JP5399434B2 - Additional ventilation system - Google Patents

Description

  The present invention relates to an additional ventilation system to be added to an existing ventilation system. More specifically, the concentration of formaldehyde can be determined by law without using an existing exhaust duct in a room where formaldehyde is generated. The present invention relates to a technology that makes it possible to reduce to below the standard.

  Conventionally, in formalin-immersed bodies and pathological specimens such as pathological examination rooms, dissection rooms, and excision rooms in hospitals, formalin vaporizes and formaldehyde, a gas harmful to the human body, is generated. Air-conditioner installed in the ceiling air-conditions the outside air to the desired humidity and temperature, mechanically supplies the air indoors, and a suction fan (ventilation fan) installed in the ceiling equals or exceeds the amount of air supplied The total number of ventilations is 17 by the exhaust system (not the total heat exchange type) ventilation system of the ceiling air supply and ceiling exhaust belonging to the first type ventilation that mechanically inhales the amount of polluted air from the room and releases it to the outside air Ventilation was performed at about times / h (see FIGS. 1 and 3).

  In recent years, it has been known that this formaldehyde has a risk of causing nasopharyngeal cancer by being exposed to a high concentration environment for a long time, and that it is a causative substance of sick house syndrome and chemical sensitivity. The Industrial Safety and Health Law Enforcement Ordinance has been revised, and formaldehyde has been designated as a second-class substance in the special rules, and the concentration in the working environment has been obliged to be 0.1 ppm or less.

  However, in a conventional ceiling air supply and ceiling exhaust type ventilation system, formaldehyde having a slightly higher specific gravity than air could not be removed, and a residual concentration of about 0.5 to 0.8 ppm was observed. In order to solve this problem, it is conceivable to provide a local exhaust device or a local ventilator for each site where formaldehyde is generated, such as a dissecting table, a fixed tank, or a cutting table.

  For example, in Patent Document 1, the intake port of the suction box 3 is exposed to the intake opening provided on the inner side of the circumference of the dissection table 1, and the exhaust side of the suction box is connected to the intake side of the collective intake box 5 via the duct 4. And connecting the exhaust side of the collective inhalation box to an exhaust blower via a flexible duct 7 and having a height of the maximum size in the vertical direction of an autopsy specimen on the four sides of the dissection table. Formaldehyde gas of dissection table 1 comprising a flexible board or a comb-like flexible board made of a material and having a cut in a width dimension in which only the elbow or arm portion of the operator falls inward A local exhaust system is disclosed (see FIG. 2 of Patent Document 1).

  In such a ventilation system that exhausts formaldehyde from the source of formaldehyde by individual local exhaust, a dedicated exhaust duct must be provided for each part. In addition, a large-scale renovation work in which a new through-hole is drilled or an existing through-hole is expanded, resulting in a problem that costs increase.

  In addition, pathological examination rooms and anatomical rooms are often installed in the back of hospitals so that they cannot be seen by general patients. The number of existing walls that need to be penetrated is high, which is not only more costly but also bypasses other special facilities such as operating rooms, X-ray rooms, ICUs, and CCUs where it is difficult to provide through holes There is also a problem that a space for providing an individual exhaust duct for each part where formaldehyde is generated cannot be taken.

  Further, in Patent Document 2, a table plane 11 for pathological examination work, which is a formaldehyde generation source, is a suction table 10 having air permeability and capable of discharging contaminated air in a work space by suction, and a suction table. 10 is provided with a blower 20 that is connected via a first air passage 21 and sucks contaminated air. In the exhaust passage of the blower 20, a first deodorizing device 30 by an adsorption action or an oxidation catalytic action, and oxygen cluster ions are provided. A hybrid type deodorizing system for a pathological laboratory is disclosed in which the second deodorizing apparatus 50 is connected to the pathological laboratory after the contaminated air is purified and deodorized by these deodorizing apparatuses 30 and 50 ( (See FIG. 1 of Patent Document 2).

  In such a deodorization system for a pathological laboratory described in Patent Document 2, although deodorization and sterilization can be performed with the oxygen cluster ions of the second deodorization apparatus 50, formaldehyde that is harmful to the human body is removed with oxygen cluster ions. After all, in terms of removal of formaldehyde, it is simply removed by the adsorption action or oxidation catalytic action of the deodorizing device 30 and returned to the room, but only by the adsorption action / oxidation catalytic action of the deodorizing device 30 There is a question whether the concentration in the working environment can be reduced below the standards stipulated by law.

  As another method of clearing the formaldehyde concentration standard, it is conceivable to simply increase the ventilation volume of the ventilation system, but this method also increases the exhaust duct as in the case of the above-mentioned local exhaust. There is a problem that the cost of the work and the installation space cannot be taken.

JP 2006-075592 A JP 2010-279679 A

  Accordingly, the present invention provides an additional ventilation system that solves the above-mentioned conventional problems and can reliably remove and reduce formaldehyde to a concentration lower than the standard stipulated by laws and regulations without requiring additional construction of an exhaust duct. The purpose is to do.

  In order to solve the above-mentioned problem, the invention according to claim 1 is an additional ventilation system using an existing ventilation system installed in a ceiling of a room where formaldehyde is generated, and the concentration at which formaldehyde is generated. A push-pull ventilator is installed near the existing high-concentration facility where the concentration is higher than the predetermined value, and in the vicinity of the existing low-concentration facility where the concentration of formaldehyde is lower than the predetermined value, A pull stage is installed, and the push-pull ventilator has a blowing means for blowing air to the upper part of the work space of the high-concentration facility, and air contaminated with ambient formaldehyde on the lower side of the work space. A suction means for sucking air, and the pull stage is provided with suction means for sucking air contaminated with surrounding formaldehyde, Adsorbing means for adsorbing aldehyde, the suction means of the pull stage and the blowing means of the push-pull ventilator are connected by a first duct, and the push-pull ventilator of the push-pull ventilator The suction means and the exhaust duct of the existing ventilation system are connected by a second duct.

  According to a second aspect of the present invention, in the additional ventilation system according to the first aspect, an airtight flexible member is provided so as to surround the low concentration facility and the pull stage.

  According to a third aspect of the present invention, in the additional ventilation system according to the first or second aspect, a biohazard countermeasure cabinet is installed near the entrance of the room, and the biohazard countermeasure cabinet is an openable / closable cabinet. This cabinet has a blowing means for blowing air above the internal space, a germicidal lamp for sterilizing the internal space by irradiating ultraviolet rays, a HEPA filter for adsorbing the fine particles blown off by the blowing means, The exhaust duct of the biohazard countermeasure cabinet is connected to the exhaust duct of an existing ventilation system.

  According to a fourth aspect of the present invention, in the additional ventilation system according to any one of the first to third aspects, the interior of the room is adjusted to a negative pressure and the wall that separates the interior from the exterior Is characterized in that a pressure adjusting damper is installed.

  According to a fifth aspect of the present invention, in the additional ventilation system according to any one of the first to fourth aspects, an adsorption means for adsorbing formaldehyde is also installed in the second duct. .

  This invention is as described above, and according to the invention of claim 1, an additional ventilation system using an existing ventilation system installed in the ceiling of a room where formaldehyde is generated, A push-pull ventilator is installed in the vicinity of an existing high concentration facility where the concentration of formaldehyde is higher than a predetermined value, and an existing low concentration facility where the concentration of formaldehyde is lower than the predetermined value. A pull stage is installed in the vicinity of the push-pull ventilator, and the push-pull ventilator has blowing means for blowing air to the upper part of the work space of the high-concentration facility, and surrounding formaldehyde on the lower side of the work space. A suction means for sucking air contaminated with air, and the pull stage sucks air contaminated with ambient formaldehyde A stage and an adsorption means for adsorbing formaldehyde, the suction means of the pull stage and the blowing means of the push-pull ventilation device are connected by a first duct, and the push-pull ventilation Since the suction means of the device and the exhaust duct of the existing ventilation system are connected by a second duct, the concentration of formaldehyde can be reduced to a level below the standard stipulated in the law without the need for additional construction of a new exhaust duct. It can be reliably removed and reduced. For this reason, cost reduction can be achieved, and even if there is a room in a place where no duct for individual exhaust can be provided, the concentration standard of formaldehyde stipulated by law can be achieved.

  According to the second aspect of the present invention, in the additional ventilation system according to the first aspect, an airtight flexible member is provided so as to surround the low concentration facility and the pull stage. In addition to the above effects, the formaldehyde generated from a low concentration facility is less likely to diffuse, and formaldehyde can be reliably removed by adsorption.

  According to the invention described in claim 3, in the additional ventilation system according to claim 1 or 2, a biohazard countermeasure cabinet is installed in the vicinity of the entrance of the room, and the biohazard countermeasure cabinet can be freely opened and closed. The cabinet has a blower means for blowing air above the internal space, a sterilization lamp for sterilizing the interior space by irradiating ultraviolet rays, and a HEPA filter for adsorbing the fine particles blown off by the blower means. And the exhaust duct of the biohazard countermeasure cabinet is connected to the exhaust duct of the existing ventilation system, in addition to the above-mentioned effects, harmful substances such as pathogenic bacteria that can be generated from pathological specimens, etc. It can be sterilized and removed, and it can prevent the spread of unknown pathogens as a biohazard measure .

  According to a fourth aspect of the present invention, in the additional ventilation system according to any one of the first to third aspects, the interior of the room is adjusted to a negative pressure, and the interior and the exterior are partitioned. Since the pressure regulating damper is installed on the wall, in addition to the above effects, the negative pressure in the room prevents formaldehyde and pathogens from spreading, and the pressure regulating damper causes excessive negative pressure. It is possible to smoothly open and close the entrance door of the room.

  According to the invention described in claim 5, in the additional ventilation system according to any one of claims 1 to 4, the second duct is also provided with an adsorbing means for adsorbing formaldehyde. In addition to the action and effect, safety at a location where formaldehyde is released to the outside air can be enhanced.

It is a schematic diagram which shows schematic structure of the existing ventilation system. It is a schematic diagram which shows schematic structure of the ventilation system for extension which concerns on embodiment of this invention. It is a structure explanatory drawing which shows each facility used for the structure of an existing ventilation system, and pathological examination. It is composition explanatory drawing which shows each facility used for the structure of the new ventilation system at the time of adding the ventilation system for extension which concerns on embodiment of this invention to the existing ventilation system, and pathological examination. It is a front view of the push-pull ventilation apparatus which concerns on embodiment of this invention. It is a right view of the push pull ventilation apparatus same as the above. It is a top view of a push pull ventilation apparatus same as the above. It is an airflow figure which shows the direction of the airflow of a push pull ventilation apparatus same as the above. It is a front view of the pull stage which concerns on embodiment of this invention. It is a top view of a pull stage same as the above. It is a front view of the biohazard countermeasure cabinet which concerns on embodiment of this invention. It is a right view of a biohazard countermeasure cabinet same as the above.

  The schematic configuration of the additional ventilation system according to the embodiment of the present invention will be described with reference to FIGS. The expansion ventilation system according to the present invention is an invention applied when adding to an existing ventilation system installed in a room where formaldehyde is generated. Therefore, in the description of this embodiment, as a room where formaldehyde is generated, An example of a pathological examination room (also referred to as a cut-out room) for performing pathological examinations in hospitals is provided in the existing ventilation system installed in this pathological examination room and each facility used for pathological examinations, and additional ventilation according to the present embodiment This will be described when adding a system.

First, an existing ventilation system will be described.
An existing ventilation system E1 shown in FIG. 1 includes an air conditioner E2 installed in the ceiling, an air supply duct E3 connected to the air conditioner E2 and communicating with the outside air, and an exhaust fan E4 installed in the ceiling. The exhaust duct E5 is connected to the exhaust fan E4 and communicates with the outside air. The outside air is taken in via the air supply duct E3 by the air conditioner E2 and air-conditioned to a desired humidity and temperature, and then opened to the ceiling surface. The air is supplied into the pathological examination room through the air supply port SH, and polluted air containing formaldehyde generated in the room is sucked in from the exhaust port EH by the exhaust fan E4 and provided upstream of the exhaust fan E4. After the formaldehyde is adsorbed by the activated carbon filter F1, which is an adsorbing means for formaldehyde, it is discharged to the outside air through the exhaust duct E5. Is Temu, has become a full exhaust type of ventilation system is not the total heat exchange type to directly exhaust all without the exchange of heat and moisture to the air supply from the exhaust.

  As described in the background art, in such a ceiling air supply and ceiling exhaust type ventilation system E1, since air is sucked and exhausted from an exhaust port EH provided on the ceiling surface, formaldehyde (formaldehyde having a higher specific gravity than air) is formed. : FA) cannot be successfully eliminated (see FIG. 1), and the concentration in the atmosphere of the working environment determined by law cannot be reduced to 0.1 ppm or less. In addition, formaldehyde FA that could not be removed by the ventilation system E1 is not preferable for safety because it diffuses outside the pathology laboratory.

  Next, the path of the pathological examination will be briefly explained. In the dissection room (not shown), an organ is taken out from the dead human body as a specimen, and immediately after that, the specimen is immersed in formalin, which is an aqueous solution of formaldehyde. And sent to the pathology laboratory. The specimen sent to the pathology laboratory is placed in a fixing tank (not shown) in order to allow formalin to sufficiently penetrate into the cells, and formalin fixation is performed. The specimen for which formalin fixation has been completed is transported to the washing tank E10, where formalin and blood are washed away cleanly and thinned with a cutting table (not shown) so that the lesion can be easily confirmed. Sliced. The sliced specimen is photographed by the photographing apparatus E11 (see FIG. 3).

  As described above, in the pathological examination work, high-formaldehyde is generated in the formalin fixing, washing, and cutting processes that are initial processes, and the concentration of formaldehyde that is gradually generated tends to decrease as the work process proceeds. . As a facility for performing pathological examination, the above-described imaging apparatus E11, sample shelf E12 for storing specimens, container place E13 for storing containers used for pathological examination work, dust box for throwing away wiping knives used for pathological examination, etc. (Not shown), etc., formaldehyde is observed even at a low concentration (see FIG. 3).

  In a specific measurement example, the concentration of formaldehyde in the surroundings shows a dangerous value of several tens of ppm or more with the lid of the fixed tank opened, and is about several tens of ppm near the cleaning tank E10 (see FIG. 3). In the vicinity of the table, it is about several ppm. In the subsequent process, the formaldehyde concentration gradually decreases, and a residual concentration of about 0.5 to 0.8 ppm is observed in the entire room.

  Therefore, in the present invention, the concentration category of generated formaldehyde is clarified, a predetermined value of about several ppm is set as a threshold value, a region where formaldehyde at a higher concentration is generated is a high concentration region, and a low concentration formaldehyde is generated below a predetermined value. The existing facilities used for pathological examinations are classified into high-concentration facilities and low-concentration facilities, respectively, and the high-concentration facilities are equipped with blowing / suction means above them. In order to prevent the diffusion of formaldehyde by airflow, we installed a push-pull ventilation device, which will be described later, which is a local exhaust means that can exhaust, considering that formaldehyde whose specific gravity is heavier than air accumulates in the low concentration facility near the floor, Formaldehyde is captured efficiently and economically by installing a pull stage, which will be described later, as a suction / exhaust means, near the floor near the low-concentration facility. To remove, it is aimed to improve the work environment.

  2 and 4 indicate an additional ventilation system according to the embodiment of the present invention. The additional ventilation system 1 mainly includes a push-pull ventilation device 2, a pull stage 3, and a biotechnology. As shown in FIG. 4, an additional ventilation system 1 having such a configuration is added to the existing ventilation system E1 (see FIG. 3), and this push-pull ventilation is configured. The device 2 and the pull stage 3 are connected by a duct D1, which is a first duct, and the push-pull ventilation device 2 and an existing exhaust fan E4 are connected by a duct D2, which is a second duct. A new ventilation system 1 ′ is constructed in the pathology laboratory by connecting the cabinet 4 and the existing exhaust fan E4 with a duct D3 which is an exhaust duct.

  The new ventilation system 1 ′ thus constructed takes in outside air through the air supply duct E <b> 3 by the air conditioner E <b> 2, air-conditions it to a desired humidity and temperature, and performs a pathological examination from the air supply opening SH that opens to the ceiling surface. The air is supplied into the room, and the contaminated air containing formaldehyde is sucked by the push / pull ventilator 2, the pull stage 3, and the biohazard countermeasure cabinet 4, respectively, and is provided upstream of the exhaust fan E4. After the formaldehyde is adsorbed by the activated carbon filter F1, which is an adsorbing means for formaldehyde, air containing formaldehyde is discharged to the outside air by the exhaust fan E4 through the exhaust duct E5.

Moreover, this new ventilation system 1 ′ prevents the pathogenic bacteria from diffusing outside by adjusting the air supply amount and the exhaust amount to keep the inside of the pathological examination room at a negative pressure. Specifically, when the pathology laboratory has a frontage of 6500 mm × depth of 3600 mm × height of 2700 mm, negative pressure is obtained by supplying about 1020 m ³ / h with the air conditioner E2 and exhausting about 1100 m ³ / h with the exhaust fan E4. Keep.
A pressure adjusting damper DP is installed on the wall that divides the pathological examination room from the outside so that the pressure difference from the outside becomes a predetermined pressure (−5 Pa in the present embodiment). For this reason, it becomes possible to prevent the opening and closing of the entrance door of the pathology laboratory from being obstructed by excessive negative pressure.

  In addition, if the exhaust amount of the push-pull ventilator 2 or the biohazard countermeasure cabinet 4 can secure a necessary exhaust amount, the existing exhaust fan E4 is removed, and the push-pull ventilator 2 and the exhaust duct E5, The biohazard countermeasure cabinet 4 and the exhaust duct E5 may be directly connected.

  Next, the detailed structure of the push-pull ventilation apparatus 2 is demonstrated using FIGS. This push-pull ventilator 2 is a high-concentration facility, that is, a fixed tub, a cleaning tub (E10), and a push-pull type local exhaust device (ventilator) installed above a cutting table (FIG. 2, 4), a pair of left and right blow fans 21 and 22 as blow means for blowing air, a pair of left and right suction fans 23 and 24 as suction means for sucking ambient air, and a blow fan A pair of left and right air curtain fans 25 and 26 that blow out airflow faster than 21 and 22 to form an air curtain, and a control box 27 in which a control device for controlling the plurality of fans is housed.

  The apparatus main body 20 includes a flat box-shaped air supply unit 20a that extends over the work space of the high-concentration facility, an exhaust unit 20b that is provided on the back side of the air supply unit 20a, and the exhaust unit 20a. A pair of left and right duct portions 20c and 20d extending downward from both left and right ends of the portion 20b is formed, and a stainless steel shelf 20e is bridged between the duct portions 20c and 20d.

  The air supply unit 20a is divided into two at the center, and the blower fans 21 and 22 and the air curtain fans 25 and 26 are accommodated in the respective interiors, and duct connection ports 20f and 20g to which the duct D1 is connected at the upper part thereof. Is provided, and the lower end surface thereof is an outlet Ih. In addition, side curtains C1 and C2 made of a vinyl curtain, which is a flexible member having airtightness, are suspended at both ends of the air supply unit 20a in order to prevent diffusion of formaldehyde.

  In the exhaust part 20b, a duct connection port 20h to which the duct D2 is connected is formed slightly to the left of the upper center, and the exhaust part 20b and the duct parts 20c and 20d communicate with each other inside the duct part 20c. A suction port Oh is formed at the lower end of 20d, and suction fans 23 and 24 are attached to the upper part thereof.

According to the push-pull ventilator 2 configured as described above, the suction fans 21 and 22 and the suction fans 23 and 24 suck the pressure while pressing, so that the work of the high concentration facility is performed as shown in FIG. Since polluted air can be exhausted while forming a downward flow in the space, there is little risk of formaldehyde diffusing and it can be efficiently eliminated.
Further, the air curtain fans 25 and 26 can blow out an air flow faster than the blow fans 21 and 22 to form an air curtain, and the work space is enclosed together with the side curtains C1 and C2, thereby further diffusing formaldehyde. Can be effectively eliminated.

Next, a detailed configuration of the pull stage 3 will be described with reference to FIGS. 9 and 10.
The pull stage 3 is a low concentration facility, that is, a pull type local exhaust device installed on a floor in the vicinity of a photographing device E11, a sample shelf E12, a container place E13 (see FIG. 3), and a dust box (not shown). Yes, the stage main body 30, the suction fan 31 that is a suction means installed in the stage main body 30, and the aldehyde adsorption that adsorbs and removes aldehydes such as formaldehyde from the contaminated air sucked by the suction fan 31. A plurality of activated carbon filters 32 for dealdehyde are used as means.

  The stage main body 30 includes a flat, substantially box-shaped main body portion 30a having a small depth, and a rectangular tubular duct portion 30b having a substantially square horizontal cross section that communicates with a side end portion of the main body portion 30a. A suction port 30c is formed in front of 30a, and a suction fan 31 is provided inside the suction port 30c. A cartridge-type activated carbon filter 32 that can be attached to and detached from the stage main body 30 is installed in the exhaust direction of the suction fan 31, and the exhaust gas rear end side of the activated carbon filter 32 reaches the duct portion 30 b.

The upper surface of the duct portion 30b is a duct connection port 30d to which the exhaust duct D1 is connected. The contaminated air sucked by the suction fan 31 from the suction port 30c passes through the activated carbon filter 32. A harmful substance such as formaldehyde is adsorbed to the activated carbon filter 32 and reaches the blower fan 21 or the blower fan 22 of the push-pull ventilator 2 through the duct connection port 30d through the exhaust duct D1. For this reason, since the inertial force of the air flow given to the air by the suction fan 31 of the pull stage 3 is added to the air blowing force given by the blowing fan 21 or the blowing fan 22 of the pull stage 2, push-pull ventilation. The downward flow generated by the apparatus 2 becomes stronger, and formaldehyde can be efficiently removed from the room.
When the pressure loss in the duct connection port 30d or the duct D1 is large, an exhaust fan may be added in the middle of the duct D1 in addition to the suction fan 32 as shown in FIG.

  According to the pull stage 3 configured as described above, since it is installed on the floor near the low concentration facility, it is possible to efficiently suck in formaldehyde whose specific gravity is heavier than that of air, and formaldehyde with the activated carbon filter 32. Since it is adsorbed and removed and sent to the blowing fan 21 or the blowing fan 22 of the pull stage 2, the air flow is accelerated by the inertial force, and the formaldehyde removal efficiency in the pull stage 2 is improved.

  As exemplified around the sample shelf E12 in FIG. 2 and the imaging device E11 in FIG. 4, it may be airtight so as to surround the low concentration facility (sample shelf E12, imaging device E11) and its pull stage 3. The vinyl curtain VC, which is a flexible member, may be suspended from the ceiling, and by providing the vinyl curtain VC, there is less risk of formaldehyde generated from low-concentration facilities being diffused, and the formaldehyde is reliably removed by adsorption. Can do.

Next, a detailed configuration of the biohazard countermeasure cabinet 4 will be described with reference to FIGS. 11 and 12.
The biohazard countermeasure cabinet 4 is a push-pull type local exhaust device having a function of sterilizing and removing pathogens provided near the entrance of the pathology laboratory and preventing the spread of pathogens. A blower fan 41 which is installed in the cabinet body and blows out air; a suction / exhaust fan 42 which sucks air and exhausts contaminated air from inside the cabinet; and is provided directly below the blower fan 41. A HEPA filter 43 that collects fine particles, a sterilization lamp 44 that is provided further below the HEPA filter 43 and sterilizes by irradiating ultraviolet rays, and the like.

  The cabinet body 40 includes a lower caster portion 40a which is movable with a caster, and a cabinet portion 40b installed on the lower caster portion 40a. The cabinet portion 40b can be opened and closed forward and downward. A slide glass 40c is fitted. The inside of the slide glass 40c is formed of a cavity, and a sterilization part 40d is formed, which is a space for inserting a hand to wipe off sterilization and foreign matters. Above the sterilization part 40d, the blowout fan 41 and the HEPA filter 43 are provided. The sterilizing lamp 44 is installed on the back of the sterilizing unit 40d, and the suction / exhaust fan 42 is installed below the sterilizing unit 40d.

  Further, inside the cabinet part 40b, a circulatory duct part 40e that is partitioned from the sterilizing part 40d by providing a predetermined space below and on the rear surface of the sterilizing part 40d. The front suction port 40f is opened at the front, and the rear suction port 40g is opened at the back. For this reason, a downward flow is formed in the sterilization part 40d by driving the blower fan 41 and the suction / exhaust fan 42, and the cabinet passes from the front suction port 40f and the rear suction port 40g to the top of the blower fan 41 through the circulation duct part 40d. It is comprised so that it may circulate in the part 40b.

Further, an exhaust dust box 45 is provided on the cabinet body 40, and an exhaust HEPA filter 46 is provided below the exhaust dust box 45 to prevent particulates and pathogens from being released to the outside air. . In the upper part of the exhaust dust box 45, a duct connection port 45a connected to the duct D3 is provided.
If the pressure loss at the duct connection port 45a or the pressure loss at the duct D3 can be covered, the above-described suction / exhaust fan 42 can be omitted.

  The above-mentioned HEPA filter (High Efficiency Particulate Air Filter) shows a particle collection rate of 99.97% or more with respect to particles having a rated air volume and a particle size of 0.3 μm, and an initial pressure loss of 245 Pa or less. It refers to the air filter with the performance of. In the present embodiment, a HEPA filter that exhibits a particle collection rate of 99.99% or more for particles having a rated air volume and a particle size of 0.3 μm is employed.

  According to the biohazard countermeasure cabinet 4 configured in this way, after the pathological examination, the surgeon opens the slide glass 40c of the cabinet part 40b, inserts his hand into the sterilization part 40d, and the blower fan 41 and the suction / exhaust fan are placed in the hand. Since the fine particles adhering to the hand are blown off by blowing the downward flow of air generated in 42, and the fine particles blown off by the HEPA filter 43 and the exhaust HEPA filter 46 are collected and exhausted, the fine particles that can be generated from a pathological sample or the like are collected. Adherent harmful substances such as pathogenic bacteria can be sterilized and removed, and the spread of unknown pathogenic bacteria can be prevented as a biohazard countermeasure.

  As described above, a pathological examination room has been described as an example of a room in which the additional ventilation system 1 according to the embodiment of the present invention is installed. However, a room to which the additional ventilation system of the present invention can be applied The expansion ventilation system of the present invention is applied not only to the laboratory but also to the room where formalin-immersed bodies and pathological specimens, such as the dissection room and the excision room (also known as pathological laboratory), are treated with formaldehyde. Is possible.

  Moreover, the shape, structure, etc. of each component shown in the drawings as the additional ventilation system 1 according to the embodiment of the present invention are only a preferable example, and the design can be appropriately changed within the scope of the claims. Needless to say. In particular, it is clear that the object of the present invention can be achieved without the exhaust fan E4, the activated carbon filter F1, and the biohazard countermeasure cabinet 4. In short, when adding to an existing ventilation system installed in the ceiling of a room where formaldehyde is generated, the additional ventilation system of the present invention can be applied.

1 Ventilation system for expansion 1 'New ventilation system 2 Push / pull ventilators 21 and 22
23, 24 Suction fan (suction means)
3 Pull stage 31 Suction fan (suction means)
32 Activated carbon filter (aldehyde adsorption means)
4 Resident Evil Countermeasure Cabinet 41 Blowout fan (Blowout means)
42 Suction / exhaust fan (suction / exhaust means)
43 HEPA filter 44 germicidal lamp D1 duct (first duct)
D2 duct (second duct)
D3 Duct (exhaust duct)
E1 Existing ventilation system E2 Air conditioner E3 Air supply duct E4 Exhaust fan E5 Exhaust duct DP Pressure adjustment damper VC Vinyl curtain (flexible member with airtightness)

Claims (5)

An additional ventilation system using an existing ventilation system installed in the ceiling of a room where formaldehyde is generated,
A push-pull ventilator is installed in the vicinity of an existing high concentration facility where the concentration of formaldehyde is higher than a predetermined value, and an existing low concentration facility where the concentration of formaldehyde is lower than the predetermined value. There is a pull stage in the vicinity of
The push-pull ventilator is provided with blowing means for blowing air to the upper part of the work space of the high-concentration facility, and suction means for sucking air contaminated with ambient formaldehyde on the lower side of the work space. And
The pull stage is provided with a suction means for sucking air contaminated with surrounding formaldehyde, and an adsorption means for adsorbing formaldehyde,
The suction means of the pull stage and the blowing means of the push-pull ventilator are connected by a first duct, and the suction means of the push-pull ventilator and the exhaust duct of the existing ventilation system are second. Ventilation system for expansion, characterized by being connected by a duct.   The expansion ventilation system according to claim 1, wherein a flexible member having airtightness is installed so as to surround the low concentration facility and the pull stage. Near the entrance of the room, a biohazard countermeasure cabinet is installed,
The biohazard countermeasure cabinet has an openable / closable cabinet. The cabinet has a blowing means for blowing air above the internal space, a sterilizing lamp for sterilizing the internal space by irradiating ultraviolet light, and the blowing means. And a HEPA filter that adsorbs the fine particles blown away by
The additional ventilation system according to claim 1 or 2, wherein an exhaust duct of the biohazard countermeasure cabinet is connected to an exhaust duct of an existing ventilation system.   The interior of the room is adjusted to a negative pressure, and a pressure regulating damper is installed on a wall that divides the interior and the exterior. Ventilation system for expansion.   The additional ventilation system according to any one of claims 1 to 4, wherein adsorption means for adsorbing formaldehyde is also installed in the second duct.

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