KR101903549B1 - Energy Saving System using Control of Exhaust Air Amount and Controlling Air Inflow Rate of Inflow Air Speed Control of Multi - Fume Hood - Google Patents

Abstract

The present invention relates to an exhaust system and an energy saving system in accordance with airflow control of a multi-fume hood. More specifically, in the multi-fume hood, an exhaust amount of the multi-fume hood is controlled so that intake air is kept constant at all times irrespective of an opening/closing amount of a door, and a predetermined space corresponding to the multi-fume hood is also controlled to a predetermined supply amount so as to be a predetermined sound pressure. Therefore, it is possible to prevent unnecessary exhaust and intake air, thereby achieving an energy saving effect.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an energy saving system for controlling exhaust air flow rate in a multi-fume hood,

The present invention controls an amount of exhaust to keep the intake speed of each of a number of fume hoods constant at a constant time and controls the amount of supply correspondingly, thereby preventing unnecessary energy consumption due to unnecessary supply of air, And a constant pressure control system of the hood.

Generally, the fume hood is an essential facility for maintaining a pleasant laboratory work environment by forcibly discharging gas such as gas, odor, steam, etc., which is installed in a place handling a toxic chemical substance or in a laboratory, The fume hood is provided with a working plate so that a working space is formed therein. A door is vertically openable and closable at the front, and an exhaust duct is provided at an upper portion to exhaust the harmful gas generated in the working space.

The door provided on the front surface of the thus configured fume hood is appropriately opened and the experiment is performed using an experimental apparatus placed on the work plate. The harmful gas generated during the experiment is exhausted to the outside through the exhaust duct.

However, in the case of the conventional fume hood, as the door is opened and gradually closed, the wind speed flowing into the fume hood is increased. However, the fume hood is not exhausted in accordance with the opening and closing amount of the fume hood, As the air in the laboratory is fed into the laboratory, the amount of air to be fed into the laboratory is required. In this way, the air to be fed into the laboratory is maintained at an appropriate temperature and humidity according to the laboratory conditions, There has been a problem in energy loss.

Korean Registered Patent No. 10-1347217 (Registered on December 26, 2013)

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and it is an object of the present invention to provide a fume hood control apparatus and a fume hood control method, And the air supply is controlled so as to maintain the predetermined sound pressure inside the predetermined space in which the plurality of fume hoods are installed, by controlling the external exhaust unit for exhausting air from the plurality of fume hoods in accordance with the control by the damper The intake speed varies depending on the door opening / closing amount of each of the plurality of fume hoods, the exhaust amount increases as the intake air speed increases, and the exhaust amount of the corresponding external exhaust portion and the intake portion of the intake portion also increase, The control of the exhaust volume by controlling the wind speed of the multi-fume hood to prevent the increase of energy loss To provide an energy-saving system according to the control group.

Other objects and advantages of the present invention will be described hereinafter and will be understood by the embodiments of the present invention. Further, the objects and advantages of the present invention can be realized by the means and the combination shown in the claims.

In order to solve the above problems, the present invention provides a fume hood comprising: a fume hood having a plurality of doors installed in a predetermined space; It is possible to determine whether or not the fume hood 11 is exhausted and the displacement of the fume hood 11 to the individual dampers 22 so that the intake air speed entering the interior of the fume hood 11 is always maintained at the preset intake air speed irrespective of the door opening / closing amount of the fume hood 11. [ A fume hood exhaust unit 20 for controlling the fume hood exhaust gas temperature; The external exhaust unit 40 is provided in the single duct 30 connected to the multi-fume hood exhaust unit 20 and corresponds to the fume hood 11 in which the door opening and closing amount is changed, ; The measured differential pressure in the predetermined space 10 is compared with the preset differential pressure so that the predetermined space 10 is constantly set to the predetermined negative pressure corresponding to the displacement of the multiple fume hood 11, An air supply control unit 50 for controlling the air supply amount; And a control unit.

As described above, according to the present invention, the intake speed is not increased according to the door opening / closing amount of each of a plurality of installed fume hoods, and a constant speed is maintained at all times, thereby limiting unnecessary exhaust and air supply. , It is possible to prevent the energy loss occurring in the case of pretreatment of air to be supplied (cooling / heating, humidification, dehumidification, sterilization, disinfection, etc.) in advance.

Also, according to the present invention, the fume hood exhaust unit, the external exhaust unit, and the air supply control unit installed in each of the plurality of fume hoods are operated in conjunction with each other, and the external exhaust unit and the air supply control unit are also operated corresponding to the door opening / closing amount or the exhaust amount of the fume hood , It is possible to reliably and rapidly reduce the energy of the multi-fume and control the static pressure.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a view of an embodiment showing an energy saving system according to an exhaust amount control and an air supply control by controlling the air speed of a multi-fume hood according to the present invention. FIG.
2 is a graph of an embodiment showing the relationship between the intake air velocity and differential pressure of the multi-fume hood of the present invention.
3 is an exemplary view showing a pressure distribution in a fume hood for specifying a position capable of ensuring the representative of an intake rate of the multi-fume hood of the present invention and a representative position (or representative point) of the differential pressure sensor.

Before describing in detail several embodiments of the invention, it will be appreciated that the application is not limited to the details of construction and arrangement of components set forth in the following detailed description or illustrated in the drawings. The invention may be embodied and carried out in other embodiments and carried out in various ways. It should also be noted that the device or element orientation (e.g., "front,""back,""up,""down,""top,""bottom, Expressions and predicates used herein for terms such as "left,"" right, "" lateral, " and the like are used merely to simplify the description of the present invention, Or that the element has to have a particular orientation. Also, terms such as " first "and" second "are used herein for the purpose of the description and the appended claims, and are not intended to indicate or imply their relative importance or purpose.

The present invention has the following features in order to achieve the above object.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Reference will now be made in detail to the preferred embodiments of the present invention, examples of which are illustrated in the accompanying drawings. Prior to this, terms and words used in the present specification and claims should not be construed as limited to ordinary or dictionary terms, and the inventor should appropriately interpret the concepts of the terms appropriately It should be interpreted in accordance with the meaning and concept consistent with the technical idea of the present invention based on the principle that it can be defined.

Therefore, the embodiments described in this specification and the configurations shown in the drawings are merely the most preferred embodiments of the present invention and do not represent all the technical ideas of the present invention. Therefore, It is to be understood that equivalents and modifications are possible.

To this end, according to an embodiment of the present invention,

A fume hood (11) having a plurality of doors installed in a predetermined space (10); It is possible to determine whether or not the fume hood 11 is exhausted and the displacement of the fume hood 11 to the individual dampers 22 so that the intake air speed entering the interior of the fume hood 11 is always maintained at the preset intake air speed irrespective of the door opening / closing amount of the fume hood 11. [ A fume hood exhaust unit 20 for controlling the fume hood exhaust gas temperature; The external exhaust unit 40 is provided in the single duct 30 connected to the multi-fume hood exhaust unit 20 and corresponds to the fume hood 11 in which the door opening and closing amount is changed, ; The measured differential pressure in the predetermined space 10 is compared with the preset differential pressure so that the predetermined space 10 is constantly set to the predetermined negative pressure corresponding to the displacement of the multiple fume hood 11, An air supply control unit 50 for controlling the air supply amount; And a control unit.

In order to maintain the pressure difference corresponding to the predetermined intake air speed of the fume hood 11 because the intake air speed increases as the pressure difference between the inside and outside of the fume hood 11 increases, And whether or not the fume hood 11 is exhausted and the amount of exhaust is adjusted.

The fume hood exhaust unit 20 receives the measured values of the individual pressure sensor 21 and the individual damper 22 individually installed in the plurality of fume hoods 11 and the measured values And an individual control section (23) for controlling the individual damper (22) in comparison with the external pressure.

The fume hood exhaust unit 20, the external exhaust unit 40 and the air supply control unit 50 operate in conjunction with each other. When the exhaust amount is adjusted by one or more fume hood exhaust units 20, The amount of exhaust of the external exhaust unit 40 is controlled by interlocking with the control of the exhaust amount of the exhaust unit 20 and the exhaust amount of the external exhaust unit 40 is controlled by the air supply control unit 50, Is performed.

The fume hood 11 is connected to an external exhaust portion 40 operated in conjunction with the fume hood exhaust portion 20 when the respective fume hood exhaust portions 20 of the plurality of fume hoods 11 are operated simultaneously Is controlled so as to be always maintained at a predetermined intake air rate from a fume hood exhaust portion (20) having a relatively larger door opening / closing amount among simultaneously operated fume hood exhaust portions (20).

Also, the fume hood 11 is characterized in that the preset difference between the inside and the outside of the fume hood 11 is maintained at 0.315 Pa so that the preset intake speed of 0.50 m / s is maintained at all times.

Further, the individual pressure sensor 21 is installed at a position where the pressure in the fume hood 11 becomes an average in each of the fume hoods 11.

Hereinafter, the representative pressure difference measuring position and the energy saving system according to the preferred embodiment of the present invention will be described in detail with reference to FIG. 1 to FIG.

The energy saving system according to the present invention includes a fume hood exhaust unit 20, an external exhaust unit 40, and an air supply control unit 50.

The fume hood exhaust unit 20 is installed individually for each of the fume hoods 11 installed in a predetermined space such as a laboratory room 10. A plurality of fume hoods 11 in the present invention are arranged in a predetermined space 10 So that the multi-fume hood 11 is formed.

The fume hood exhaust unit 20 is installed in each of the multifume hoods 11 and comprises an individual pressure sensor 21, an individual damper 22, an individual control unit 23 and an individual speed sensor, Ensure that they are connected to each other.

That is, the individual pressure sensor 21 measures the pressure inside the fume hood 11, and the individual control unit 23 measures the pressure outside the fume hood 11 (a separate pressure measurement sensor for measuring the external pressure The individual dampers 22 installed in the fume hood 11 are controlled to compare the measured pressures measured and delivered by the individual pressure sensors 21 to the exhaust And the amount of exhaust. In the case of the individual pressure sensor 21, as shown in FIG. 3, in each of the fume hoods 11, there is no interference with opening and a position where the pressure overlaps, that is, Respectively.

As the pressure difference between the inside and outside of the fume hood 11 increases, the inspiratory rate measured by the individual speed sensor increases. Therefore, when the pressure difference between the door opening and closing amount of the fume hood 11 changes, The pressure difference between the inside and the outside of the fume hood 11 can be preset by adjusting the exhaustion amount and the exhaust amount of the fume hood 11 so as to maintain the pressure difference corresponding to the preset intake air speed of the fume hood 11. [ The pressure difference of 0.315 Pa (0 to 10.000 Pa) was maintained so that the preset intake air velocity of 0.50 m / s (0 to 10.00) m / s was maintained at all times.

In other words, in the present invention, when the door provided on the fume hood 11 is opened or closed, the pressure difference with the outside is kept constant, and the intake air velocity, which varies according to the opening / closing amount of the door, And controls the individual dampers 22 so as to maintain the preset intake air speed at all times, thereby controlling whether or not to exhaust the fume hood 11 and the amount of exhaust

In other words, irrespective of the door opening / closing amount of the fume hood 11, the inlet flow rate (wind speed) flowing into the fume hood 11 is constantly maintained constantly, .

When the fume hood 11 is operated so that the fume hood exhaust portions 20 of the plurality of fume hoods 11 are simultaneously operated to open or close the door, The external exhaust part 40 to be described later to be operated in cooperation is controlled so as to be maintained at a predetermined intake air rate from a fume hood exhaust part 20 having a relatively larger door closing amount among concurrently operated fume hood exhaust parts 20 So that the door opening / closing amount can be controlled in a larger order from the larger one

In one embodiment, the fume hood exhaust unit 20 having a relatively large door opening / closing amount among the plurality of fume hood exhaust units 20 is controlled in accordance with the control of the corresponding individual dampers 22, Air discharge is controlled and the remaining fume hood exhaust section 20 is controlled by an individual damper 22 installed in the fume hood exhaust section 20 or controlled by an external exhaust section 40) is also controlled by air discharge).

The external exhaust unit 40 is provided in a plurality of fume hoods 11 in which the fume hood exhaust units 20 described above are respectively installed so that the air exhausted to the individual dampers 22 of the fume hood 11 is discharged to the outside And includes a central static pressure sensor 41, a central control unit 42, and an exhaust unit 43, which are installed in the duct 30.

That is, since the air discharged from the fume hood exhaust unit 20 of each fume hood 11 is exhausted using only a single duct, the influence of the air exhausted to the outside through the individual dampers 22 is re- The external exhaust portion 40 is operated so as not to be received by the exhaust pipe 11,

When the exhaust amount is controlled so that the intake speed of the fume hood 11, in which the door opening and closing amount is changed, of each of the fume hoods 11 described above is kept constant through the fume hood exhaust portion 20, The central static pressure sensor 41 measures the static pressure inside the duct 30 so exhausted and when the static pressure in the duct 30 is lower than the preset static pressure in the duct 30, if the measured static pressure is higher than the preset static pressure in the duct 30, the speed of the exhaust device 43 connected to the duct 30 is reduced to reduce the exhaust amount will be.

Of course, the preset static pressure in the duct 30 is a preset static pressure when the multi-fume hood 11 keeps the intake speed constant regardless of the door opening / closing amount.

The air supply control unit 50 operates in cooperation with the fume hood exhaust unit 20 and the external exhaust unit 40 as described above so that when the air is exhausted to the outside through the external exhaust unit 40 , So that the air in the laboratory is introduced into the fume hood 11, so that the air in the laboratory is also used to supply air.

When the amount of exhaust gas from the fume hood exhaust unit 20 is controlled, the flow rate of the exhaust gas discharged from the fume hood exhaust unit 20 is adjusted according to the opening / closing amount of the door. And the external exhaust portion 40 for discharging the air also corresponds to the fume hood exhaust portion 20 so that the external exhaust amount of the air should be controlled.

The supply controller 50 includes a differential pressure sensor 51 and an air supply controller 52. The differential pressure detector 51 measures a differential pressure in the laboratory and then compares the measured differential pressure with a predetermined preset differential pressure in the laboratory, The air supply control unit 52 controls the air supply unit (ex: blower or the like) 53 so as to adjust the air supply amount so that the pre-set sound pressure is maintained in the interior of the laboratory corresponding to the exhaust amount of the hood 11.

In addition, the air supply unit 53 of the air supply control unit 50, the air exhaust unit 43 of the external exhaust unit 40, and the damper unit of the fume hood exhaust unit 20 operate in a proportional manner However,

The individual damper 22 is gradually opened and closed according to the amount of opening and closing of the fume hood 11 so that the exhaust device 43 of the external exhaust unit 40 can be opened and closed according to the operation state of the individual damper 22, The static pressure is changed and the changed static pressure is increased or decreased in accordance with the static pressure measured by the central static pressure sensor 41 (the measured static pressure is compared with the preset static pressure and adjusted accordingly) The device 53 also compares the measured differential pressure with a preset setting, and the speed is gradually increased or decreased in accordance with the preset differential pressure so that the automatic operation is performed so that the predetermined space 10 becomes the preset sound pressure state.

In addition, in the present invention, a multi-fume hood is used as a single duct in the embodiment of the present invention. However, even in the case of providing a single blower with a fume hood, a differential pressure sensor may be installed to control the exhaust blower by measuring the exhaust air speed.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. It is to be understood that various changes and modifications may be made without departing from the scope of the appended claims.

10: a predetermined space 11: a fume hood
20: Fume hood exhaust part 21: Individual pressure sensor
22; Individual damper 23: Individual control unit
30: Duct 40: Integrated exhaust part
41: central static pressure sensor 42: central control unit
43: Exhaust device 50:
51: differential pressure sensor 52:
53: Supply device

Claims (7)

A fume hood (11) having a plurality of doors installed in a predetermined space (10);
It is possible to determine whether or not the fume hood 11 is exhausted and the displacement of the fume hood 11 to the individual dampers 22 so that the intake air speed entering the interior of the fume hood 11 is always maintained at the preset intake air speed irrespective of the door opening / closing amount of the fume hood 11. [ A fume hood exhaust unit 20 for controlling the fume hood exhaust gas temperature;
The external exhaust unit 40 is provided in the single duct 30 connected to the multi-fume hood exhaust unit 20 and corresponds to the fume hood 11 in which the door opening and closing amount is changed, ;
The measured differential pressure in the predetermined space 10 is compared with the preset differential pressure so that the predetermined space 10 is constantly set to the predetermined negative pressure corresponding to the displacement of the multiple fume hood 11, And an air supply control unit (50) for controlling the air supply amount,
Since the fume hood 11 has an increased intake air velocity as the pressure difference between the inside and outside of the fume hood 11 increases, the fume hood 11 is controlled to maintain a pressure difference corresponding to the preset intake air velocity of the fume hood 11, 11 and the exhaust amount are controlled,
The fume hood exhaust unit 20 receives the measured values of the individual pressure sensor 21 and the individual dampers 22 individually installed in the plurality of fume hoods 11 and measures the measured external pressure And an individual control unit 23 for controlling the individual damper 22 in comparison with the individual control unit 23,
The fume hood exhaust unit 20, the external exhaust unit 40 and the air supply control unit 50 operate in conjunction with each other. When the exhaust amount is adjusted in one or more fume hood exhaust units 20, The amount of exhaust of the external exhaust unit 40 is controlled by interlocking with the control of the exhaust amount of the external exhaust unit 20 and the supply of air is performed in the predetermined space 10 by the air supply control unit 50 in conjunction with the exhaust amount adjustment of the external exhaust unit 40 Respectively,
The fume hood 11 is configured such that when the fume hood exhaust portions 20 of the plurality of fume hoods 11 are simultaneously operated, the external exhaust portion 40 operated in cooperation with the fume hood exhaust portion 20 The fume hood exhaust unit 20 is controlled to be maintained at a predetermined intake air rate from a fume hood exhaust unit 20 having a relatively larger door opening / closing amount among the simultaneously operated fume hood exhaust units 20,
The individual pressure sensor 21 is installed in each fume hood 11 at a position where there is no interference with the opening and an average pressure in the fume hood,
The external exhaust part 40 is composed of a central static pressure sensor 41, a central control part 42 and an exhaust device 43. Of the respective fume hoods 11, the fume hood 11, The static pressure inside the exhaust duct 30 to be exhausted is measured by the central static pressure sensor 41 provided in the duct 30 to control the flow rate of the exhaust gas discharged from the duct 30 The central control unit 42 increases the speed of the exhaust unit 43 connected to the duct 30 to increase the exhaust amount and if the measured static pressure is higher than the preset static pressure in the duct 30, The speed of the exhaust device 43 connected to the engine 30 is reduced to reduce the amount of exhaust,
The air supply control unit 50 includes a differential pressure sensor 51 and an air supply control unit 52. The air supply control unit 50 measures a differential pressure within the predetermined space 10 and then transmits the measured differential pressure to a preset differential pressure The air supply control unit 52 controls the air supply unit 53 so that the predetermined sound pressure is maintained in the predetermined space 10 in correspondence with the amount of exhaustion of the multiple fume hood 11, Which is controlled by the air speed of the multi-fume hood.
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