KR100821612B1 - A knockdown ventilative reagent cabinet - Google Patents

Abstract

An assembly type ventilation reagent cabinet is provided to use the space of a laboratory effectively and to prevent power waste by using a sensing switch detecting the opening and closing of a door and a control unit effectively operating a delivery fan according to the opening and closing of the door. In an assembly type ventilation reagent cabinet, a body(100) is composed of: a reagent compartment opened and closed by a door installed on the front side, to store reagents; an exhaust hole formed at the back side to communicate with reagent compartment; upper combining perforated holes formed on the upside; lower combining perforated holes formed at the lower side; left combining perforated holes formed on the left sides; and right combining perforated holes formed on the right sides. An external air inflow unit has a penetrating hole formed from the outside of the door to the inside; a blocking plate installed at an inlet of the inside of the penetrating hole; and a filter mounted in the penetrating hole. A sensing switch is turned on or off according to the opening and closing of the door. An exhaust hood(400) is installed at the back side of the body to receive the harmful gas generated from the reagents stored in the reagent compartment, from the exhaust hole and to deliver the harmful gas to the outdoor side by a delivery fan. A control unit(500) comprises a timer sensor and a control sensor. If the timer sensor detects an on-signal transmitted from the sensing switch, the delivery fan is repeatedly operated and stopped according to a set pattern and the blocking plate is opened by the flow of air while the delivery fan is operated. If the timer sensor detects an off-signal transmitted from the sensing switch, the timer sensor stops repeating of the operation and stop of the delivery fan. The control sensor continuously operates the delivery fan if the off-signal transmitted from the sensing switch is detected.

Description

A knockdown ventilative reagent cabinet

The present invention relates to an exhaust reagent chamber, and more specifically, to variously sized reagent fields can be assembled and detached according to the size of the laboratory and the type and amount of the experimental materials to be stored in the reagent room to efficiently use the laboratory's interior space. A prefabricated exhaust reagent field.

In general, the reagent field is installed in a laboratory such as a school or a research institute, and is a kind of furniture for storing reagents or chemicals therein.

Conventional reagent fields are produced relatively heavy to prevent explosion and fire because the liquid reagent may be spilled to the outside when collapsed or shaken by an external impact.

In addition, the conventional reagent cabinet was produced in a state in which a discharging fan and an exhaust hood for discharging harmful gas inside the reagent cabinet to the outside are installed.

Accordingly, the reagent field installed in the laboratory was not easy to be rearranged, and even when the amount of the reagents stored in the reagent field was small, a large reagent field must be used, and thus, the indoor space of the laboratory could not be efficiently used.

In addition, the delivery fan and the exhaust hood installed in the conventional reagent chamber is continuously operated regardless of the opening and closing of the reagent gate door, there is a problem that the power wasted.

The present invention has been made to solve the above-described problems, an object of the present invention is to make the laboratory space and the laboratory space to be detachably assembled in various sizes according to the type and amount of experimental materials to be stored in the laboratory. It is to provide an assembled exhaust reagent field that can be used efficiently.

In addition, the main body is provided with a sensing switch for detecting the opening and closing of the door and a control unit for efficiently operating the operation of the delivery fan according to the opening and closing of the door of the reagent field by the signal detected by the detection switch to waste the power It is to provide a prefabricated exhaust reagent field that can be prevented.

In order to solve the above problems, the assembled exhaust reagent chamber according to the present invention is opened and closed by a door 120 having a reagent chamber 110 in which a reagent is stored therein, and the rear of the reagent chamber 110. An exhaust hole 111 is formed in communication with the upper surface, the upper surface coupling punching hole 130 is formed, the lower surface coupling punching hole 140 is formed on the lower surface, the left surface coupling punching hole 150 is formed, the right surface A main body 100 having a right coupling hole 160 formed therein; and a through hole 210 formed from an outer surface to an inner surface of the door 120, and a blocking film 220 at an inlet of the inner surface of the through hole 210. ) Is installed, the outside air inlet 200, the filter 230 is installed in the through hole 210; and the detection switch 300 that is ON / OFF in accordance with the opening and closing of the door 120; and the It is installed on the back of the main body 100 to generate harmful gas generated from the reagent stored in the reagent chamber 110 An exhaust hood 400 which is received from the exhaust hole 111 and sent out to the outside through a delivery fan 410; And when the signal transmitted by the sensing switch 300 is detected as ON, the transmission fan 410 is repeatedly operated and stopped according to the set pattern, and the blocking film 220 is operated while the transmission fan 410 is operated. The timer sensor 510 is opened by the flow of air, and when the signal transmitted to the sensing switch 300 is sensed to be OFF, the timer sensor 510 which stops the repetition of the set operation and stop of the delivery fan 410: And a control sensor 500 configured to continuously operate the delivery fan 410 when a signal transmitted to the detection switch 300 is detected to be OFF.

In addition, the upper coupling punching holes 130 formed on the main body 100 are coupled to the lower coupling punching holes 140 'and the fastening bolt B of another main body 100', and formed on the main body 100. The lower coupling perforation 140 is coupled via the upper coupling perforation 130 'and the fastening bolt B of another main body 100', and the left coupling perforation 150 formed in the main body 100 is another. The right surface coupling perforation 160 'and the coupling bolt B of the main body 100' are coupled via a medium, and the right surface coupling perforation 160 formed in the main body 100 is the left side coupling perforation of another main body 100 '. (150 ') and the coupling bolt (B) is characterized in that the continuous installation in the vertical, vertical, left and right directions.

As described above, according to the present invention, according to the present invention, it is possible to use the laboratory space efficiently by making it possible to assemble and detach the reagent cabinets of various sizes in accordance with the size and type of the experimental materials to be stored in the reagent cabinet. have.

In addition, the main body is provided with a sensing switch for detecting the opening and closing of the door and a control unit for efficiently operating the operation of the delivery fan according to the opening and closing of the door of the reagent field by the signal detected by the detection switch to waste the power There is an advantage that can be prevented.

Hereinafter, with reference to the accompanying drawings will be described a preferred embodiment of the present invention. Like reference numerals in the drawings denote like elements.

1 is a perspective view of a prefabricated exhaust reagent station according to a preferred embodiment of the present invention, Figure 2 is a view illustrating the assembly of the prefabricated exhaust reagent station according to a preferred embodiment of the present invention, Figure 3 An illustration of the installation of a prefabricated exhaust reagent station according to a preferred embodiment of the invention is shown. In addition, Figure 4 is a perspective view of an open state of the door of the prefabricated exhaust reagent station according to a preferred embodiment of the present invention, Figure 5 is a detailed view of A of Figure 4, a preferred embodiment of the present invention Prefabricated exhaust reagent station according to the body 100, the external air inlet 200, the detection switch 300, the exhaust hood 400, the control unit 500, the reagent chamber 110, the door 120 , The upper coupling perforation 130, the lower coupling perforation 140, the left coupling perforation 150, the right coupling perforation 160, the through hole 210, the blocking membrane 220, the filter 230, and the delivery fan 410. The timer sensor 510 and the control sensor 520 may be further included.

The main body 100 is a place for storing a reagent, and a reagent chamber 110, which is a space in which the reagent is stored, is formed inside the main body 100. In addition, the front of the main body 100, the door 120 for opening and closing the reagent chamber 110 is installed via a hinge, the back of the main body 100, the exhaust hole communicating with the reagent chamber 110 111 is formed, the exhaust hole 111 is in communication with the exhaust hood 400 to be described later.

In addition, the outer surface of the main body 100, the upper coupling punching 130, the lower coupling punching 140, the left coupling punching 150, the right coupling punching 160 is formed, the upper coupling punching 130 is On the upper surface of the main body 100, the lower surface coupling perforation 140 is on the lower surface of the main body 100, the seat surface coupling perforation 150 on the left surface of the main body 100, the right surface coupling perforation 160 Are each formed on the right side of the main body 100.

Accordingly, as shown in FIG. 2, when the main body 100 is continuously installed with another main body 100 ′, the upper surface combined perforation 130 formed in the main body 100 is another main body 100 ′. The lower surface coupling perforation 140 'and the lower surface coupling perforation 140 formed in the main body 100 is the upper surface coupling perforation 130' of another main body 100 'and the left surface coupling formed in the main body 100. The perforation 150 is the right side coupling perforation 160 'of another main body 100', and the right side coupling perforation 160 formed in the main body 100 is the left side coupling perforation 150 of another main body 100 '. ') And the coupling bolt (B) is coupled through.

As described above, when the main body 100 and the other main body 100 'are coupled by the fastening bolt B, the perforations 130, 140, 150, and 160 are tightly sealed, and the fastening bolt B is closed. As shown in FIG. 3B, the surface exposed to the room without being fastened as an intermediate is preferably sealed by a rubber stopper 101.

That is, the main body 100 by the four perforations (130, 140, 150, 160) formed as described above can be installed in a prefabricated manner, depending on the size of the laboratory and the type and amount of experimental materials stored in the reagent cabinet It is characterized in that it can be installed in a shape or size, and, for example, when repositioning the location of the reagent field, such as relocation of the laboratory or transfer, it is natural that the mobility is superior to the conventional reagent field.

In addition, as shown in Figure 3, the exhaust hood 400 to be described later is formed on the back of the main body 100, the exhaust hood 400 is preferably formed integrally with the main body 100, After the assembly of the main body 100 and another main body 100 'is completed, it may be installed. When the delivery fan 410 formed in the exhaust hood 400 is operated, the inside of the reagent chamber 110 may be installed. Noxious gases generated from the stored reagents are sent out to the outside.

The outside air inlet 200 is formed in the door 120, and as shown in FIGS. 5 and 6, the door 120 is exposed to the reagent chamber 110 from an outer surface of the door 120. A plurality of through holes 210 penetrates to the inner surface, which is a surface thereof, are provided in a plurality of holes, and a filter 230 is provided inside the through hole 210.

The filter 230 serves to prevent the deterioration of the reagent stored in the reagent chamber 110, and prevents fine dust and bacteria in the air from entering the reagent chamber 110, the filter 230 is a well-known technology, and thus detailed description thereof will be omitted.

In addition, a blocking film 220 is installed on the inner surface of the through hole 210, and the blocking film 220 is generally a thin and light material so that the through hole 210 is opened and closed according to the suction force of the delivery fan 410 which will be described later. For example, although it is preferable that it is formed as a film, if it can be opened and closed by the suction force of the said sending fan 410, a thin plate may be installed through a hinge.

The detection switch 300 detects the opening / closing of the door 120 as two signals of ON / OFF, and transmits the detected signal to the controller 500 to be described later.

Accordingly, as illustrated in FIG. 4, the sensing switch 300 is preferably formed at the door area where the main body 100 and the door 120 come into contact with each other, and the door 120 is closed and turned on. The state is detected as OFF.

The exhaust hood 400 serves to inhale harmful gas generated from the reagent stored in the reagent chamber 110 from the exhaust hole 111 when the delivery fan 410 is operated. It is installed on the back of the main body 100, the upper side of the exhaust hood 400, as shown in Figure 3, through the discharge fan 410 from the main body 100 with the exhaust hood 400 is installed A suction pipe 420 for sucking harmful gas is formed.

In addition, the exhaust hood 400 installed on the rear surface of the main body 100 as described above sucks the harmful gas generated from the reagent stored in the reagent chamber 110 from the exhaust hole 111, as described above. Although preferably formed integrally with the main body 100, it may be formed prefabricated.

On the other hand, the discharge fan 410 is formed on the upper side of the suction pipe 420 as shown in Figure 4, the harmful gas sucked by the discharge fan 410 is formed as described above, for example, the air conditioning room or It is desirable to transmit directly to the air conditioning duct.

Referring to Figure 3, when the main body is installed vertically, vertically, vertically, the installation method of the exhaust hood is shown.

In addition, as shown in Figure 3, when the main body 100 is continuously installed in the left and right direction, the upper side of the exhaust hood 400, the suction inlet collecting the harmful gas sucked into a plurality of suction pipes (420) in one place ( It is preferable that a 430 is formed, and it is aesthetically preferable that a blocking member 440 is formed on a front surface of the suction port 430 to block a surface where the suction port 430 is exposed to the indoor side.

The controller 500 serves to drive the delivery fan 410 by receiving the signal sensed by the detection switch 300, and is divided into a timer sensor 510 and a control sensor 520, as described above. The operating control unit 500 will be described in detail with reference to FIG. 6.

The timer sensor 510 is activated at the same time as the signal transmitted from the detection switch 300 is ON, that is, the door 120 is closed, as shown in Figure 6, the detection switch 300 When the ON signal is applied from the driving fan 410 repeatedly, and as described above, the blocking film 220 opens and closes the through hole 210 according to the driving pattern of the sending fan 410. do.

When the delivery fan 410 is operated as described above, for example, it is preferable to repeatedly drive the pattern in which the delivery fan 410 is stopped for 5 minutes after 10 minutes of operation. Accordingly, the delivery fan 410 is Power consumption can be reduced compared to when operating continuously.

On the other hand, it is preferable that an operation switch is formed on the outside of the control unit 500 so that the user can set the operation time of the delivery fan 410 according to the amount of harmful gas discharged from the reagent.

In addition, when the delivery fan 410 is operated as described above, the blocking membrane 220 is opened and the outside air flows into the reagent chamber 110 by the amount of air sent out to the outside by the delivery fan 410. Be sure to

On the other hand, when the signal transmitted from the detection switch 300 to the timer sensor 510 is OFF, that is, the door 120 is detected in the open state, the timer sensor 510 is initialized and at the same time the control sensor ( 520 is activated.

When the detection switch 300 is detected to be OFF, the control sensor 520 initializes the setting of the timer sensor 510 and continuously operates the delivery fan 410. Accordingly, the reagent chamber ( 110) Prevents harmful gases from entering the laboratory.

The best embodiments have been disclosed in the drawings and the specification. Herein, specific terms have been used, but they are used only for the purpose of illustrating the present invention and are not intended to limit the scope of the present invention as defined in the claims or the claims. Therefore, those skilled in the art will understand that various modifications and equivalent other embodiments are possible from this. Therefore, the true technical protection scope of the present invention will be defined by the technical spirit of the appended claims.

1 is a perspective view of a prefabricated exhaust reagent station according to a preferred embodiment of the present invention,

Figure 2 is an assembly example assembled with the prefabricated exhaust reagent field and another reagent field according to a preferred embodiment of the present invention,

Figure 3 is an installation example of the assembled exhaust reagent station according to a preferred embodiment of the present invention,

Figure 4 is a perspective view of the open door of the prefabricated exhaust reagent station according to a preferred embodiment of the present invention,

5 is a cross-sectional view of A of FIG.

6 is a flow chart of a schematic operating pattern of a control unit of a prefabricated exhaust reagent station according to a preferred embodiment of the present invention.

<Description of Symbols for Main Parts of Drawings>

100-body 110-reagent

120-door 130-top combined perforation

140-Flat Combined Perforation 150-Flat Combined Perforation

160-Right Side Combined Perforation

200-Inlet air inlet 210-Through

220-blocker 230-filter

300-sensing switch

400-Exhaust Hood 410-Exhaust Fan

500-controller 510-timer sensor

520 control sensor

Claims (2)

A reagent chamber 110 in which a reagent is stored therein is opened and closed by a door 120 provided at a front surface thereof, and an exhaust hole 111 communicating with the reagent chamber 110 is formed at a rear surface thereof, and an upper surface coupled punched hole at the upper surface thereof ( 130 is formed, the lower surface coupling perforation 140 is formed on the bottom surface, the left surface coupling perforation 150 is formed on the left side, the right surface coupling perforation 160 is formed on the right surface; and Through-hole 210 is formed from the outer surface to the inner surface of the door 120, a blocking film 220 is installed at the inlet of the inner surface of the through-hole 210, the filter inside the through-hole 210 Outside air inlet 200 is installed; Detection switch 300 that is ON / OFF according to the opening and closing of the door 120; And Exhaust hood installed on the back of the main body 100 to receive the harmful gas generated from the reagents stored in the reagent chamber 110 from the exhaust hole 111 and to send it to the outside via the delivery fan 410 ( 400); And When the signal transmitted by the sensing switch 300 is detected as ON, the sending fan 410 is repeatedly operated and stopped according to the set pattern, and the blocking film 220 is operated while the sending fan 410 is operated. The timer sensor 510 is opened by the flow of air, and when the signal transmitted to the sensing switch 300 is sensed to be OFF, the timer sensor 510 which stops the repetition of the set operation and stop of the delivery fan 410: and the detection When the signal transmitted to the switch 300 is detected as OFF OFF control sensor 520 for continuously operating the delivery fan 410: Control unit 500 consisting of; Prefabricated exhaust reagent field comprising a The method according to claim 1, The upper coupling punching hole 130 formed on the main body 100 is coupled to the lower coupling punching hole 140 'and the fastening bolt B of another main body 100', The lower coupling perforation 140 formed on the main body 100 is coupled to the upper coupling perforation 130 'and the fastening bolt B of another main body 100', The seat coupling hole 150 formed in the main body 100 is coupled to the right coupling hole (160 ') and the fastening bolt (B) of another main body 100', The right coupling hole (160) formed on the main body 100 is coupled to the left coupling hole (150 ') and the fastening bolt (B) of another main body 100' is installed continuously up, down, left and right direction Prefabricated exhaust reagent station.

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