240 includes a third body 241, an air exhausting mechanism is disposed in the third body 241, a second air inlet 243 is communicated with the hollow cavity, a roller 210 is disposed at the bottom of the third body 241, and a third telescopic rod 242 capable of extending out from the top of the third body 241 is accommodated in the third body 241. The first air outlet end 226 and the second air inlet end 243 are arranged diagonally, which is beneficial to rapid diffusion of the gas entering the hollow cavity, for example, for a patient needing oxygen inhalation, air with higher oxygen content can be introduced from the first channel; when the hollow cavity body needs to be sterilized, sterilizing gas can be introduced from the first channel; when the harmful substances in the hollow cavity need to be removed or reacted, the corresponding gas can be introduced from the first channel.

Further, the fourth supporting mechanism 250 includes a fourth body 251, as shown in fig. 3, in which the backup power source 400 is partially cut away, it can be seen that the backup power source 400 is disposed in the fourth body 251 to ensure that the isolation system 10 can still operate when the external power supply to the isolation system 10 is stopped. The fourth body 251 is provided at the bottom thereof with a roller 210, and the fourth body 251 accommodates a fourth telescopic rod 252 which can be extended from the top thereof. Of course, in other embodiments, the backup power source 400 may also be disposed within one or more of the first support mechanism 220, the second support mechanism 230, the third support mechanism 240, and the fourth support mechanism 250 to provide power to the isolation system 10 when power is removed.

When the supporting device 200 is retracted, the first supporting mechanism 220, the second supporting mechanism 230, the third supporting mechanism 240 and the fourth supporting mechanism 250 can surround to form an accommodating space 290, and the closed structure 100 can be retracted and the cross beam 280 can be folded to be accommodated in the accommodating space 290, so that the portability of the isolation system 10 during retraction is improved.

The above disclosure is only for the purpose of illustrating the preferred embodiments of the present invention, and it is therefore to be understood that the invention is not limited by the scope of the appended claims.

Claims

1. An isolation system, comprising:

a support device capable of deploying the enclosure;

2. The isolation system of claim 1, further comprising a power consuming component, the backup power source being coupled to the power consuming component and configured to power the power consuming component when powered off.

3. The isolation system of claim 2, wherein the power consuming components comprise one or more of a respiratory unit, a lighting unit, a heating unit, a monitoring unit, and a calling unit.

4. The isolation system of claim 1, further comprising a charging device coupled to the backup power source and configured to provide power to the backup power source.

5. The isolation system of claim 1, further comprising a power supply mechanism and an inductive element, wherein the power supply mechanism is connected to an external power grid and is configured to supply power to the isolation system, and the inductive element is connected to the power supply mechanism and is configured to detect a power supply condition of the power supply mechanism.

6. The isolation system of claim 1, further comprising a control unit capable of controlling the backup power source to power the isolation system when power is removed.

7. The isolation system of claim 1, wherein the support device comprises a plurality of support mechanisms, and the backup power source is disposed within one or more of the plurality of support mechanisms.

8. The isolation system of claim 1, wherein the ventilation device comprises an intake mechanism, an exhaust mechanism, and a purification mechanism for purifying gas passing through the intake mechanism and gas passing through the exhaust mechanism;

9. The isolation system of claim 8, wherein the support mechanism includes bodies, at least one of the bodies having the air intake mechanism disposed thereon and at least one of the bodies having the exhaust mechanism disposed thereon.

10. The isolation system of claim 8, further comprising a telescoping link for driving adjacent support mechanisms closer together and further apart.