TW201915407A - Cooling system for guiding airstream - Google Patents

Abstract

A cooling system for guiding airstream includes a body, a cooling device, a plurality of sensing devices and a central controlling device. The body includes an air outlet and an air exhausting vent. A first partition board, a second partition board and an air guiding board are disposed in the vicinity of the air outlet and divide the air outlet into a first air guiding outlet and a second air guiding outlet. The cooling device transforms the air into the cold air. Then, the cold air discharges from the first air guiding outlet and the second air guiding outlet and becomes a first cold airstream and a second cold airstream. A hot waste steam discharges from the air exhausting vent. When the plurality of sensing devices sense that the flow direction of the first cold airstream is different from the flow direction of the second cold airstream, the plurality of sensing devices transmits a adjusting signal to the central controlling device, and the central controlling device make the first partition board, the second partition board and the air guiding board move in order to achieve that the flow direction of the first cold airstream is the same as the flow direction of the second cold airstream.

Description

Convection guided cooling system

The present invention relates to a cooling system, and more particularly to a convection guiding cooling system that controls the flow direction of cold air.

Due to the influence of the greenhouse effect, the temperature of the earth is increasing year by year, and the temperature in summer is also increasing. Therefore, every summer, people always need to use air conditioners or air conditioners to reduce indoor air temperature and mitigate the impact of high temperature. However, the wind direction of the air outlet of the air conditioner is fixed and the wind direction cannot be adjusted, so that the indoor area limited to a certain part can feel the cold air and the other part of the indoor area fails to blow the air.

As described above, the inventors of the present invention have conceived and designed a convection-guided cooling system in order to improve the lack of the prior art, thereby enhancing the industrial implementation.

In view of the above-mentioned problems, it is an object of the present invention to provide a convection-guided cooling system for solving the problems faced by the prior art.

In view of the above, the present invention provides a convection-guided cooling system including a body, a cooling device, a plurality of sensing devices, and a central control device. The air body includes an air outlet and an air outlet. The first partition is disposed adjacent to the front surface of the body, and the second partition is disposed behind the first partition. The air deflector is disposed at the air outlet and located at the second partition by means of the interlocking structure. After the board, the area of the air deflector is larger than the area of the first partition and the area of the second partition; the first partition, the second partition and the air deflector divide the air outlet into a first air guiding port and a second air guiding port The first air guiding port is located between the first partition plate and the second partition plate, and the second air guiding port is located between the second partition plate and the air guiding plate, and the first partition plate is provided with the first driving device to move the first partition The second partition is provided with a second drive to move the second partition, and the wind deflector is provided with a guiding drive to drive the interlocking structure to move the wind deflector. The cooling device is disposed in the body and converts the outside air into cold air, and the cold air is taken out from the first air guiding port and the second air guiding port, and is divided into the first cold flow and the second cold flow, and the heat is discharged from the air exhaust port. Exhaust gas. The plurality of sensing devices are evenly distributed on the first separator, the second separator, and the wind deflector. The central control device is electrically connected to the cooling device, the first driver, the second driver, and the guiding driver. Wherein, when the plurality of sensing devices sense that the flow direction of the first cold flow is different from the flow direction of the second cold flow, the plurality of sensing devices transmit the adjustment signal to the central control device, and the central control device receives the adjustment signal and causes The first drive, the second drive and the guide drive are moved according to the first drive and the second drive, and the guide drive drives the linkage mechanism to move the air deflector to allow the flow direction of the first cold flow. The flow direction is the same as the second cold flow.

Preferably, when the plurality of sensing devices sense the temperature of the first cold flow or the temperature of the second cold flow exceeds the critical high temperature, the plurality of sensing devices send a boost signal to the central control device, and the central control device receives the enhanced signal and The cooling device is actuated according to the enhanced signal.

Preferably, the critical high temperature is 28 °C.

Preferably, the remote control module and the receiving module are further disposed in the body and electrically connected to the central control device. The remote control module sends a remote control signal to the receiving module, and the receiving module receives the remote control signal and transmits the same to the receiving module. The central control unit receives the remote control signal and causes the cooling device, the first driver, the second driver and the pilot driver to act accordingly.

Preferably, the remote control module sends a periodic signal to the receiving module, the receiving module receives the periodic signal and transmits it to the central control device, and the central control device receives the periodic signal, and causes the first driver, the second driver and the guiding driver to be based on It rotates periodically.

Preferably, the remote control module sends a timing signal to the receiving module, and the receiving module receives the timing signal and transmits it to the central control device. The receiving module receives the timing signal and transmits it to the central control device, and the central control device receives the timing signal. And the cooling device, the first driver, the second driver, and the pilot driver are stopped according to their timing.

Preferably, the first driver, the second driver and the guiding driver are all motor components.

Preferably, the cooling device comprises a compression unit, a condensing unit, a refrigerant control unit and an evaporation unit. The low temperature and low pressure liquid refrigerant circulates in the cooling device, and the compression unit compresses the low temperature and low pressure liquid refrigerant into a high temperature and high pressure gaseous refrigerant, high temperature and high pressure. The gaseous refrigerant is cooled by the condensing unit and then condensed into a liquid refrigerant of normal temperature and high pressure. The liquid refrigerant of normal temperature and high pressure is depressurized by the refrigerant control unit to form a liquid refrigerant of normal temperature and low pressure, and the external refrigerant flows through the evaporation unit and the liquid refrigerant at normal temperature and low pressure. When entering the evaporation unit, the liquid refrigerant at normal temperature and low pressure absorbs the heat of the external air and evaporates, and condenses into a low-temperature low-pressure liquid refrigerant to lower the temperature of the outside air.

Preferably, the interlocking structure comprises a fixing plate and a linking arm, and the fixing plate is disposed in the body, and the air guiding plate and the fixing plate are provided with a connecting seat for connecting the linking arm, and the guiding driver is disposed on the fixing plate and is connected to the connecting arm. The lead actuator drives the connecting arm when rotating, thereby moving the air deflector.

In view of the above, the convection guiding cooling system of the present invention may have one or more of the following advantages:

(1) The convection guiding cooling system of the present invention has a first partition plate, a second partition plate, and an air deflector for controlling the flow direction of the first cold flow and the flow direction of the second cold flow to allow the interior space to be There is cold air flow, not limited to a single flow direction.

(2) The convection guiding cooling system of the present invention has a remote control module to facilitate the user to control the flow direction of the first cold flow and the flow direction of the second cold flow.

The advantages and features of the present invention, as well as the technical methods of the present invention, are described in more detail with reference to the exemplary embodiments and the accompanying drawings. The embodiments of the present invention are to be construed as being limited by the scope of the present invention, and the invention The scope of the patent application is defined.

1 and 2 are respectively a block diagram of a first embodiment of a convection guiding cooling system of the present invention and a first embodiment of a convection guiding cooling system. In this embodiment, the convection guiding cooling system includes a body 10, a cooling device 20, a plurality of sensing devices 40, and a central control device 30. The air body 11 includes an air outlet 11 and an air outlet 12 . The first partition 13 is disposed adjacent to the front surface of the body 10 and the second partition 14 is disposed behind the first partition 13 . The air deflector 15 is moved by the interlocking structure 151 . After being disposed at the air outlet 11 and located behind the second partition 14, the area of the air deflector 15 is larger than the area of the first partition 13 and the area of the second partition 14 to turn the air outlet 11 adjacent to the rear surface of the body 10 The wind direction of the air outlet 11 adjacent to the front surface of the body 10 is consistent with the wind direction of the air outlet 11 adjacent to the rear surface of the body 10. The first partition 13, the second partition 14, and the air deflector 15 divide the air outlet 11 into An air guiding port 111 and a second air guiding port 112, the first air guiding opening 111 is located between the first partition plate 13 and the second partition plate 14, and the second air guiding port 112 is located between the second partition plate 14 and the wind deflector 15 And the first partition plate 13 is provided with a first drive 131 to move the first partition plate 13, the second partition plate 14 is provided with a second drive 141 to move the second partition plate 14, and the air guide plate 15 is provided with the guide drive 152 The wind deflector 15 is moved to drive the interlocking structure 151. The cooling device 20 is disposed in the body 10 and changes the outside air into cold air, and the cold air is taken out from the first air guiding port 111 and the second air guiding port 112, and is thereby divided into a first cold flow and a second cold flow, and simultaneously The hot exhaust gas is exhausted from the exhaust port 12. The plurality of sensing devices 40 are evenly distributed on the first separator 13 , the second separator 14 , and the air deflector 15 . The central control device 30 is electrically connected to the cooling device 20, the first driver 131, the second driver 141, and the guide driver 152. Wherein, when the plurality of sensing devices 40 sense that the flow direction of the first cold flow and the flow direction of the second cold flow are different, the plurality of sensing devices 40 transmit the adjustment signal 41 to the central control device 30, and the central control device 30 accepts When the adjustment signal 41 is applied and the first driver 131, the second driver 141, and the guiding driver 152 are actuated according to the operation, the first partition plate 13 and the second partition plate 14 move accordingly, and the guiding driver 152 drives the linkage mechanism 151 to move. The wind deflector 15 is configured to make the flow direction of the first cold flow and the flow direction of the second cold flow the same, and indirectly adjust the flow direction of the second cold flow to the other direction instead of blowing down from the second air guiding opening 112.

Moreover, when the plurality of sensing devices 40 sense the temperature of the first cold flow or the temperature of the second cold flow exceeds the critical high temperature, the plurality of sensing devices 40 send the boosting signal 42 to the central control device 30, and the central control device 30 Receiving the enhancement signal 42 and causing the cooling device 20 to actuate according to the enhancement signal 42 to adjust the ambient temperature without making it too high, and the critical high temperature is 28 ° C, which is an illustrative property and is not limited to the scope of the present invention. Make appropriate adjustments based on the perceived temperature of the user. The first driver 131, the second driver 141, and the guide driver 152 are all motor components, which are illustrative and not limiting to the scope of the invention, and may of course be other types of drive components.

Here, the operation mechanism of the cooling device 20 will be described in detail, and will be described in conjunction with FIG. As shown in FIG. 3, it is a structural diagram of a cooling device according to a first embodiment of the convection guiding cooling system of the present invention. As seen from FIG. 3, the cooling device 20 includes a compression unit 21, a condensing unit 22, and a refrigerant control unit. 23. The evaporation unit 24 and the refrigerant tank 25, and the low-temperature low-pressure liquid refrigerant circulates in the cooling device 20, and the refrigerant tank 25 is a container for storing the liquid refrigerant and the liquid refrigerant. The compressing unit 21 compresses the low-temperature low-pressure liquid refrigerant into a high-temperature high-pressure gaseous refrigerant, and the high-temperature high-pressure gaseous refrigerant is cooled and cooled by the condensing unit 22 to be condensed into a liquid refrigerant of normal temperature and high pressure, and the liquid refrigerant of normal temperature and high pressure is depressurized by the refrigerant control unit 23. Then, a liquid refrigerant of normal temperature and low pressure is formed. When the external air flows through the evaporation unit 24 and the liquid refrigerant at normal temperature and low pressure enters the evaporation unit 24, the liquid refrigerant at normal temperature and low pressure absorbs the heat of the external air and evaporates, and condenses into a low temperature and low pressure liquid refrigerant. The temperature of the outside air is lowered. Further, a fan may be added in the vicinity of the evaporation unit 24 to accelerate the discharge of the cooled outside air from the air outlet 11.

Here, the members of the interlocking mechanism 151 will be described in detail, and will be described with reference to FIG. As shown in FIG. 4, it is a structural view of the interlocking structure of the first embodiment of the convection guiding cooling system of the present invention. As seen from FIG. 4, the interlocking structure 151 includes a fixing plate 1511, a linking arm 1512, and a fixing plate. 1511 is disposed in the body 10, and the air guiding plate 15 and the fixing plate 1511 are provided with a connecting seat 1513 for connecting the connecting arm 1512. The guiding driver 152 is disposed on the fixing plate 1511 and axially connected to the connecting arm 1512. When the guiding driver 152 rotates, the connecting arm 1512 is driven to move the air guiding plate 15. Since the fixing plate 1511 and the guiding driver 152 are both located in the body 10, the central control device 30 is more easily connected to the guiding driver 152 through the electric wire. The wires are thus not exposed, making the overall look better.

5 and 6 are respectively a block diagram of a second embodiment of the convection guiding cooling system of the present invention and a schematic view of the second embodiment of the convection guiding cooling system of the present invention. In the present embodiment, the components of the same component symbols are similar in configuration to those described above, and the likes are not described herein again.

As shown in FIG. 5, the remote control module 50 and the receiving module 60 are further disposed. The receiving module 60 is disposed in the body 10 and electrically connected to the central control device 30. The remote control module 50 is electrically connected to the receiving module in a wireless manner. 60. The remote control module 50 sends the remote control signal 51 to the receiving module 60. The receiving module 60 receives the remote control signal 51 and transmits it to the central control device 30. The central control device 30 receives the remote control signal 51, and causes the cooling device 20 and the first driver 131. The second driver 141 and the guiding driver 152 are actuated according to the user to adjust the flow direction and temperature of the first cold flow and the second cold flow, and the first cold flow and the second can be adjusted without touching the body 10. Cold flow.

By the way, the remote control module 50 emits a periodic signal 52 different from the remote control signal 51. The mechanism of the periodic signal 52 will be described below. The remote control module 50 sends a periodic signal 52 to the receiving module 60. The receiving module 60 receives the periodic signal 52 and transmits it to the central control unit 30. The central control unit 30 receives the periodic signal 52 and causes the first driver 131 and the second driver. The first driver 131 drives the first partition plate 13 to periodically move according to the periodic rotation of the guide driver 152, the second drive unit 141 drives the second partition plate 14 to periodically move, and the guide driver 152 drives the linkage mechanism 151 to interlock. The mechanism 151 drives the air deflector 15 to periodically move, thereby periodically changing the flow direction of the first cold flow and the flow direction of the second cold flow, while the flow direction of the first cold flow and the flow direction of the second cold flow are not fixed. Flowing in a single direction, when the present invention is used in an indoor space, the effects of the first cold flow and the second cold flow can be felt everywhere in the indoor space.

In addition, the remote control module 50 also issues a timing signal 53 different from the foregoing. The mechanism of the timing signal 53 will be described below. The remote control module 50 sends a timing signal 53 to the receiving module 60. The receiving module 60 receives the timing signal 53 and transmits it to the central control device 30. The receiving module 60 receives the timing signal 53 and transmits it to the central control device 30 for central control. The device 30 receives the timing signal 53 and causes the cooling device 20, the first driver 131, the second driver 141, and the guiding driver 152 to stop according to the timing thereof, and the first partition 13, the second partition 14, and the air deflector 15 thereby The movement is stopped, and the user adjusts the operation time of the present invention according to his own preference, thereby increasing the flexibility in use.

As shown in FIG. 6, the user adjusts the flow direction of the first cold flow and the flow direction of the second cold flow according to his own preference, and only needs the signal of the remote control module 50 to reach the receiver of the receiving module 60. The signal can be an infrared signal or an RF signal. The type of the signal is not limited. Of course, the periodic signal 52 and the timing signal 53 can be sent through different buttons of the remote control module 50, which is more convenient for overall use.

In summary, the convection guiding cooling system of the present invention adjusts the movement of the first partition 13, the second partition 14 and the wind deflector 15 by the combination of the plurality of sensing devices 40 and the central control device 30, thereby adjusting The flow direction of the first cold flow and the flow direction of the second cold flow do not allow the flow direction of the second cold flow to be blown downward from the second air guide 112, and further include a remote control module 50 and a receiving module 60, The remote control module 50 is used to generate the remote control signal 51, and the movement of the first partition plate 13, the second partition plate 14 and the air deflector 15 and the operation of the cooling device 20 are controlled, and the first cold flow and the first adjustment can be adjusted without touching the body 10. In the second cold flow, the remote control module 50 emits a periodic signal 52 different from the remote control signal 51 and a timing signal 53, and adjusts the operating condition of the present invention according to the user's preference. In summary, the convection guiding cooling system of the present invention has the advantages described above, and adjusts the flow direction of the first cold flow and the flow direction of the second cold flow according to the user's preference, thereby increasing the comfort in use.

The above is intended to be illustrative only and not limiting. Any equivalent modifications or alterations to the spirit and scope of the invention are intended to be included in the scope of the appended claims.

10‧‧‧ body

11‧‧‧air outlet

12‧‧‧ exhaust vents

13‧‧‧ first partition

14‧‧‧Second partition

15‧‧‧Air deflector

20‧‧‧Cooling device

21‧‧‧Compression unit

22‧‧‧Condensation unit

23‧‧‧Refrigerant Control Unit

24‧‧‧Evaporation unit

25‧‧‧Refrigerant tank

30‧‧‧Central control unit

40‧‧‧Sensing device

41‧‧‧Adjustment signal

42‧‧‧Enhanced signal

50‧‧‧Remote control module

51‧‧‧Remote signal

52‧‧‧cycle signal

53‧‧‧Timed signal

60‧‧‧ receiving module

111‧‧‧First air duct

112‧‧‧Second air vent

131‧‧‧First drive

141‧‧‧second drive

151‧‧‧ linkage agency

152‧‧‧Guide Drive

1511‧‧‧fixed board

1512‧‧‧ linkage arm

1513‧‧‧Connector

Fig. 1 is a structural view showing a first embodiment of a convection guiding cooling system of the present invention.

Figure 2 is a block diagram of a first embodiment of a convective pilot cooling system of the present invention.

Figure 3 is a structural view of a cooling device of a first embodiment of the convection guiding cooling system of the present invention.

Fig. 4 is a structural view showing the interlocking structure of the first embodiment of the convection guiding cooling system of the present invention.

Figure 5 is a block diagram of a second embodiment of the convective pilot cooling system of the present invention.

Figure 6 is a schematic view showing the use of the second embodiment of the convection guiding cooling system of the present invention.

Claims (9)

A convection guiding cooling system includes: a body including an air outlet and a vent, a first partition disposed adjacent to a front surface of the body, and a second partition contiguously disposed after the first partition An air deflector is disposed on the air outlet and located behind the second partition, and the area of the air deflector is larger than an area of the first partition and an area of the second partition, the first The partition, the second partition, and the air deflector divide the air outlet into a first air guiding port and a second air guiding port, the first air guiding port is located between the first partition plate and the second partition plate The second air guiding port is located between the second partition plate and the air guiding plate, and the first partition plate is provided with a first driving device for moving the first partition plate, and the second partition plate is provided with a second driving device Moving the second partition, the air deflector is provided with a guiding drive to drive the interlocking structure to move the air guiding plate; a cooling device is disposed in the body and converts an outside air into a cold air, from The first air guiding port and the second air guiding port derive the cold air, and the cold air Dividing into a first cold flow and a second cold flow, and discharging a hot exhaust gas from the exhaust vent; a plurality of sensing devices are evenly distributed on the first partition, the second partition, and the wind guide a central control device electrically connected to the cooling device, the first driver, the second driver, and the guiding driver; wherein, when the plurality of sensing devices sense a flow direction of the first cold flow and the When the flow directions of the second cold flow are different, the plurality of sensing devices transmit an adjustment signal to the central control device, the central control device receives the adjustment signal and causes the first driver, the second driver, and the guide The first partition and the second partition move along with the driver, and the guiding drive drives the linkage to move the air deflector to allow the flow direction of the first cold flow and the second The flow direction of the cold flow is the same. The convection guiding cooling system according to claim 1, wherein when the plurality of sensing devices sense the temperature of the first cold flow or the temperature of the second cold flow exceeds a critical high temperature, the plural The sensing device sends a boosting signal to the central control device, and the central control device receives the enhanced signal and causes the cooling device to act according to the enhanced signal. The convection guiding cooling system of claim 2, wherein the critical high temperature is 28 °C. The convection-guided cooling system of claim 1, further comprising a remote control module and a receiving module, the receiving module being disposed in the body and electrically connected to the central control device, the remote control module Sending a remote control signal to the receiving module, the receiving module receives the remote control signal and transmits it to the central control device, the central control device receives the remote control signal, and causes the cooling device, the first driver, the second The driver and the pilot driver act accordingly. The convection-guided cooling system of claim 4, wherein the remote control module sends a periodic signal to the receiving module, and the receiving module receives the periodic signal and transmits the signal to the central control device. The central control device receives the periodic signal and causes the first driver, the second driver, and the guiding driver to periodically rotate according to the periodicity. The convection-guided cooling system of claim 4, wherein the remote control module sends a time signal to the receiving module, and the receiving module receives the timing signal and transmits the timing signal to the central control device. Receiving, by the receiving module, the timing signal and transmitting the timing signal to the central control device, the central control device accepting the timing signal, and causing the cooling device, the first driver, the second driver and the guiding driver to stop according to the timing thereof . The convection guiding cooling system of claim 1, wherein the first driver, the second driver, and the guiding driver are motor assemblies. The convection guiding cooling system according to claim 1, wherein the cooling device comprises a compression unit, a condensing unit, a refrigerant control unit and an evaporation unit, wherein a low-temperature low-pressure liquid refrigerant circulates in the cooling device. The compression unit compresses the low-temperature low-pressure liquid refrigerant into a high-temperature high-pressure gas refrigerant, and the high-temperature high-pressure gas refrigerant is cooled and cooled by the condensing unit to be condensed into one liquid refrigerant of normal temperature and high pressure, and the liquid refrigerant at normal temperature and high pressure is passed through The refrigerant control unit is stepped down to form a liquid refrigerant of a normal temperature and a low pressure. When the external air flows through the evaporation unit and the liquid refrigerant enters the evaporation unit at a normal temperature and a low pressure, the liquid refrigerant at normal temperature and low pressure absorbs the heat of the external air. The liquid refrigerant evaporates and condenses into a low temperature and a low pressure. The convection guiding cooling system of claim 1, wherein the linking structure comprises a fixing plate and a connecting arm, wherein the fixing plate is disposed in the body, and the air guiding plate and the fixing plate are provided with a connection. The connecting arm is connected to the connecting arm, and the guiding driver is disposed on the fixing plate and is coupled to the linking arm. The guiding driver drives the connecting arm when rotating, thereby moving the air guiding plate.