KR102623578B1 - Automatic heat collection and emission control system - Google Patents

Abstract

The present invention relates to an automatic collection and emission control system, which includes a first exhaust fan and a second exhaust fan that discharge high temperature heat generated from communication equipment to the outside, a failure detection unit that detects a failure occurring in the first exhaust fan, and It is characterized by comprising a motion detection unit that detects the operating state of the first exhaust fan and an exhaust fan control unit that drives the second exhaust fan when the operation of the first exhaust fan is stopped.
In addition, a rack that accommodates communication equipment and includes one side through which high-temperature heat generated from the communication equipment is discharged, is installed in close contact with one side of the rack to prevent a gap, and collects high-temperature heat generated from the communication equipment. A heat collecting device, a heat transfer means including a first passage and a second passage for discharging the collected heat to the outside, a first exhaust fan installed in the first passage, and a second exhaust fan installed in the second passage. Including a fan, when the operation of the first exhaust fan is stopped due to failure, the second exhaust fan is driven.
Through the present invention, the operating time of the air conditioner can be significantly reduced by discharging hot air generated from communication equipment to the outside in a continuous and stable manner through the mutual operation of two exhaust fans, thereby reducing the time required for cooling. Costs can be reduced.

Description

Automatic collection and emission control system {AUTOMATIC HEAT COLLECTION AND EMISSION CONTROL SYSTEM}

The present invention relates to an automatic collection and discharge control system, and more specifically, to a system that automatically controls an exhaust fan to collect and discharge hot air generated from communication equipment.

Generally, communication equipment (network equipment, servers, communication exchangers, etc.) placed in a communication room is installed in a communication rack that can accommodate the communication equipment. Communication equipment that provides the above information and communication services includes a large number of electronic components and circuits and has high power consumption, so high-temperature air and heat are generated during operation.

In other words, during the operation process, high-temperature air and resulting waste heat are generated. This is to prevent performance degradation and breakdown of communication equipment and reduce the operation time of the air conditioner used inside the communication room. The process of stably discharging high-temperature and high-velocity air must be carried out smoothly.

Meanwhile, the exhaust fan, which is a component of the collection and exhaust system that discharges air and heat generated from communication equipment, frequently malfunctions and stops operating for reasons such as phase loss or overcurrent, failing to properly discharge the generated heat.

If the heat generated by a malfunction of the exhaust fan is not properly discharged, the temperature inside the rack may rise rapidly and the communication equipment may stop. If the equipment in question is major communication equipment such as a server, the damage can be serious. When the user turns on the power, the exhaust fan operates until the power is turned off. Generally, the above problem occurs because the user cannot quickly determine the error state of the exhaust fan.

Figure 1 shows the structure of a conventional collection and discharge system, where (a) is installed in the lower rack, (b) is in the upper rack, and (c) shows the collection device 2 installed in the entire rack. will be. As shown in FIG. 1, the conventional heat collection and discharge system is installed so that a predetermined space (3) through which heat can escape is formed without adhering the heat collection device (2), which primarily receives waste heat, to the rack (1). This allowed most of the discharged air to circulate indoors.

However, in this case, the heat collecting device was not completely adhered to the rack, reducing the effectiveness of heat collection, and cooling efficiency was reduced due to high-temperature air circulating indoors rather than being discharged to the outside. In addition, there was a problem that communication equipment was primarily exposed to high-temperature air, resulting in breakdowns, and this increased the likelihood of fires occurring secondarily.

This problem can fundamentally be said to arise from the inability to effectively control the exhaust fan that exhausts high-temperature air and heat generated from communication equipment.

The present invention is intended to solve the above problems. The purpose is to enable efficient and stable operation of collection and discharge facilities by automatically controlling alarms and switchovers of exhaust fans.

In order to solve the above technical problem, the automatic collection and emission control system according to the present invention detects a first exhaust fan and a second exhaust fan that discharge high temperature heat generated from communication equipment to the outside, and a failure occurring in the first exhaust fan. It is characterized in that it includes a fault detection unit that detects the operating state of the first exhaust fan, and an exhaust fan control unit that drives the second exhaust fan when the operation of the first exhaust fan is stopped. .

In addition, when the operation of the first exhaust fan is stopped, the exhaust fan control unit switches the first switch connected to the first exhaust fan to a second switch connected to the second exhaust fan to drive the second exhaust fan. Do it as

In addition, the failure detection unit is characterized in that it detects a failure by detecting a current flowing in the first exhaust fan.

In addition, after driving the second exhaust fan, the exhaust fan operation limiter restricts the return to the state in which the first exhaust fan is driven until the cause of the failure of the first exhaust fan is resolved.

In addition, when the cause of the failure of the first exhaust fan is resolved, the device further includes an exhaust fan reset unit that stops the operation of the second exhaust fan and drives the first exhaust fan again.

Additionally, it may further include a display unit that displays driving states of the first exhaust fan and the second exhaust fan.

On the other hand, the automatic collection and emission control system according to the present invention includes a rack that accommodates communication equipment and includes one side from which high-temperature heat generated from the communication equipment is discharged, and is installed in close contact with one side of the rack to prevent a gap from occurring, A collection device for collecting high-temperature heat generated from the communication equipment, a heat transfer means including a first passage and a second passage for discharging the collected heat to the outside, and a first exhaust fan installed in the first passage. and a second exhaust fan installed in the second passage, wherein when the operation of the first exhaust fan is stopped due to failure, the second exhaust fan is driven.

In addition, the collection device is characterized in that it collects 90 to 100% of the total high temperature heat generated from the communication equipment.

In addition, the collecting device is characterized in that it is formed of a transparent material.

In addition, the first passage and the second passage are characterized in that each passage is formed by dividing into two branches on the other side of the heat transfer means.

In addition, the failure is characterized in that any one of phase loss, overcurrent, and low current occurs in the first exhaust fan.

According to an embodiment of the present invention, the automatic collection and emission control system according to the present invention can solve operational problems caused by communication service failures and insufficient warning systems by automatically controlling the exhaust fan that discharges the collected heat.

In addition, by discharging hot air generated from communication equipment to the outside in a continuous and stable manner through the mutual operation of two exhaust fans, the operation time of the air conditioner can be significantly reduced, thereby reducing cooling costs. can do.

In addition, greenhouse gases generated by reducing the operating time of the air conditioner can be reduced, making it environmentally friendly.

However, the effects that can be achieved by the automatic collection and emission control system according to the embodiments of the present invention are not limited to those mentioned above, and other effects not mentioned are commonly known in the technical field to which the present invention belongs from the description below. It will be clearly understandable to those who have the knowledge of.

The accompanying drawings, which are included as part of the detailed description to aid understanding of the present invention, provide embodiments of the present invention, and together with the detailed description, explain the technical idea of the present invention.
Figure 1 shows a conventional collection and discharge system.
Figure 2 shows a block diagram of the automatic collection and discharge control system 1000 according to the present invention.
Figure 3 shows the display unit of the automatic collection and discharge control system 1000 according to the present invention.
Figure 4 schematically illustrates the structure of the automatic collection and discharge control system 1000 according to the present invention.
Figure 5 shows the combined state of the rack 10 and the collecting device 20 in the automatic collection and discharge control system 1000 according to the present invention.

The present invention can be modified in various ways and can have various embodiments. Hereinafter, specific embodiments will be described in detail based on the accompanying drawings.

The following examples are provided to provide a comprehensive understanding of the methods, devices and/or systems described herein. However, this is only an example and the present invention is not limited thereto.

In describing the embodiments of the present invention, if it is determined that a detailed description of the known technology related to the present invention may unnecessarily obscure the gist of the present invention, the detailed description will be omitted. In addition, the terms described below are terms defined in consideration of functions in the present invention, and may vary depending on the intention or custom of the user or operator. Therefore, the definition should be made based on the contents throughout this specification. The terminology used in the detailed description is only for describing embodiments of the present invention and should in no way be limiting. Unless explicitly stated otherwise, singular forms include plural meanings. In this description, expressions such as “comprising” or “comprising” are intended to indicate certain features, numbers, steps, operations, elements, parts or combinations thereof, and one or more than those described. It should not be construed to exclude the existence or possibility of any other characteristic, number, step, operation, element, or part or combination thereof. In addition, terms such as first, second, etc. may be used to describe various components, but the components are not limited by the terms, and the terms are used for the purpose of distinguishing one component from another component. It is used only as Hereinafter, exemplary embodiments of the automatic collection and emission control system according to the present invention will be described in detail with reference to the attached drawings.

Figure 2 shows a block diagram of the automatic collection and discharge control system 1000 according to the present invention.

Referring to FIG. 2, the automatic collection and emission control system 1000 according to the present invention includes an exhaust fan 100 that exhausts high-temperature heat generated from communication equipment to the outside, and an exhaust fan 100 that controls the overall operation of the exhaust fan 100. It includes a control unit 200, a display unit 300 that displays the driving state and failure of the exhaust fan 100, and a power supply device 400 that supplies power.

The exhaust fan 100 includes a first exhaust fan 100A and a second exhaust fan 100B. In the present invention, the first exhaust fan 100A is an active fan (100A) that plays the main role of discharging the collected heat. It may be an active (or master) exhaust fan, and when the first exhaust fan 100A does not operate, the second exhaust fan 100B causes the automatic collection and emission control system 1000 to continuously collect and exhaust the exhaust fan. It may be a standby (or slave) exhaust fan that assists the first exhaust fan (100A).

The control unit 200 includes a failure detection unit 220 that detects a failure occurring in the first exhaust fan (100A), a motion detection unit 230 that detects the operating state of the first exhaust fan (100A), and the first exhaust fan (100A). When the operation of the exhaust fan (100A) is stopped, the exhaust fan control unit 210 drives the second exhaust fan (100B), and the failure detection unit 220 detects whether the first exhaust fan (100A) is broken. , a motion detection unit 230 that detects whether the first exhaust fan (100A) is operating, an exhaust fan drive limiter 240 that limits return from the second exhaust fan (100B) to the first exhaust fan (100A). , an exhaust fan reset unit 250 that switches the operation from the second exhaust fan (100B) to the first exhaust fan (100A), and an operation delay setting unit 260 that delays the operation of the exhaust fan 100 for a certain period of time. Includes.

The display unit 300 displays the operating status and failure of the exhaust fan 100, and the power supply device 400 provides power to drive the exhaust fan 100, the control unit 200, and the display unit 300. supply.

Hereinafter, the control unit 200 according to the present invention will be described in detail.

The exhaust fan control unit 210 according to the present invention mutually controls the first exhaust fan 100A and the second exhaust fan 100B to continuously collect heat and exhaust. The exhaust fan control unit 200 is connected to a fault detection unit 220, a motion detection unit 230, an exhaust fan operation limiter 240, an exhaust fan reset unit 250, and an operation delay setting unit 260 to exhaust the exhaust fan. It plays a role in controlling the overall operation of the fans (100A, 100B).

The automatic collection and discharge control system 1000 according to the present invention includes a first switch 110A that controls the operation of the first exhaust fan 100A and a second switch (110A) that controls the operation of the second exhaust fan 100B. 110B), where the exhaust fan control unit 210 drives the second exhaust fan 100B when the operation of the first exhaust fan 100A is stopped. Specifically, when the operation of the first exhaust fan 100A is stopped, the exhaust fan control unit 210 switches the first switch 110A connected to the first exhaust fan 100A to the second exhaust fan 100B. The second exhaust fan 110B can be driven by switching to the connected second switch 110B. Here, the first switch 110A and the second switch 110B may be, for example, magnetic switches (Magnetic Contactors, MC) used in the control of an electric motor circuit.

That is, in normal circumstances, the first exhaust fan (100A) is driven to discharge heat collected from the communication equipment to the outside, and when a failure is detected in the first exhaust fan (100A) and the operation is stopped due to this, the second exhaust fan (100A) is operated. The fan (100B) is driven to continuously discharge the collected heat.

The first exhaust fan (100A) and the second exhaust fan (100B) of the automatic collection and exhaust control system 1000 according to the present invention are connected in such a way that when one fan is driven, the other fan is not driven, so that the situation By changing the fan driven in real time, collection and discharge can be performed continuously.

The failure detection unit 220 according to the present invention detects a failure of the first exhaust fan 100A. Specifically, the failure detection unit 220 detects a failure by detecting the current flowing in the first exhaust fan 100A. The cause of the failure may be any one of phase loss, overcurrent, and low current occurring in the first exhaust fan.

Phase loss refers to the loss of power in some of the three wires on the power side due to any cause, such as a defective transformer or disconnection, during normal operation. In other words, three-phase (R-phase, S-phase, T-phase) current usually flows in the exhaust fan 100. If one or two of the three phases are cut off for some reason and the current does not flow, the current is concentrated in the remaining two or one phase. It means becoming. If phase loss occurs, it will cause damage to the exhaust fan 100 that uses three phases as a power source.

Overcurrent refers to a sudden and instantaneous increase in current, that is, an abnormal current flowing beyond the allowable limit, and undercurrent refers to a state that flows less than a certain limit. This cause may also cause damage to the exhaust fan 100.

The automatic collection and discharge system 1000 according to the present invention includes a phase display instrument (Phase) connected to the first exhaust fan (100A) to detect phase loss, overcurrent, and low current of the first exhaust fan (100A). In case of phase loss, including Meter (PH) and Current Transformer (CT), it is possible to identify which phase the phase loss occurred.

The motion detection unit 230 according to the present invention detects the operating state of the first exhaust fan 100A. If a malfunction occurs in the first exhaust fan 100A and the exhaust fan does not operate, the motion detection unit 230 may request the exhaust fan control unit 210 to drive the second exhaust fan 100B. As mentioned earlier, the first exhaust fan (100A) and the second exhaust fan (100B) are connected in such a way that when one fan is driven, the other fan is not driven, and the motion detection unit 230 When the first exhaust fan 100A is stopped, the second exhaust fan 100B can be automatically driven. Meanwhile, the motion detection unit 230 can implement an alarm function when the operation of the first exhaust fan 100 is stopped so that the manager can quickly determine this.

The exhaust fan operation limiter 240 according to the present invention performs a so-called latch function, in which a failure in the first exhaust fan 100A is detected and the operation is stopped, and the second exhaust fan 100B is driven. In this case, it serves to limit the return to the operating state of the first exhaust fan (100A) until the cause of the failure of the first exhaust fan (100A) is resolved. In other words, this prevents automatic recovery from the second exhaust fan (100B) to the first exhaust fan (100A).

For example, the cause of the failure of the first exhaust fan (100A) has not been completely resolved, but after operating the second exhaust fan (100B), it is determined that a normal current is detected in the first exhaust fan (100A), and the second exhaust fan (100B) is restarted. ), when the first exhaust fan (100A) returns to operation, the operation may stop again due to the cause of a previously occurring failure, and this operation is repeated, eventually causing the first exhaust fan (100A) and the second exhaust fan (100A) to operate. A situation may occur in which the exhaust fan 100B operates unstable and alternately.

The exhaust fan drive limiter 240 restricts the return from the second exhaust fan (100B) to the first exhaust fan (100A) until the cause of the malfunction in the first exhaust fan (100A) is resolved, thereby creating a collection and exhaust system. stability can be improved. The cause of the failure can be resolved by a remote person detecting an abnormality in the first exhaust fan (100A) and replacing the exhaust fan.

The exhaust fan reset unit 250 according to the present invention operates after the first exhaust fan (100A) is stopped and the second exhaust fan (100B) is driven, and the cause of the failure of the first exhaust fan is resolved, the second exhaust fan is restarted. (100B) performs a function of returning the first exhaust fan (100A) to operation. That is, the operation of the second exhaust fan (100B) is stopped, and the first exhaust fan (100A) is driven again. This can be performed by switching the second switch 110B connected to the second exhaust fan 100B to the first switch 110A connected to the first exhaust fan 100A.

The operation delay setting unit 260 according to the present invention adjusts the characteristics (e.g., horsepower (HP)) of each exhaust fan 100 to prevent an overcurrent exceeding the allowable current from continuously flowing in the exhaust fan 100. It plays a role in setting the operating current and operating delay time.

For example, if the exhaust fan 100 can withstand a current of about 10 times the allowable current, the current at which the exhaust fan 100 operates and the time to delay the operation (for example, 5 to 10 sec) By appropriately setting the etc., the characteristics of each exhaust fan can be taken into consideration. As an example, this can be easily implemented by applying a jig setting technique for constructing a separate substrate.

Meanwhile, the display unit 300 according to the present invention displays the driving state and malfunction of the exhaust fan 100, which will be described below with reference to FIG. 3.

Figure 3 shows the display unit 300 of the automatic collection and discharge control system 1000 according to the present invention.

The display unit 300 is connected to the control unit 200 and displays the operating status and malfunction of the exhaust fan 100. This can be implemented so that the manager can easily understand it through the lighting of the LED. Additionally, a separate switch (not shown) that drives the exhaust fan 100 can be implemented in the display unit 300 to quickly control the system in an emergency.

Meanwhile, the automatic collection and discharge control system 1000 according to the present invention has been described as a system applied to one space (e.g., one floor) for convenience of explanation, but this is a system applied to a plurality of spaces (e.g. For example, it can be implemented integratedly by implementing each layer (two or more layers). Therefore, of course, the display unit 300 can also be implemented to display a plurality of exhaust fans so that the driving status and failure of each exhaust fan 100 implemented in a plurality of spaces can be known.

Figure 4 schematically illustrates the structure of the automatic collection and discharge control system 1000 according to the present invention.

As mentioned earlier, the conventional heat collection and discharge system had no choice but to install the heat collection device in such a way that a predetermined space was formed through which heat could escape without being closely attached to the rack. This was to alleviate damage caused by high temperatures by circulating most of the heat generated (more than 70%) indoors to prevent problems such as damage to communication equipment and further fires caused by continued failure of the exhaust fan. . However, there was a problem that this lowered the cooling efficiency of the communication room and still caused equipment failure.

The automatic collection and discharge control system according to the present invention, previously described with reference to FIGS. 2 and 3, can solve this problem and ensure that collection and discharge are performed stably and completely even in a structure in which a rack and a collection device are installed in close contact. Hereinafter, the structure of the automatic collection and emission control system according to the present invention will be described in detail with reference to FIG. 4.

Referring to FIG. 4, the automatic collection and emission control system according to the present invention includes a rack 10 that accommodates communication equipment and includes one side through which high-temperature heat generated from the communication equipment is discharged, one side of the rack 10, and A collection device 20 that is installed in close contact to prevent a gap from occurring and collects high-temperature heat generated from the communication equipment, a first passage 30A and a second passage (30A) for discharging the collected heat to the outside ( 30B), including a first exhaust fan (100A) installed in the first passage (30A) and a second exhaust fan (100B) installed in the second passage (30B), When the operation of the first exhaust fan (100A) is stopped due to a failure, the second exhaust fan (100B) is driven.

The rack 10 is a type of cabinet that accommodates various communication equipment in a uniform stack, and a plurality of racks 10 may be provided in a communication room. The rack 10 is provided on one side to discharge high-temperature heat (waste heat) generated from communication equipment. In general, one side may be formed toward the rear of the communication equipment where heat is generated.

One side of the rack 10, where high-temperature heat generated from the communication equipment is discharged, is installed in close contact with the heat collection device 20. That is, the heat collecting device 20 is installed in close contact with one side of the rack 10 to prevent a gap from occurring. When installed in this way, the collection device can collect most (about 90 to 100%) of the high temperature heat generated from the communication equipment. If the sealing rate (ratio of tightly blocking or closing without leakage) without a collecting device is 0%, the collection and discharge system according to the present invention has a sealing rate of 90 to 100%. It can be seen that this is a fairly high figure, given that the sealing rate of the conventional collection and discharge system is less than 30%. Meanwhile, the collecting device 20 may be made of a transparent material to easily observe the status of a plurality of communication devices.

The collection device 20 collects high-temperature heat generated from communication equipment and then transfers it to the exhaust fans 100A and 100B through the heat transfer means 30. As an example, the heat transfer means 30 may be a duct with a corrugated structure. The heat transfer means 30 may have a first passage 30A in which the first exhaust fan 100A is installed and a second passage 30B in which the second exhaust fan 100B is installed. In the present invention, the first passage 30A and the second passage 30B are shown as each passage divided into two branches at the end of the heat transfer means 30, but the first exhaust fan 100A and the second exhaust fan ( 100B) can be of any shape as long as a passage (or space) can be accommodated therein.

The driving and control processes of the first exhaust fan 100A and the second exhaust fan 100B are the same as those previously described with reference to FIGS. 2 and 3.

Figure 5 shows the combined state of the rack 10 and the collecting device 20 in the automatic collection and discharge control system 1000 according to the present invention.

The collection and emission control system according to the present invention has a structure in which the rack (10) and the collection device (20) are in close contact to collect and discharge the waste. In Figure 5, (a) shows the lower rack, (b) the upper rack, and (c) the entire rack, each showing a form in which the heat collecting device 20 is installed in close contact with the rack 10 so that no gap is formed. will be. Through this structure, the automatic collection and emission control system according to the present invention can collect most of the high-temperature heat generated from communication equipment and discharge it to the outside.

The above description is merely an illustrative explanation of the technical idea of the present invention, and various modifications and variations will be possible to those skilled in the art without departing from the essential characteristics of the present invention. Accordingly, the embodiments described in the present invention are for illustrative purposes rather than limiting the technical idea of the present invention, and are not limited to these embodiments. The scope of protection of the present invention shall be interpreted in accordance with the claims below, and all technical ideas within the scope equivalent thereto shall be construed as being included in the scope of rights of the present invention.

1000: Collection and discharge automatic control system
100: exhaust fan
100A: 1st exhaust fan 100B: 2nd exhaust fan
110A: first switch 110B: second switch
200: control unit
210: exhaust fan control unit
220: Failure detection unit
230: motion detection unit
240: Exhaust fan drive limiter
250: Exhaust fan reset unit
260: Operation delay setting unit
300: Display unit
400: power supply
10: rack
20: collecting device
30: heat transfer means
30A: first passage 30B: second passage

Claims (14)

delete delete delete delete delete delete A rack that accommodates communication equipment and includes one side through which high-temperature heat generated from the communication equipment is discharged;
a collection device that is installed in close contact with one side of the rack to prevent a gap from occurring and collects high-temperature heat generated from the communication equipment;
Heat transfer means including a first passage and a second passage for discharging the collected heat to the outside;
a first exhaust fan installed in the first passage; and
a second exhaust fan installed in the second passage;
Including, when the operation of the first exhaust fan is stopped due to a failure, the second exhaust fan is driven.
In clause 7,
The automatic collection and discharge control system is characterized in that the collection device collects 90 to 100% of the total high temperature heat generated from the communication equipment.
In clause 7,
An automatic heat collection and discharge control system, characterized in that the collection device is formed of a transparent material.
In clause 7,
The first passage and the second passage are passages formed by dividing into two branches on the other side of the heat transfer means.
In clause 7,
The automatic collection and emission control system is characterized in that the failure occurs when any one of phase loss, overcurrent, and low current occurs in the first exhaust fan.
In clause 7,
An automatic collection and emission control system, characterized in that after driving the second exhaust fan, returning to the state in which the first exhaust fan is driven is restricted until the cause of the failure of the first exhaust fan is resolved.
In clause 7,
When the cause of the failure of the first exhaust fan is resolved, the operation of the second exhaust fan is stopped and the first exhaust fan is started again.
In clause 7,
An automatic collection and discharge control system further comprising a display device that displays driving states of the first exhaust fan and the second exhaust fan.

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