WO2015178736A1 - Server room ventilation system - Google Patents

Abstract

A server room ventilation system according to the present invention comprises: a cooling unit for drawing in air from the server room space and inducing heat transfer; a duct connected to the cooling unit and disposed on the floor of the server room space; and forced-air units connected to the duct for supplying the cooled air from heat transfer in the cooling unit to the interior of the server room, wherein the forced-air units are disposed facing each other so that a pair of rotating means rotating in the opposite directions induce the cooled air to be drawn into the space between the rotating means, thereby enhancing the speed and amount of forced air due to the rotational power of the rotating means, while simultaneously switching the blast direction of the cooled air to supply same to the interior of the server room space.

Description

Server room air conditioning system

The present invention relates to a server room air conditioning system, and more particularly, to a server room air conditioning system for supplying cooling air with improved wind speed and air volume to a server room indoor space.

In general, the cool air supplied from the air conditioner to cool the server rack disposed inside the computer room through the floor of the computer room interior space while the heat generated from the server rack is formed in the structure to discharge to the outside by forming an exhaust vent in the upper portion have.

That is, as shown in Figure 1, the server rack or panel board 12 is arranged on the wall of the computer room, from which the plurality of computer equipment 14 is arranged in the computer room indoor space in line with the row.

The power cable is supplied to each computer equipment from the distribution panel on the side of the wall.In the thermo-hygrostat 10, the cooling air is blown into the space below the raised floor 16 installed on the floor of the computer room. It is led to the upper side through the cooling air passage hole formed in the floor to cool the computer equipment.

However, the conventional computer room power supply structure for efficient energy management operation flows cooling air having air volume and wind speed generated through the air conditioner through the duct installed in the floor space. The duct communicates with the floor vent installed at the bottom of the indoor space and partially exits to the indoor space with low air pressure while air flows through the duct.

This has a problem in that the air discharge efficiency toward the indoor space is inferior.

In addition, since a separate means for guiding the flow direction of the cooling air flowing through the duct is not provided to the internal space of the computer room, there is a problem of decreasing the cooling efficiency of the computer room interior space.

Through the above problems, as shown in Figure 2, a plurality of server racks are arranged at equal intervals inside the computer room. Here, the blue color indicates a low temperature and the red color indicates a high temperature, and it can be seen that the temperature distribution inside the computer room is unevenly formed.

However, the energy management system described above shows excellent efficiency in the cooling of the server rack where cold air discharged from the air conditioner directly affects it, but where the cold air does not reach the point of passing from green to green. The central part, which appears as a red series, has a high cooling temperature due to the high ambient temperature along with the heat from other server racks placed around the server rack before it is cooled.

Also, even in a computer room where multiple server racks are arranged, if the usage is concentrated on a specific server or if a specific server where the usage is concentrated occurs frequently in an unspecified area, the server rack in an area outside the air-cooling area of the air conditioner has a low cooling efficiency. It can not be denied that the overall power consumption increases significantly.

An object of the present invention is to improve the cooling efficiency by allowing the cooling air provided through the cooler to be supplied to the server room interior space with increased air volume and wind speed.

Another object of the present invention is to circulate the air in the server room interior space to which the cold air is supplied to maintain the overall cooling temperature distribution of the indoor space evenly.

Still another object of the present invention is to sense the temperature of the server room interior space and to individually control the cooling unit and the circulation unit to match the setting temperature.

Server room air conditioning system of the present invention for achieving the above object is a cooler for introducing heat exchange in the air in the server room indoor space, a duct connected to the cooler and installed on the floor of the server room indoor space, and connected to the duct And a blower for supplying heat-exchanged cooling air of the cooler to the inside of the server room, wherein the blowers are installed to face each other, and the cooling air is introduced into the space between the rotating means by driving a pair of rotating means that are reversely rotated. The rotational force of the rotating means improves the wind speed and the air volume, and at the same time, changes the blowing direction of the cooling air to supply cooling air to the server room interior space.

According to the present invention, the server room further includes a circulation unit on the floor of the indoor space, wherein the circulation unit circulates air in the indoor space without being connected to the duct.

According to the present invention, the air flow exchange unit is further included in the upper part of the server room indoor space to provide a hot rising air in the indoor space to the cooler.

According to the invention, the rotating means is connected to the motor is equipped with a plurality of blades on the outer periphery of the shaft having a length to rotate.

According to the present invention, the server room further comprises a sensing means in the indoor space, wherein the sensing means measures the temperature of the indoor space, the controller receiving the temperature value of the sensing means is set according to the temperature of the set indoor space Drive the blower.

According to the present invention, the blower is connected to the floor duct of the server room indoor space is formed in the connection hole and the discharge hole for discharging the air in the upper portion, a pair of the reverse rotation mutually disposed to face each other in the inner space of the case When the guide means is provided with a pair of guide means having a curved shape and disposed close to the rotating means to guide the flow to the discharge hole by introducing the cooling air provided from the duct to the rotating means; Increasing the wind speed of the cooling air by the rotating means attracts air on the inlet space side formed between the pair of guide means, and configures it to be discharged to the discharge hole at an increased air volume.

According to the present invention, the circulation unit is installed on the floor of the indoor space in which the server is installed, the outlet and the inlet formed in the upper, respectively, a pair of rotating means disposed opposite to each other in the inner space of the case and the reverse rotation, the rotation A pair of guide means having a curved shape arranged in close proximity to the means is provided so that indoor air is introduced into the case through the inlet by the rotating means to guide the air flow to the outlet side through the guide means. By increasing the wind speed of the cooling air to draw the air in the inlet space side formed between the pair of guide means to be configured to discharge to the outlet side with the increased air flow.

According to the present invention, the server room further comprises a sensing means in the indoor space, the sensing means measures the temperature of the indoor space, the control unit is applied to the temperature value of the sensing means the circulation according to the temperature of the set indoor space To drive wealth.

According to the present invention, the blower is provided with a partition wall extending vertically into the inner space at the end of the discharge hole of the case to extend the length of the discharge hole, the guide means so that one side of the curved curvature is directed to the inner periphery of the lower discharge hole And the other side is disposed to face the connection hole.

According to the present invention, the circulation part is formed on the boundary between the outlet and the inlet of the case to separate the outlet and the inlet, respectively, the partition to extend vertically into the inner space of the case, the guide means is a curved curvature One side of the outlet is arranged to face the inner periphery and the other side of the inlet in the horizontal direction.

Server room air conditioning system of the present invention according to an embodiment of the present invention is a cooler for introducing heat exchange in the air in the server room indoor space, a duct connected to the cooler and installed on the floor of the server room indoor space, and connected to the duct And a blower for supplying heat-exchanged cooling air of the cooler to the inside of the server room, wherein the blowers are installed to face each other, and the cooling air is introduced into the space between the rotating means by driving a pair of rotating means that are reversely rotated. To improve the cooling efficiency of the server room through the cooling air that increases the wind speed and the air volume by supplying cooling air to the indoor space of the server room by changing the direction of blowing of the cooling air by increasing the wind speed and the air volume by the rotational force of the rotating means. It is effective.

The server room air conditioning system of the present invention is installed on the floor of the indoor space without being connected to the duct and circulates the air in the server room indoor space to which cold air is supplied through a circulation unit circulating air in the indoor space, thereby cooling the server room indoor space as a whole. There is an effect to maintain the temperature distribution evenly.

The server room air conditioning system of the present invention is installed in the server room indoor space, the sensing means for measuring the temperature of the indoor space, the cooling to match the temperature of the indoor space set according to the temperature value of the detection means By controlling the unit and the circulation unit separately, there is an effect capable of efficient temperature control.

1 is a plan view showing the internal structure of the computer room according to the prior art.

2 is a temperature distribution diagram showing a temperature distribution of a computer room according to the prior art,

3 is a structural diagram showing a server room air conditioning system of the present invention.

4 is a cross-sectional view showing a blowing unit of the server room air conditioning system of the present invention.

5 is a cross-sectional view showing another embodiment of the air blowing unit of the server room air conditioning system of the present invention.

6 is a cross-sectional view showing a circulation portion of the server room air conditioning system of the present invention.

Figure 7 is a perspective view showing a rotation means of the server room air conditioning system of the present invention.

Explanation of symbols on the main parts of the drawings

10: air conditioning system 11: floor vent

12: server room 13: duct

14: server rack 100: blower

110 case 111 connector

112: discharge hole 113: internal space

120: rotation means 121: motor

122: axis 123: blade

130: guide means 131: inflow space

140: partition 200: circulation

210: case 211: exit

212 entrance 213 internal space

220: rotation means 221: motor

222: shaft 223: blade

230: guide means 231: inflow space

240: bulkhead 300: control unit

310: detection means 400: air flow exchange unit

500: cooler

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings. First, it should be noted that in the drawings, the same components or parts denote the same reference numerals as much as possible. In describing the present invention, detailed descriptions of related well-known functions or configurations are omitted in order not to obscure the subject matter of the present invention.

As used herein, the terms "about", "substantially", and the like, are used at, or in close proximity to, numerical values as are indicative of the manufacturing and material tolerances inherent in the meanings mentioned, Absolute figures are used to prevent unfair use by unscrupulous infringers.

Figure 3 is a structural diagram showing a server room air conditioning system of the present invention, Figure 4 is a cross-sectional view showing the air blowing unit of the server room air conditioning system of the present invention, Figure 5 is another embodiment of the air blowing unit of the server room air conditioning system of the present invention 6 is a cross-sectional view showing a circulation portion of the server room air conditioning system of the present invention, and FIG. 7 is a perspective view showing a rotation means of the server room air conditioning system of the present invention.

First, as shown in FIG. 3 to FIG. 7, the server room air conditioning system 10 of the present invention includes a cooler 500 for introducing heat from the air in the server room 12 indoor space, and connected to the cooler 500 to the floor of the server room indoor space. It is composed of a duct 13 is installed, and the blower 100 connected to the duct 13 to supply the heat exchanged cooling air of the cooler 500 into the server room.

As shown in FIG. 4, the blower 100 is connected to the duct 13 installed on the floor of the indoor space to supply the cooling air supplied through the duct 13 to the indoor space.

The blower 100 is installed to face each other and the cooling air is introduced into the space between the rotating means 120 by the driving of a pair of rotating means 120 to reverse the rotation speed and the air volume is improved by the rotational force of the rotating means 120 at the same time cooling The cooling air is supplied to the server room 12 indoor space by switching the direction of air blowing.

Here, the blower 100 is composed of a case 110, a rotating means 120 and a guide means 130.

That is, the case 110 has a connection hole 111 is formed so that both sides and the bottom duct 13 of the indoor space in which the server is installed, and the discharge hole 112 for discharging air is formed in the upper portion.

Here, the connection hole 111 may be formed on the lower surface of the case.

In addition, the rotation means 120 is disposed to face each other in the case 110 internal space 113 to reverse rotation to generate and increase the air volume and wind speed.

In addition, the guide means 130 is disposed in close proximity to the rotating means 120 has a curved shape is provided in a pair.

The blower 100 configured as described above increases the wind speed of the cooling air by the rotating means 120 when the guide means 130 introduces the cooling air provided from the duct 13 to the rotating means 120 to guide the flow to the discharge hole 112. The air drawn in the inlet space 131 side formed between the pair of guide means 130 is configured to be discharged to the discharge hole 112 with an increased air volume.

Here, the rotating means 120 is connected to the motor 121, a plurality of blades 123 is mounted on the outer periphery of the shaft 122 having a length to rotate.

In addition, the blower 100 is provided with a partition wall 140 extending vertically into the inner space 113 at the end 112 of the discharge hole 112 of the case 110 to extend the length of the discharge hole 112, the guide means 130 is one side of the curved curvature discharge hole 112 It is arranged to face the lower inner circumference and the other side toward the connecting hole 111 side.

This, the cooling air supplied through the duct 13 can naturally flow the cooling air flow to the server room 12 indoor space by the arrangement of the partition 140 and the guide means 130 as described above.

The function of the blower 100 configured as described above is as follows.

The blower 100 is connected to the duct 13 is installed at least one floor of the server room 12 indoor space.

The blower 100 receives the cooling air generated by the cooler 500 from the duct 13 and supplies the cooling air to the server room 12 indoor space.

Here, when the cooling air flows into the case 110 from the duct 13, the blower 100 is branched into two spaces and supplied.

That is, the cooling air is supplied to the rotating means 120 through the guide means 130 and the cooling air is supplied to the inflow space 131 between the pair of guide means 130.

At this time, the air pressure is increased by the mutual reverse rotation of the pair of rotating means 120 to increase the air pressure in the space between the pair of rotating means 120 to increase the wind speed.

That is, when the air pressure in the space between the pair of rotating means 120 and the guide means 130 is increased, the air pressure in the inflow space 131 outside the guide means 130 is lowered.

As a result, the force of the air acts from high pressure to low pressure, so the cooling air whose wind speed is increased through the pair of rotating means 120 attracts the air flow in the inflow space 131 to increase the air volume.

In other words, the blowing unit 100 switches the blowing direction of the cooling air supplied through the duct 13 to the server room 12 indoor space, and improves the wind speed and the air volume of the cooling air to improve the airflow and the air volume of the cooling air. The indoor space is provided to improve the cooling efficiency of the server room 12 indoor space.

In addition, as shown in Figure 5, the circulation unit 200 is installed on the floor of the server room 12 indoor space.

The circulation unit 200 is not connected to the duct 13 and circulates cooling air near the bottom of the indoor space.

That is, the hot heat of the server room 12 indoor space rises by convection, and the cold heat exists on the floor side of the indoor space.

At this time, the circulation unit 200 circulates cold cooling air in the bottom portion of the server room 12 indoor space and is discharged to the upper part of the server room 12 indoor space, so that the server room 12 indoor space has an evenly distributed cooling temperature distribution.

The circulation unit 200 includes a case 210, a rotation means 220, and a guide means 230.

The case 210 is installed on the floor of the indoor space of the server room 12, and an outlet 211 and an inlet 212 are formed at an upper portion thereof.

In addition, the rotating means 220 is provided in pairs and reversely rotates in a state in which the rotating means 220 is disposed to face the inner space 213 of the case 210.

In addition, the guide means 230 is provided in a pair has a curved shape disposed in close proximity of the rotating means 220.

The circulation unit 200 configured as described above has the air velocity of the cooling air by the rotating means 220 when the indoor air is introduced into the case 210 through the inlet 212 by the rotating means 220 to guide the air flow to the outlet 211 through the guide means 230. When increasing, the air drawn in the inlet space 231 side formed between the pair of guide means 230 is configured to be discharged to the outlet 211 side with the increased air volume.

Here, the rotating means 220 is mounted to a plurality of blades 223 on the outer periphery of the shaft 222 having a length that is connected to the motor 221 to rotate.

Particularly, the circulation part 200 is formed with a partition wall 240 formed at a boundary between the outlet 211 and the inlet 212 of the case 210 to distinguish the outlet 211 and the inlet 212, respectively, and the partition wall 240 extends vertically into the case 210 internal space 213. The guide means 230 is disposed so as to face the inner periphery of the lower exit 211 of the curved curvature and the other side to face the lower portion of the inlet 212 in the horizontal direction.

In this way, the inlet 212 and the outlet 211 are partitioned so that the air in the server room 12 indoor space flows in through the inlet 212 and flows easily through the rotating means 220 to the outlet 211.

The function of the circulation unit 200 configured as described above is as follows.

The circulation unit 200 is not connected to the duct 13 and is installed at least one floor of the server room 12 indoor space.

Here, when the pair of rotating means 220 is rotated in the case 210, air in the server room 12 is introduced into the internal space 213 through the inlet 212 of the case 210.

The air introduced through the inlet 212 is supplied to the rotating means 220 through the guide means 230 and is branched to the inflow space 231 between the pair of guide means 230.

At this time, the air supplied to the space between the rotating means 220 and the guide means 230 increases the air pressure by the reverse rotation of the pair of rotating means 220 increases the air pressure in the space between the rotating means 220 and the guide means 230 to increase the wind speed. .

When the air velocity increases in the air pressure in the space between the pair of rotating means 220 and the guide means 230, the air pressure in the inflow space 231 outside the guide means 230 is lowered.

As a result, the force of the air acts from high pressure to low pressure, so that the air having an increased wind speed through the pair of rotating means 220 draws airflow in the inlet space 231 to increase the amount of air.

In addition, the air of the increased wind speed and volume through the circulation unit 200 is discharged to the outlet 211 side to circulate the air in the server room 12 indoor space to maintain the overall cooling temperature distribution of the server room 12 indoor space evenly.

In addition, the airflow exchanger 400 is further included in the upper part of the server room 12 indoor space to provide the cooler 500 with a hot rising air in the indoor space.

That is, the circulation unit 200 has a function of circulating cold cooling air at the bottom side of the indoor space, and the airflow exchange unit 400 allows the hot rising air at the top of the ceiling side of the indoor space to flow from the indoor space to the cooler 500.

As a result, the cooling air heat exchanged through the cooler 500 is supplied to the indoor space of the server room 12 through the blower to exchange heat in the indoor space, and the circulation 200 circulates air at the bottom of the indoor space to have an even distribution of heat. In addition, the airflow exchanging unit 400 flows the hot air existing in the upper part of the indoor space to the cooler 500.

This circulates the cooling air in the indoor space.

In addition, a plurality of sensing means 310 is installed in the server room 12 indoor space.

The sensing means 310 is a means for measuring a temperature, and is provided in plural numbers and installed in various places inside the server room 12.

In addition, the sensing unit 310 applies the measured temperature value to the controller 300.

This allows the controller 300 to individually control the blower 100 and the circulator 200 according to the applied temperature value so as to match the temperature of the set indoor space, thereby enabling efficient temperature control.

As described above, the server rack 14 is arranged at regular intervals in the server room 12 indoor space, and the ventilation unit 100 connected to the duct 13 and the circulation unit 200 not connected to the duct 13 are alternately arranged on the floor space between the server racks 14. To supply cooling air to the space between the server racks 14 through the blower 100 and to circulate cold cooling air at the bottom of the space between the server racks 14 where the circulation unit 200 is installed to maintain the heat distribution of the indoor space evenly. do.

In addition, the hot rising air present in the upper portion of the indoor space is guided to the cooler 500 side through the air flow exchange unit 400 to exchange heat, thereby allowing the air in the indoor space of the server room 12 to circulate as it is heat exchanged.

The present invention described above is not limited to the above-described embodiment and the accompanying drawings, and various substitutions, modifications, and changes are possible within the scope without departing from the technical spirit of the present invention. It will be evident to those who have knowledge of.

Claims (10)

1. A cooler that heats and heats the air in the server room indoor space,

   A duct connected to the cooler and installed on a floor of a server room indoor space,

   Consists of a blower connected to the duct to supply the heat exchanged cooling air of the cooler into the server room,

   The blower is installed to face each other, the cooling air is introduced into the space between the rotating means by the driving of a pair of rotating means to reverse the rotation speed is improved by the rotational force of the rotating means and at the same time the blowing direction of the cooling air A server room air conditioning system, characterized in that for supplying cooling air to the server room indoor space by switching.
2. The method of claim 1,

   And a circulation unit on the floor of the server room indoor space, wherein the circulation unit circulates air in the indoor space without being connected to a duct.
3. The method of claim 1,

   A server room air conditioning system, further comprising: an airflow exchanger at an upper portion of the server room indoor space to provide a hot rising air in the indoor space to the cooler.
4. The method of claim 1,

   The rotating means is connected to the motor server room air conditioning system, characterized in that a plurality of blades are mounted on the outer periphery of the shaft having a length to rotate.
5. The method of claim 1,

   Further comprising a sensing means in the server room indoor space, the sensing means measures the temperature of the indoor space,

   The control unit receives the temperature value of the sensing means to drive the air blowing unit according to the temperature of the set indoor space, characterized in that the server room air conditioning system.
6. The method of claim 1,

   The blowing unit,

   A case in which a connection hole is formed so as to communicate with the floor duct of the server room indoor space, and a discharge hole for discharging air is formed in the upper part;

   A pair of rotating means disposed to face each other in the inner space of the case and reversely rotating;

   Providing a pair of guide means having a curved shape and disposed close to the rotation means

   When the guide means introduces the cooling air provided from the duct into the rotating means to guide the flow to the discharge hole, when the wind speed of the cooling air is increased by the rotating means, the air on the inlet space side formed between the pair of guide means A server room air conditioning system, characterized in that configured to be discharged to the discharge hole by the increased amount of air pulled.
7. The method of claim 2,

   The circulation portion,

   A case installed at the floor of the indoor space where the server is installed and having an outlet and an inlet formed thereon,

   A pair of rotating means disposed opposite to the inner space of the case to reverse rotation with each other;

   By providing a pair of guide means having a curved shape disposed in close proximity of the rotating means

   When the indoor air is introduced into the case through the inlet by the rotating means to guide the air flow through the guide means, when the wind speed of the cooling air is increased by the rotating means, the inflow space formed between the pair of guide means. A server room air conditioning system, characterized in that configured to draw air to the outlet side with increased air volume.
8. The method of claim 2,

   Further comprising a sensing means in the server room indoor space, the sensing means measures the temperature of the indoor space,

   The control unit receiving the temperature value of the sensing means to drive the circulation unit in accordance with the temperature of the set indoor space characterized in that the server room air conditioning system.
9. The method of claim 6,

   The blowing unit,

   At the end of the discharge hole of the case is provided a partition wall extending vertically to the inner space to extend the length of the discharge hole,

   The guide means is arranged so that one side of the curved curvature is facing the inner periphery of the discharge hole and the other side toward the connection hole side.
10. The method of claim 7, wherein

    The circulation portion,

    A partition wall is formed at the boundary between the outlet and the inlet of the case to distinguish the outlet from the inlet, respectively, so that the partition extends vertically into the space inside the case.

    The guide means is directed to the inner periphery of the lower outlet side of the curved curvature and the other side is arranged to face in the horizontal direction at the bottom of the inlet.

Images