KR102119098B1 - Cooling System for Elevator Shaft and Method Thereof - Google Patents

Abstract

An elevator shaft cooling system according to an aspect of the present invention includes an elevator, a shaft in which the elevator moves up and down, an air conditioner for adjusting the temperature of the inside of the elevator and the shaft, and measuring the temperature and humidity of the elevator and the shaft. It may include a control device for operating the air conditioning device.

Description

Cooling System for Elevator Shaft and Method Thereof

The present invention relates to an elevator shaft cooling system and method, and more particularly, to an elevator shaft cooling system and method capable of reducing a fluctuation effect by reducing a temperature difference between an elevator and a shaft in summer and winter.

High-rise buildings are gradually increasing due to the development of building technology and the urbanization of the population, and elevators are generally installed inside the high-rise buildings as vertical moving means.

In this case, the elevator shaft, which is the vertical movement path of the elevator, is an empty space formed vertically similar to a chimney. As a result, the temperature difference between the inside and outside of the building creates a rising air flow inside the elevator shaft, resulting in a stack effect. .

In other words, the elevator shaft is an empty space formed vertically like a chimney, and the air inside the elevator shaft is maintained at room temperature, and a difference from the temperature of the outside air occurs.

Therefore, as the hot air balloon rises by the hot air, the air inside the elevator shaft generates an upward flow of air, and as a result, the air pressure in the lower layer of the elevator shaft decreases.

As such, when the air pressure in the lower floor of the elevator shaft is lowered, air in the elevator hall (meaning a corridor of a building equipped with an elevator door) is sucked into the elevator shaft.

As such, when the air in the room is sucked from the elevator hall into the interior of the elevator shaft, the air pressure in the room becomes lower than the air pressure in the outside of the building, causing infiltration that infiltrates the outside air from the building into the building. The outside air that has been introduced is heated by a heating device and then sucked back into the elevator shaft.

Due to the above-described flue effect, the upper portion of the elevator shaft has a high pressure due to the rising air, and unlike the lower layer portion, air is sucked from the elevator shaft toward the elevator hole.

As such, when air enters the elevator hall, the air in the room also increases in pressure, causing exfiltration of the air in the room to the outside of the building.

All of these flue effects, which are repeated inundation in the lower part of the building and leakage in the upper part of the building, can occur in the building, especially in high-rise buildings in winter when the temperature difference between indoor and outdoor is severe.

Such a chimney effect causes various problems as follows, and the countermeasure is necessary.

First, there is a problem in that excessive energy loss occurs due to the continuous circulation between the indoor air and the outside air as the inundation and leakage are repeatedly generated.

Second, there is a problem that causes unpleasant discomfort to the occupants as the unwanted outside air is strongly introduced.

Third, in the process of closing the elevator sliding door in the low-rise part of the high-rise building, high-speed air flows into the elevator shaft through the elevator sliding door.

Fourth, there is a problem in that a high-frequency noise is generated according to the invasion and leakage, thereby hindering the residential environment.

Fifth, there is a problem in that various odors and other contaminants are diffused inside the building by riding the upward airflow inside the elevator shaft generated according to the effect of the stack.

Sixth, it is difficult to control the indoor temperature/humidity of each floor.

Seventh, there is a problem that the ride comfort of the elevator is reduced.

In order to solve this problem, it is not possible to prevent airflow in the elevator shaft, which is the root cause of the infiltration of the lower floor and the leakage of the upper floor, and install a windshield to prevent outside air from entering the room and separate the elevator hall. Although the construction work has been carried out, such as compartments, the effect of blocking the inflow of outside air is limited, and the revolving door is being constructed to reduce the inflow of outside air by opening and closing of the doorway, but the effect of the revolving door is also limited, the construction cost is high, and the use is high. It is inconvenient and has problems of various safety accidents.

The present invention has been devised to solve the above problems, and an object of the present invention is to control an elevator shaft cooling system that can reduce a stack effect by controlling a temperature difference between an elevator and a shaft in summer and winter by operating a blocking device. And to provide a method.

An elevator shaft cooling system according to an aspect of the present invention for achieving the above object is an elevator, a shaft in which the elevator moves up and down, an air conditioner for controlling the temperature inside the elevator and the shaft, and the elevator. It may include a control device for operating the air conditioning device by measuring the temperature and humidity of the shaft.

The air conditioner is provided on an upper portion of the elevator to provide air-conditioned air to the inside of the elevator, a duct protruding from the air conditioner and circulating the temperature-controlled air as it penetrates the elevator, and the air conditioner It may be provided at the top to be provided with an air conditioner for controlling the temperature of the shaft with the air of the elevator.

The duct protrudes from the air conditioner, and a supply duct formed by bending to supply temperature-controlled air into the elevator, and a discharge duct formed by bending the air discharged from inside the elevator into the air conditioner. , The supply duct and the discharge duct extends to the top from the bent position, the upper end is open to be provided with a circulation duct through which the air in and out of the shaft.

The duct may be provided at a position where the supply duct and the circulation duct are in contact, and may include a blocking device blocking air supplied and discharged from the elevator.

The air conditioner extends from the top of the air conditioner to the top, an outlet pipe having a first damper at the top, an extension pipe extending to one side from the outlet pipe, and having a second damper at a position in contact with the outlet pipe, and A supply pipe for purifying the air supplied from the extension pipe and supplying it to the elevator may be provided.

The air conditioner is provided in the exhaust pipe and an exhaust fan for raising the waste heat source generated in the air conditioner to the upper portion, and an air purifier provided in the supply pipe to purify the waste heat source supplied to the elevator by the exhaust fan It can be further provided.

The control device includes a measurement sensor provided in the elevator and in the shaft to measure temperature and humidity, and a temperature sensor provided in the duct and the air conditioning device in the measurement sensor to measure the temperature of air discharged from the air conditioner. can do.

In the summer, the first damper is opened in the summer, and the second damper is closed to discharge the waste heat source generated in the air conditioner to the shaft, and in the winter, the second damper is opened, and the first damper is Closed to purify the waste heat source generated in the air conditioner can be supplied to the interior of the elevator.

The control device circulates air from the air conditioner to the inside of the elevator by closing the circulation duct by operating the blocking device in the summer season, and by operating the blocking device in the winter season to open the circulation duct. Air can be circulated through the shaft.

In addition, an elevator shaft cooling method according to another aspect of the present invention for achieving the above object comprises: (a) measuring the temperature of the inside of the elevator and the shaft; (b) operating the blocking device of the duct according to the temperature of the shaft in the elevator interior temperature; (c) supplying cold air from the air conditioner; (d) supplying the waste heat source discharged from the air conditioner from the air conditioner to the inside of the elevator and the shaft.

In the step (b), in the summer, when the temperature inside the elevator is higher than the temperature of the shaft, the blocking device is operated to supply cold air into the elevator, and in the winter, when the temperature inside the elevator is lower than the temperature of the shaft. By operating the blocking device, cold air can be supplied to the shaft.

The duct protrudes from the air conditioner, and a supply duct formed by bending to supply temperature-controlled air into the elevator, and a discharge duct formed by bending the air discharged from inside the elevator into the air conditioner. , The supply duct and the discharge duct extends to the top from the bent position, the upper end is open to be provided with a circulation duct through which the air in and out of the shaft.

The air conditioner extends from the top of the air conditioner to the top, an outlet pipe having a first damper at the top, an extension pipe extending to one side from the outlet pipe, and having a second damper at a position in contact with the outlet pipe, and A supply pipe for purifying the air supplied from the extension pipe and supplying it to the elevator may be provided.

In the step (d), the summer season opens the first damper, the second damper is closed to discharge the waste heat source generated in the air conditioner to the shaft, the winter season the second damper is opened, and The first damper can be closed to purify the waste heat source generated in the air conditioner and supply it to the interior of the elevator.

According to the elevator shaft cooling system and method according to the present invention, cold air supplied from an air conditioner may be supplied to an elevator and a shaft in summer and winter, respectively, to prevent a chimney effect.

1 is a cross-sectional view showing an elevator shaft cooling system according to an embodiment of the present invention.
2 to 3 is a perspective view showing an elevator shaft cooling system according to an embodiment of the present invention.
Figure 4 is a cross-sectional view showing an elevator shaft cooling system in the summer according to an embodiment of the present invention.
Figure 5 is a cross-sectional view showing an elevator shaft cooling system in the winter season according to an embodiment of the present invention.
6 is a flowchart illustrating a method for cooling an elevator shaft according to an embodiment of the present invention.

Hereinafter, an elevator shaft cooling system and method according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is a cross-sectional view showing an elevator shaft cooling system according to an embodiment of the present invention, and FIGS. 2 to 3 are perspective views showing an elevator shaft cooling system according to an embodiment of the present invention.

1 to 3, the elevator shaft cooling system according to an embodiment of the present invention includes an elevator, a shaft in which the elevator moves up and down, and an air conditioner for adjusting the temperature of the elevator interior and the shaft. A control device for measuring the temperature and humidity of the elevator and the shaft to operate the air conditioning device may be provided.

The elevator shaft cooling system cools the inside of the elevator in the existing way in the summer and maintains the shaft the same as in the past, but in the winter, it is the fundamental cause of raising the internal temperature of the elevator in the building and cooling the shaft temperature at the same time to generate a stack effect. It is to reduce the differential pressure and temperature difference between the inside of the phosphorus shaft and the outside of the building.

In this way, it is possible to prevent the occurrence of a chimney effect by controlling the temperature difference between the elevator and the shaft in which the elevator moves up and down.

The air conditioner is provided on an upper portion of the elevator to provide air-conditioned air to the inside of the elevator, a duct protruding from the air conditioner and circulating the temperature-controlled air as it penetrates the elevator, and the air conditioner It may be provided at the top to be provided with an air conditioner for controlling the temperature of the shaft with the air of the elevator.

The air conditioner includes a frame provided to be mounted on the upper part of the elevator, an evaporator for cooling and supplying the inflowed air, a refrigerant compressor for circulating the refrigerant for cooling of the evaporator, and a compression pumping process in the refrigerant compressor. It may include a condenser that cools the heated refrigerant and supplies it to an evaporator, a circulation fan that circulates air inside the elevator around the evaporator, and a cooling fan that blows air to cool the condenser.

The air conditioner supplies cold air to the inside of the elevator and receives the remaining warmth to the elevator to generate cold air.

As the ducts are provided on both sides of the air conditioner, cold and warm air are circulated to alternately move the elevator and the air conditioner.

The duct protrudes from the air conditioner and is formed by bending a supply duct to supply temperature-controlled air to the elevator, and a discharge duct formed by bending the air discharged from the elevator to the air conditioner. In addition, the supply duct and the discharge duct extend from the bent position to the top, and the top is open to have a circulating duct through which the air of the shaft is introduced and discharged.

The supply duct and the discharge duct are respectively formed to protrude from both sides of the air conditioner, and after protruding horizontally from the air conditioner, one end extends vertically and penetrates the top of the elevator.

In addition, as the circulation duct extends upward from a joint in which the supply duct and the discharge duct are vertically bent, a duct is formed in the shape of'ㅓ','ㅏ'.

4 to 5, the supply duct may induce cold air supplied from the air conditioner to be supplied to the elevator and the shaft, and a blocking device is provided to supply cold air to the elevator and the shaft in the summer and winter, respectively.

And the discharge duct is also formed through the elevator so that the inside of the elevator is circulated to the air conditioner when discharged by the cold air supplied from the supply duct.

This discharge duct can also induce air in the elevator and shaft to flow into the air conditioner, and a blocking device is provided to supply warmth to the elevator and shaft in summer and winter, respectively.

The blocking device is provided with a hinge on the outer wall of the joint of the supply duct, and as the blocking plate rotates to the top and bottom, it can guide air to the shaft through the inside of the elevator and the circulation duct.

The air conditioner may include a discharge pipe extending from the top of the air conditioner to the top, an extension pipe extending from one side of the discharge pipe, and a supply pipe for purifying air supplied from the extension pipe and supplying it to the elevator.

The discharge pipe is provided at the top of the air conditioner to cool the air, and then a discharged waste heat source can be guided upward, and a first damper for guiding the waste heat source to a shaft and an elevator is provided at the top of the discharge pipe.

In addition, the discharge pipe may be provided with an exhaust fan to raise the waste heat source generated in the air conditioner upward.

The extension pipe extends to one side from the top of the discharge pipe, and an air purifier for purifying the waste heat source is provided at a position in contact with the discharge pipe. In addition, as the second damper is provided at a position where the extension pipe and the discharge pipe are in contact, the direction of induction of the waste heat source discharged through the discharge pipe can be adjusted to the shaft and the extension pipe.

In addition, a supply pipe is provided at the bottom of the air purifier provided at the end of the extension pipe to penetrate the elevator.

Accordingly, the waste heat source is purified from the air purifier during the winter and then supplied to the interior of the elevator.

The control device includes a measurement sensor provided in the elevator and in the shaft to measure temperature and humidity, and a temperature sensor provided in the duct and the air conditioning device in the measurement sensor to measure the temperature of air discharged from the air conditioner. can do.

The measurement sensor is provided inside the shaft, and can measure the temperature and humidity of the shaft. At this time, the measurement sensor can be provided anywhere on the outside of the elevator and on the wall of the shaft, and the information of the measurement sensor can be determined in real time by the control device.

The temperature sensor is provided in the duct and the air conditioning device to measure the temperature of the elevator and the temperature of air supplied and discharged from the elevator.

In addition, as the information measured by the temperature sensor is discriminated in real time by the control device, the fluctuation effect due to the temperature difference can be reduced.

At this time, in order to prevent the effect of the fluctuation in the control device, the air supplied from the air conditioner is operated in the summer to circulate the air from the air conditioner to the inside of the elevator by operating the blocking device to close the circulation duct. The air is circulated from the air conditioner to the shaft as the device is operated to open the circulation duct.

And the waste heat source generated from the air conditioner is opened in the summer, the first damper is closed, the second damper is closed and discharged to the shaft, the second damper is opened in the winter, and the first damper is closed to close the air conditioner. Purify the waste heat source generated in the supply to the inside of the elevator.

And the control device measures the internal temperature and humidity of the shaft in real time, calculates the dew point, and when the cold air blown out by the evaporator is below the dew point temperature, the system automatically stops to prevent condensation.

In describing the method for cooling an elevator shaft according to another embodiment of the present invention, the same reference numerals are used for the same configuration as the elevator shaft cooling system according to the above-described embodiment, and detailed description thereof will be omitted.

6 is a flowchart illustrating an elevator shaft cooling method according to an embodiment of the present invention.

In step S1100, temperature may be measured in real time by a measuring sensor provided in the shaft and a temperature sensor provided in the elevator.

In step S1200, the temperature inside the elevator may compare the temperature of the shaft.

At this time, the control device measures the internal temperature and humidity of the shaft in real time, calculates the dew point, and when the cold air drawn into the evaporator is below the dew point temperature, the system automatically stops to prevent condensation.

In step S1300, when it is determined in S1200 that the temperature inside the elevator is higher than the temperature of the shaft, it may be determined in summer.

In step S1400, when it is determined in S1200 that the temperature inside the elevator is lower than the temperature of the shaft, the winter season may be determined.

Step S2100 may operate the blocking device when it is determined that the summer season in step S1300. At this time, the blocking device is directed toward the upper portion so that air of the air conditioner is supplied to the interior of the elevator.

In step S2200, it is determined that it is the summer season, and the first damper inside the discharge pipe is opened, and the second damper is closed to discharge the waste heat source generated from the air conditioner to the shaft, thereby lowering the temperature inside the elevator and raising the shaft temperature. .

In step S3100, when it is determined that the winter season is in step S1300, the blocking device may be operated. At this time, the blocking device is directed toward the lower portion so that air of the air conditioner is supplied to the shaft.

At this time, the warmth of the shaft is supplied to the air conditioner through the discharge duct.

In step S3200, it is determined that it is the winter season, and the second damper inside the discharge pipe is opened, and the first damper is closed to purify the waste heat source generated in the air conditioner as in step S3300 and supply it into the elevator. Raise and lower the temperature of the shaft.

In the above, the elevator shaft cooling system and method according to an embodiment of the present invention have been described, but the spirit of the present invention is not limited to the embodiments presented herein. And, those skilled in the art who understand the spirit of the present invention can easily propose other embodiments by adding, changing, deleting, adding, or the like components within the scope of the same spirit, but also within the scope of the present invention. Would say

100: elevator 200: shaft
300: air conditioning unit 310: air conditioning
320: duct 330: air conditioner
331: discharge pipe 332: extension pipe
333: supply pipe 334: exhaust fan
335: air purifier 336: first damper
337: second damper 400: control device

Claims (14)

With an elevator,
A shaft in which the elevator moves up and down,
And an air conditioning device for adjusting the temperature of the interior of the elevator and the shaft,
It is provided with a control device for measuring the temperature and humidity of the elevator and the shaft to operate the air conditioning device,
The air conditioner is provided on an upper portion of the elevator to supply air with controlled temperature to the inside of the elevator, a duct protruding from the air conditioner and circulating the temperature-controlled air as it penetrates the elevator, and the air conditioner An elevator shaft cooling system which is provided at the top and includes an air conditioner that controls the temperature of the shaft with air in the elevator.
delete According to claim 1,
The duct protrudes from the air conditioner, and a supply duct formed by bending to supply temperature-controlled air into the elevator,
An exhaust duct formed by bending the air discharged from the inside of the elevator to be supplied to the air conditioner;
An elevator shaft cooling system, characterized in that the supply duct and the discharge duct extend from the bent position to the top, and the upper end is opened to include a circulation duct through which air in and out of the shaft flows.
According to claim 3,
The duct is provided at a position where the supply duct and the circulation duct are in contact, and an elevator shaft cooling system, characterized in that it has a blocking device for blocking air supplied and discharged from the elevator.
The method of claim 4,
The air conditioner extends from the top of the air conditioner to the top, and a discharge pipe having a first damper at the top,
An extension pipe extending from the discharge pipe to one side, and having a second damper at a position in contact with the discharge pipe,
And a supply pipe for purifying air supplied from the extension pipe and supplying it to the elevator.
The method of claim 5,
The air conditioning device is provided in the discharge pipe and an exhaust fan for raising the waste heat source generated in the air conditioner to the top,
An elevator shaft cooling system, further comprising an air purifier provided in the supply pipe to purify the waste heat source supplied to the elevator by the exhaust fan.
The method of claim 5,
The control device is provided on the inside of the elevator and the shaft and a measurement sensor for measuring the temperature and humidity,
The measurement sensor is provided in the duct and the air conditioning device is provided with a temperature sensor for measuring the temperature of the air discharged from the air conditioner Elevator shaft cooling system.
The method of claim 7,
The control device discharges the waste heat source generated in the air conditioner to the shaft by opening the first damper and closing the second damper in summer.
In the winter, the second damper is opened, and the first damper is closed to purify the waste heat source generated in the air conditioner and supply it to the interior of the elevator.
The method of claim 8,
The control device circulates air from the air conditioner to the inside of the elevator as the closing duct is closed by operating the blocking device in summer.
Elevator shaft cooling system, characterized in that the air is circulated from the air conditioner to the shaft by operating the blocking device in the winter to open the circulation duct.
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