LT6344B - COOLING UNIT WITH COOLING FAN IN ELECTRICAL INSTALLATION PIPES IN BUILDINGS - Google Patents

Abstract

The cooling unit element with cooling fan for the electrical installation pipe in buildings includes several cooling devices with air supply through the air supply pipe (61). The cooling devices are arranged along the vertical direction of the electrical installation channel. Each cooling unit has the same cooling device (82) and fixed supports (100) which are mounted on both sides of the cooling unit (82) itself and are used to fasten that cooling device (82) to the two opposite wall walls (102) of the electrical installation channel. Cable mounting holes (103) for the supply cable (1030) are provided in fixed supports (100). The cooling device (82) itself has an air inlet (6) and an annular cavity (15) connected to the air supply pipe (61).

Description

Technical field

The present invention relates to the field of construction, more particularly to a cooling unit element with a cooling fan for a wiring pipe in a building.

State of the art

Electrical wiring to supply electricity is currently known. One of the cooling units with a fan is described in Chinese Patent Application WO2008080285 (A) CN.

To ensure an even supply of electricity to the electrical equipment on each floor of the building, wiring pipes are often installed to supply electricity. The heat generated by the cable in the electrical installation pipe is dissipated in time and ensures the safety of energy use, and the electrical installation pipe is typically provided with a municipal exhaust ventilation duct so that the heat is evenly distributed.

With a long supply cable, the amount of electricity used on each floor is different. In addition, cable ducts have different structures and cable quality. All this results in intense heat accumulation in the cables. Such uneven heat build-up damages the insulation layer of the cable surface and poses a potential risk to the energy security of the entire building.

Existing cooling units are difficult to dissipate heat at intense heat points or the construction of cooling units is too complicated.

The essence of the invention

It is an object of the present invention to provide a cooling unit element with a cooling fan for electrical installation pipes in a building that can overcome said defects.

The cooling unit element with cooling fan for the electrical installation pipe in the building comprises a plurality of air cooling pipe units, and the cooling units are arranged along the vertical installation pipe. Each cooling device has its own cooling device and fixed supports, which are mounted on either side of the cooling device itself and are used to attach that cooling device to two opposite side walls of the electrical installation duct.

Cable mounting holes for the supply cable are provided in fixed supports. The cooling device itself has an air inlet nozzle and an annular cavity sheath connected to the air supply pipe. The annular cavity shell is integrated with the lower annular portion and the drum-shaped portion on the upper side, and the inside is an air-connected cavity. A plurality of connection openings evenly spaced along the peripheral direction provided on the inner side wall of the drum-shaped portion are used to selectively align and connect the central connecting openings in the upper inflated loop of the coupling eyelet which is pivotally located inside the drum-shaped portion. The inside of the upper edge of the inflated loop is pivotally connected to a curved air duct connection block which is rigidly connected to the top of the drum-shaped portion of the annular shell casing via a plurality of nozzles. Multiple gas paths forming a right angle are provided in the bending air channel connector block and each gas path is connected to each nozzle in a plurality of nozzles and corresponds to each junction so that air can be delivered to the jets through a separate junction with the middle junctions. The connecting loop device is connected to the disk portion at the bottom of the upper inflated loop. The disk button hole is located in the middle of the disk portion and is used to slide the upper end of the output button axis, which can slip axially in the engine, which is mounted at the bottom of the annular portion of the annular shell casing. The output button axis is slidably connected to the motor by a button hole in the center of the motor rotor, and the notch head is located at the bottom end and is used to slip the baseboard button hole in the fixed skirting. The fixed skirt keeps the annular cavity shell through the bearing unit. Cooling vanes are mounted on the outer surface of the engine and are used to absorb and dissipate heat generated during engine operation. The cooling fan is mounted on the cooling blades and is used to accelerate the dissipation of heat absorbed by the cooling blades to prevent the engine from igniting due to too high a temperature after prolonged operation. Each nozzle has a different nozzle angle with the horizontal surface of the nozzle plate. Thus, when the output button axis is controlled at the top by the output button axis workpiece, the top end of the output button axis is connected to the disk opening, and the cutter head is disconnected from the skirting button hole. At this point, the motor can rotate the coupling loop device to select the nozzle with the required nozzle angle and connect them to the annular cavity shell. When the output key axis in the lower position is controlled by the output key axis device, the top end of the output key axis is disconnected from the disk button hole and the cutter head is connected to the skirting board button hole. At this point, the motor can rotate the annular cavity shell to rotate the nozzle plate and adjust the peripheral angular position of the nozzles. The motor stator is connected to the power supply via a rotary junction device.

It is desirable that each cooling device be connected to a temperature sensor signal that can detect the temperature of the wiring pipe at different positions to determine the exact nozzle position that is necessary to fine-tune the cooling air injection.

The present invention dissipates heat through intense cooling of air injection in the area of superheat and is discharged through a municipal air vent. Based on the use of the wiring pipe and its design features, the present invention employs a cooling device. Because the nozzles are fixed at different angles, and a series of such nozzles with different angles are installed, the variable design of fixed elements can be reduced to a size that avoids unstable factors in the working process. The engine can control the nozzle connection at the right angle to the air, and the engine can adjust the peripheral direction of the nozzle to match the heat concentration site to cool the area. The entire unit has a compact design and stable performance and can effectively reduce local overheating in the equipment and improve the reliability of all equipment. A temperature detector mounted at different locations in each electrical installation pipe (particularly at different locations in the vertical direction) can detect the location of the heat concentration so as to align the nozzle with the direction of the cooling injection and provide a basis for selecting the nozzle angle.

Descriptions of enclosed drawings Fig. showing a general arrangement diagram of a cooling unit element with a cooling fan for a wiring pipe in buildings;

Fig. shows a schematic diagram of a cooling unit of the present invention.

Detailed implementation mode

The present invention is described in detail with reference to FIG. and Fig. 2.

According to an embodiment, the cooling unit element with cooling fan for the electrical installation pipe in the building comprises a plurality of cooling devices with air supply by the air supply pipe 61. The cooling devices are arranged along the electrical installation channel in the vertical direction. Each cooling device has a cooling device 82 itself and fixed supports 100, which are mounted on either side of the cooling device 82 itself, and are used to attach that cooling device 82 to two opposite side walls 102 of the electrical installation conduit. The cooling device 82 itself has an air inlet nozzle 6 and an annular cavity sheath 15 connected to the air supply tube 61. The annular cavity sheath 15 is integrated with the lower annular portion 152 and the drum-shaped portion 151 on the upper side, and the inside is an air-connected cavity 150. connecting holes 4 evenly spaced along a peripheral direction disposed on the inner side wall of the drum portion 151, and these openings 4 are used to selectively align and connect the middle connecting holes 2 in the upper inflated loop 31 of the connecting loop device 3 rotatably inside the drum-shaped portion 151. The interior of the periphery of the upper inflated loop 31 is pivotally connected to a curved air channel connector block 19 which is rigidly connected to the top of the drum-shaped portion 151 of the annular shell 15 through a nozzle plate 17 with a plurality of nozzles 20. in the air duct connection unit 19, and each gas path 21 is connected to each nozzle in a plurality of nozzles 20 and corresponds to each junction 4 so that air can be delivered to the nozzles 20 through a separate junction with the middle junctions 2. portion 30 at the bottom of the upper inflated loop 31. The disk button aperture is located in the middle of the disk portion 30 and is used to slide the upper end of the output button axis 11, which can slip axially in the engine 111 in a fixed mounting aperture of the annular portion 152 of the annular shell 15. The output button axis 11 is slidably connected to the motor by a button hole in the middle of the rotor 5 of the motor 111 and a notching head 9 is disposed at the lower end and used to slidably connect the baseboard button hole 8 in the fixed baseplate 12. The fixed baseplate 12 holds the annular cavity 15 through the cooling device. The cooling fan 63 is mounted on the cooling blades 62 and is used to accelerate the dissipation of the heat absorbed by the cooling blades 62 to prevent ignition of the engine 111 due to excessive temperature after prolonged operation. Each nozzle 20 has a different nozzle angle with a horizontal surface of the nozzle plate 17. Thus, when the output button axis 11 is controlled at the top by the output button axis 11 actuator 7, the upper end of the output button axis 11 is connected to the disk opening and the notch head 9 is disconnected from the baseboard button hole 8. to select the nozzle 20 with the required nozzle angle and to connect them to the annular cavity shell 15. When the output key axis 11 is controlled by the output key axis 11 device 7 in its lower position, the upper end of the output key axis 11 is disconnected by the disk key hole 9 is connected to the button hole 8 in the skirting board. At present, the motor 111 can rotate the annular cavity cover 15 so as to rotate the nozzle plate 17 and adjust the peripheral angular position of the nozzles 20. The stator 16 of the motor 111 is connected to a power supply via a rotary junction device 200.

Preferably, each cooling device 82 is connected to a temperature sensor signal that can detect a temperature value of the wiring pipe at different positions to determine the exact position of the nozzles 20 that is necessary to adjust the cooling air injection.

The locking device 13 is optionally also mounted on a fixed skirting 12 to relatively rotate and block the annular cavity shell 15 and the fixed skirting 12.

The linear mounting bracket 1031 is optionally mounted separately on the other two corresponding side walls of the electrical installation pipe. The cooling unit element may cool the power cable 1030 attached to the cable mounting holes 103 and the power cable 1030 attached to the linear mounting support 1031.

The heat is dissipated by intense cooling of the air injection in the area of superheat and discharged through a municipal air vent. Based on the use of the wiring pipe and its design features, the present invention employs a cooling device. Because the nozzles are fixed at different angles, and a series of such nozzles with different angles are installed, the variable design of fixed elements can be reduced to a size that avoids unstable factors in the working process. The engine can control the nozzle connection at the right angle to the air, and the engine can adjust the peripheral direction of the nozzle to match the heat concentration site to cool the area. The entire unit has a compact design and stable performance and can effectively reduce local overheating in the equipment and improve the reliability of all equipment. A temperature detector mounted at different locations in each electrical installation pipe (particularly at different locations in the vertical direction) can detect the location of the heat concentration so as to align the nozzle with the direction of the cooling injection and provide a basis for selecting the nozzle angle.

In accordance with the foregoing, various modifications may be made to the person skilled in the art as defined in the operating mode within the scope of the present invention.

Claims (4)

DEFINITION OF INVENTION A cooling unit with a cooling fan for an electrical installation pipe in a building, characterized in that it comprises a plurality of cooling units with an air supply pipe (61); the cooling devices are arranged along the electrical installation channel in the vertical direction; each cooling unit having a cooling unit (82) itself and fixed supports (100) mounted on either side of the cooling unit (82) itself and used to attach said cooling unit (82) to two opposite side walls (102) of the electrical installation conduit; cable mounting holes (103) for the supply cable (1030) are provided in fixed supports (100); the cooling device (82) itself has an air inlet nozzle (6) and an annular cavity sheath (15) connected to the air supply pipe (61); the annular cavity shell (15) integrated with the lower annular portion (152) and the drum-shaped portion (151) on the upper side, the interior being an air-connected cavity (150); a plurality of connecting openings (4) evenly spaced along a peripheral direction disposed on the inner side wall of the drum-shaped portion (151), and these openings (4) are used to selectively align and connect the central connecting openings (2) in the upper inflated loop of the connecting loop device (3) (31) which is secured within the pivotable drum-shaped portion (151); the inside of the periphery of the upper inflated loop (31) being pivotally connected to the curved air channel connection block (19) rigidly connected to the top of the drum-shaped portion (151) of the annular shell (15) through a nozzle plate (17) with several nozzles (20); a plurality of gas paths (21) forming a right angle formed in the bending air channel connection block (19) and each gas path (21) being connected to each nozzle in a plurality of nozzles (20) and corresponding to each connection opening (4) could be delivered to the nozzles (20) via a separate connection with the middle connection openings (2); a connecting loop device (3) connected to the disk portion (30) at the bottom of the upper inflated loop (31); a disk button aperture located in the middle of the disk portion (30) and used to slide the upper end of the output button axis (11), which may slip axially in the motor (111), at a fixed mounting aperture of the annular portion (152) of the annular cavity; the output button axis (11) is slidably coupled to the motor by a button hole in the middle of the rotor (5) of the motor (111) and the notching head (9) is disposed at the lower end and used to slidably connect the baseboard button opening (8) to the fixed skirting board (12); the fixed skirting (12) holds the annular cavity shell (15) through the bearing device (14); cooling blades (62) mounted on the outer surface of the engine (111) and used to absorb and dissipate heat generated during engine operation (111); a cooling fan (63) mounted on the cooling vanes (62) and used to accelerate the dissipation of heat absorbed by the cooling vanes (62) to prevent the engine (111) from igniting due to excessive temperature after prolonged operation; each nozzle (20) having a different nozzle angle with a horizontal surface of the nozzle plate (17); thus, when the output button axis (11) is controlled at the top by the output button axis (11) working device (7), the upper end of the output button axis (11) is connected to the disk opening and the cavity head (9) is disconnected from the skirting button hole (8). ; the motor (111) can then rotate the connecting loop device (3) to select a nozzle (20) with the required nozzle angle and connect them to the annular cavity shell (15); when the output key axis (11) in the lower position is controlled by the output key axis (11) device (7), the upper end of the output key axis (11) is disconnected from the disk button hole and the cutaway head (9) is connected to the skirting button hole (8); at this point, the motor (111) can rotate the annular cavity shell (15) so as to rotate the nozzle plate (17) and adjust the peripheral angular position of the nozzles (20); the stator (16) of the motor (111) being connected to a power supply via a rotary junction device (200). A cooling unit element with a cooling fan for a wiring pipe in a building according to claim 1, characterized in that each cooling unit (82) is connected to a temperature sensor signal that can detect a wiring temperature value at different positions to determine the exact nozzle (20). ) position necessary to adjust cooling air injection. A cooling unit element with a cooling fan for an electrical installation pipe in a building according to claim 1 or 2, characterized in that the blocking device (13) is optionally also mounted on a fixed baseboard (12) to rotate and block the annular cavity shell (15). a fixed skirting (12). A cooling unit element with a cooling fan for an electrical installation pipe in a building according to claim 1 or 2, characterized in that the linear mounting support (1031) is optionally mounted separately on the other two corresponding side walls of the electrical installation pipe; the cooling unit element can cool the power cable (1030) secured in the cable mounting holes (103) and the power cable (1030) secured by the linear mounting support (1031).