CN113251819B

CN113251819B - Energy-saving cooling tower

Info

Publication number: CN113251819B
Application number: CN202110508302.XA
Authority: CN
Inventors: 周武平; 谢茂华
Original assignee: Jiangxi Ark Fliud Science Technology Co ltd
Current assignee: Jiangxi Ark Fliud Science Technology Co ltd
Priority date: 2021-05-11
Filing date: 2021-05-11
Publication date: 2022-07-15
Anticipated expiration: 2041-05-11
Also published as: CN113251819A

Abstract

The invention relates to a cooling tower, in particular to an energy-saving cooling tower. The invention provides an energy-saving cooling tower which can automatically control the flow of cooling water, automatically clean water scale and automatically extract steam. An energy saving cooling tower comprising: the base is provided with a cooling tower; the lower side of the cooling tower is provided with six first fixing frames; the lower sides of the six first fixing frames are provided with first telescopic assemblies; the six first telescopic assemblies are rotatably provided with universal wheels; the cooling tower is provided with a water inlet component; the air inlet pipe is arranged on the air inlet pipe and the cooling tower. According to the invention, the cold air generated by the rotation of the fan blades is used for extracting the steam in the cooling tower, so that the steam flows out through the outlet of the cooling tower, and the steam extraction effect is realized.

Description

Energy-saving cooling tower

Technical Field

The invention relates to a cooling tower, in particular to an energy-saving cooling tower.

Background

The effect of cooling tower is to carry the circulating water of waste heat to carry out the heat exchange with the air in the tower, give the air and the atmosphere of scattering to the heat transmission of water, cool down the circulating water, conventional cooling tower sprays hot water to the surface of packing and the cold air contact through packing, produce the heat exchange between hot water and the cold air, partial hot water is evaporated simultaneously, water after the cooling finally falls into the pond, because mainly dispel the heat through the evaporation of water, so the cooling tower produces a large amount of evaporation loss water yield, lead to the water waste, energy-concerving and environment-protective inadequately.

At present, a water pump for supplying water to a cooling tower and a fan of the cooling tower are driven by motors, the automatic control level of the motor is low, the working state of the cooling tower is single, the motor does not have the capability of automatic adjustment along with the change of various parameters, the cooling capability of the cooling tower is surplus all the year round, a large amount of electric energy for driving the water pump and the fan is consumed every year, and a large energy-saving space is provided.

Therefore, an energy-saving cooling tower capable of automatically controlling cooling water flow, automatically cleaning water scale and automatically extracting steam is designed.

Disclosure of Invention

In order to overcome the defects that the traditional cooling tower cannot automatically control the cooling water flow, cannot automatically clean water scales and cannot automatically extract steam, the invention provides an energy-saving cooling tower which can automatically control the cooling water flow, automatically clean the water scales and automatically extract the steam.

The invention is realized in this way, and an energy-saving cooling tower comprises:

the base is provided with a cooling tower;

the lower side of the cooling tower is provided with six first fixing frames;

the lower sides of the six first fixing frames are provided with first telescopic assemblies;

the six first telescopic assemblies are rotatably provided with universal wheels;

the cooling tower is provided with a water inlet component;

the cooling tower is provided with an air inlet pipe;

a water outlet pipe is arranged on the cooling tower;

the air guide mechanism is arranged in the cooling tower;

the fan blades are arranged on the air guide mechanism;

the cooling tower is provided with a heat dissipation mechanism.

Further, it is particularly preferable that the air guide mechanism includes:

the water inlet component is provided with a water flow sensor;

the upper side in the cooling tower is provided with a first driving motor;

the output shaft of the first driving motor is connected with a rotating shaft, and the rotating shaft is connected with the fan blades;

the installation piece, pivot downside is equipped with the installation piece.

Further, it is particularly preferable that the heat dissipation mechanism includes:

the upper side in the cooling tower is provided with a first heat dissipation frame;

the upper side in the cooling tower is provided with a second heat dissipation frame in a sliding manner;

the fixing rings are arranged on the two sides of the cooling tower and connected with the second heat dissipation frame;

the cooling tower is provided with cooling fins at the lower side.

As a preferable aspect of the present invention, the moving mechanism includes:

the first driving motor is provided with a digital Hall magnetic sensor;

the magnetic steel is arranged on the rotating shaft;

the two sides of the cooling tower are provided with second fixing frames;

electric putter all installs electric putter on two second mounts, and electric putter telescopic link is connected with second heat dissipation frame.

As a preferable aspect of the present invention, the cleaning mechanism includes:

the temperature sensor is arranged inside the cooling tower;

the middle part of the lower side of the cooling tower is provided with a third fixing frame;

the third fixing frame is provided with a second driving motor;

the output shaft of the second driving motor is provided with a first brush plate;

the two sides of the first brush plate are provided with second telescopic assemblies;

the second brush board, two flexible subassemblies of second all are equipped with the second brush board.

As a preferred aspect of the present invention, a valve control mechanism includes:

the lower side in the cooling tower is provided with a liquid level sensor;

the water pump is arranged on the lower side of the cooling tower;

the electromagnetic valve is arranged on the water outlet pipe.

As a preferable aspect of the present invention, the adsorption mechanism includes:

the upper side of the cooling tower is provided with six fourth fixing frames;

the air guide frames are connected among the six fourth fixing frames and are connected with the cooling tower;

the metal screen panel, air guide frame downside is equipped with the metal screen panel, and metal screen panel quantity is four.

As a preferable aspect of the present invention, the descaling device includes:

the cooling tower is internally provided with three fixing blocks;

the three fixed blocks are provided with third telescopic assemblies;

the annular sponge brush is connected between the three third telescopic assemblies.

As a preferred technical scheme of the invention, a control box is installed on the upper side of the cooling tower, a switching power supply, a control module and a power module are installed in the control box, the switching power supply supplies power for the energy-saving cooling tower, the output end of the switching power supply is electrically connected with the power module, the power module is connected with a power main switch through a circuit, and the control module is electrically connected with the power module; the control module is connected with a DS1302 clock circuit and a 24C02 circuit; the water flow sensor, the digital Hall magnetic sensor, the temperature sensor and the liquid level sensor are all electrically connected with the control module, and the first driving motor, the second driving motor, the electromagnetic valve, the electric push rod and the water pump are all connected with the control module through the relay control module.

The invention provides an energy-saving cooling tower. The method has the following beneficial effects:

1. according to the invention, the cold air generated by the rotation of the fan blades is used for extracting the steam in the cooling tower, so that the steam flows out through the outlet of the cooling tower, and the steam extraction effect is realized;

2. according to the invention, water drops flow into the cooling tower through the first heat dissipation frame and the second heat dissipation frame, and the water drops are cooled by the heat dissipation fins, so that heat is discharged out of the cooling tower, and the heat dissipation effect of the heat dissipation fins is realized;

3. according to the invention, the second telescopic assembly is extended, so that the second brush plate is driven to move outwards and backwards, and the second brush plate cleans scale in the cooling tower, so that the scale cleaning effect of the second brush plate is realized;

4. according to the invention, hot water after cooling in the cooling tower is extracted through the water pump, so that the hot water after cooling flows out through the water outlet pipe, and the water pump extraction effect is realized.

Drawings

Fig. 1 is a schematic perspective view of the present invention.

Fig. 2 is a schematic cross-sectional three-dimensional structure of a first viewing angle according to the present invention.

Fig. 3 is a schematic cross-sectional three-dimensional structure of a second viewing angle according to the present invention.

Fig. 4 is a schematic cross-sectional three-dimensional structure of a third viewing angle according to the present invention.

Fig. 5 is a schematic cross-sectional three-dimensional structure of the air guiding mechanism of the present invention.

Fig. 6 is a schematic cross-sectional three-dimensional structure of the heat dissipation mechanism of the present invention.

Fig. 7 is a perspective view of a first part of the moving mechanism of the present invention.

Fig. 8 is a perspective view of a second part of the moving mechanism of the present invention.

Fig. 9 is a schematic cross-sectional perspective view of the cleaning mechanism of the present invention.

Fig. 10 is a perspective view of a first portion of the valve control mechanism of the present invention.

Fig. 11 is a perspective view of a second part of the control valve mechanism of the present invention.

FIG. 12 is a schematic cross-sectional perspective view of the adsorption mechanism of the present invention.

FIG. 13 is a schematic sectional perspective view of the descaling mechanism according to the present invention.

FIG. 14 is a circuit block diagram of the present invention.

Fig. 15 is a schematic circuit diagram of the present invention.

Number designation in the figure: 1: cooling tower, 2: base, 3: first mount, 4: first telescopic assembly, 5: universal wheel, 6: water intake assembly, 7: air-supply line, 8: outlet pipe, 9: fan blade, 10: control box, 11: air guide mechanism, 111: water flow rate sensor, 112: first drive motor, 113: rotating shaft, 114: mounting block, 12: heat dissipation mechanism, 121: first heat dissipation frame, 122: second heat dissipation frame, 123: fixing ring, 124: heat sink, 13: moving mechanism, 131: digital hall magnetic sensor, 132: magnetic steel, 133: second mount, 134: electric putter, 14: cleaning mechanism, 141: temperature sensor, 142: third mount, 143: second drive motor, 144: first brush plate, 145: second telescopic assembly, 146: second brush plate, 15: valve control mechanism, 151: level sensor, 152: water pump, 153: electromagnetic valve, 16: adsorption mechanism, 161: fourth mount, 162: air guide frame, 163: metal mesh enclosure, 17: descaling mechanism, 171: fixed block, 172: third telescopic assembly, 173: an annular sponge brush.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

Referring to fig. 1-15, the present invention provides a technical solution: an energy-saving cooling tower comprises a cooling tower 1, a base 2, a first fixing frame 3, a first telescopic component 4 and universal wheels 5, intake subassembly 6, air-supply line 7, the outlet pipe 8, flabellum 9, air guiding mechanism 11 and heat dissipation mechanism 12, be equipped with cooling tower 1 on the

base

2, 1 downside of cooling tower is equipped with six first mounts 3, six first mount 3 downside all are equipped with first telescopic component 4, equal rotary type is equipped with universal wheel 5 on six first

telescopic component

4, 1 right side of cooling tower is equipped with water intake assembly 6, water intake assembly 6 comprises water pipe and atomizer, the water pipe is established on cooling tower 1, atomizer establishes on the water pipe, 1 left side of cooling tower is equipped with air-

supply line

7, 1 right side of cooling tower is equipped with

outlet pipe

8, 1 inside air guiding mechanism 11 that is equipped with of cooling tower, be equipped with flabellum 9 on the air guiding mechanism 11, be equipped with heat dissipation mechanism 12 on the cooling tower 1.

The air guide mechanism 11 comprises a water flow sensor 111, a first driving motor 112, a rotating shaft 113 and an installation block 114, the water flow sensor 111 is arranged on the water inlet assembly 6, the first driving motor 112 is arranged on the upper side inside the cooling tower 1, the rotating shaft 113 is connected with an output shaft of the first driving motor 112, the rotating shaft 113 is connected with fan blades 9, and the installation block 114 is arranged on the lower side of the rotating shaft 113.

The heat dissipation mechanism 12 includes a first heat dissipation frame 121, a second heat dissipation frame 122, fixing rings 123 and heat dissipation fins 124, the first heat dissipation frame 121 is disposed on the upper side inside the cooling tower 1, the second heat dissipation frame 122 is slidably disposed on the upper side inside the cooling tower 1, the fixing rings 123 are disposed on the left side and the right side of the cooling tower 1, the fixing rings 123 are connected with the second heat dissipation frame 122, and the heat dissipation fins 124 are disposed on the lower side of the cooling tower 1.

The cooling tower is characterized by further comprising a moving mechanism 13, wherein the moving mechanism 13 comprises a digital Hall magnetic sensor 131, magnetic steel 132, a second fixing frame 133 and an electric push rod 134, the digital Hall magnetic sensor 131 is arranged on the first driving motor 112, the magnetic steel 132 is arranged on the rotating shaft 113, the second fixing frames 133 are arranged on the front side and the rear side of the left portion of the cooling tower 1, the electric push rods 134 are arranged on the two second fixing frames 133, and telescopic rods of the electric push rods 134 are connected with the second heat dissipation frame 122.

Still including clean mechanism 14, clean mechanism 14 is including temperature sensor 141, third mount 142, second driving motor 143, first brush board 144, second flexible subassembly 145 and second brush board 146, cooling tower 1 is inside to be equipped with temperature sensor 141, cooling tower 1 downside middle part is equipped with third mount 142, install second driving motor 143 on the third mount 142, second driving motor 143 output shaft is connected with the bottom rotary type of cooling tower 1, be equipped with first brush board 144 on the second driving motor 143 output shaft, first brush board 144 left and right sides all is equipped with second flexible subassembly 145, two flexible subassemblies 145 of second all are equipped with second brush board 146.

Still including accuse valve mechanism 15, accuse valve mechanism 15 is equipped with level sensor 151 including level sensor 151, water pump 152 and

solenoid valve

153, 1 inside downside of cooling tower, and water pump 152 is installed to 1 downside of cooling tower, and water pump 152 is connected with outlet pipe 8, is equipped with solenoid valve 153 on the water pipe 8.

Still including adsorption apparatus 16, adsorption apparatus 16 is including fourth mount 161, air guide frame 162 and

metal screen panel

163, and 1 upside of cooling tower is equipped with six fourth mounts 161, is connected with air guide frame 162 between six fourth mounts 161, and air guide frame 162 is connected with cooling tower 1, and air guide frame 162 downside is equipped with metal screen panel 163, and metal screen panel 163 quantity is four.

The descaling device further comprises a descaling mechanism 17, wherein the descaling mechanism 17 comprises fixing blocks 171, third telescopic assemblies 172 and annular sponge brushes 173, the three fixing blocks 171 are arranged inside the cooling tower 1, the third telescopic assemblies 172 are arranged on the three fixing blocks 171, and the annular sponge brushes 173 are connected among the three third telescopic assemblies 172.

The cooling tower is characterized by further comprising a control box 10, the control box 10 is installed on the upper side of the cooling tower 1, a switching power supply, a control module and a power supply module are installed in the control box 10, the switching power supply supplies power for the energy-saving cooling tower, the output end of the switching power supply is electrically connected with the power supply module, the power supply module is connected with a power supply main switch through a circuit, and the control module is electrically connected with the power supply module; the control module is connected with a DS1302 clock circuit and a 24C02 circuit; the water flow sensor 111, the digital hall magnetic sensor 131, the temperature sensor 141 and the liquid level sensor 151 are all electrically connected with the control module, and the first driving motor 112, the second driving motor 143, the electromagnetic valve 153, the electric push rod 134 and the water pump 152 are all connected with the control module through the relay control module.

The working principle of the invention is that when people want to cool hot water, the energy-saving cooling tower can be used, firstly, a user pushes the cooling tower 1, the universal wheel 5 is in contact fit with the ground, so as to drive the universal wheel 5 to rotate, the universal wheel 5 drives the first telescopic component 4, the first fixing frame 3, the base 2 and the cooling tower 1 to move, after the cooling tower 1 moves to a specified position, the user stops pushing the cooling tower 1, the universal wheel 5 stops rotating along with the universal wheel, then the user presses the power main switch to electrify the device, then the user pours the hot water into the water inlet component 6, the hot water flows into the cooling tower 1 through the water inlet component 6, when the flow rate of the hot water reaches the preset value of the air guide mechanism 11, the air guide mechanism 11 drives the fan blades 9 to rotate, cold air generated by the rotation of the fan blades 9 is discharged through the outlet of the cooling tower 1, the heat dissipation mechanism 12 cools the steam, make steam turn into the drop of water, the drop of water flows through heat dissipation mechanism 12 and falls in cooling tower 1, and the hot water that the heat dissipation was accomplished flows through outlet pipe 8, and hot water heat dissipation is accomplished the back, and the user stops pouring hot water for air guide mechanism 11 and heat dissipation mechanism 12 stop work, the user presses the power master switch once more, cuts off the power supply with this device.

After hot water flows into water inlet assembly 6, when the flow rate of hot water reaches the preset value of water flow sensor 111, make first driving motor 112 of control module control work, first driving motor 112 output shaft drives pivot 113 and rotates, pivot 113 drives flabellum 9 and rotates, pivot 113 drives installation piece 114 and rotates, the cold wind that flabellum 9 rotated the production extracts the steam in to cooling tower 1, make steam flow through cooling tower 1 export, realize the steam extraction effect, when hot-water flow rate is less than water flow sensor 111's preset value, make first driving motor 112 stop work of control module control, pivot 113, flabellum 9 and installation piece 114 stall thereupon.

Steam gets into cooling tower 1 after, steam can waft on second heat dissipation frame 122 and first heat dissipation frame 121, the user can promote second heat dissipation frame 122, make first heat dissipation frame 121 and second heat dissipation frame 122 cool off steam, make steam convert the drop of water into, the drop of water rethread first heat dissipation frame 121 and second heat dissipation frame 122 flow down in cooling tower 1, fin 124 cools down the drop of water, make heat discharge cooling tower 1, realize fin 124 and discharge the heat effect, the drop of water heat dissipation is accomplished the back, the user stops to promote second heat dissipation frame 122.

When the rotating shaft 113 rotates, the rotating shaft 113 drives the magnetic steel 132 to rotate, when the magnetic steel 132 rotates to the position below the digital hall magnetic sensor 131, the digital hall magnetic sensor 131 sends a signal, so that the control module controls the telescopic rod of the electric push rod 134 to extend rightwards, the telescopic rod of the electric push rod 134 drives the second heat dissipation frame 122 to move rightwards, the telescopic rod of the electric push rod 134 extends rightwards for one second, the control module controls the telescopic rod of the electric push rod 134 to be static for one second, after one second, the control module controls the telescopic rod of the electric push rod 134 to be shortened leftwards, the telescopic rod of the electric push rod 134 drives the second heat dissipation frame 122 to move leftwards, after the telescopic rod of the electric push rod 134 is shortened leftwards for one second, the control module controls the telescopic rod 134 to be static, and when the magnetic steel 132 rotates to separate from the digital hall magnetic sensor 131, the control module controls the telescopic rod 134 to stop working.

When the temperature in the cooling tower 1 reaches the preset value of the temperature sensor 141, the control module controls the second driving motor 143 to work, the output shaft of the second driving motor 143 drives the first brush plate 144 to rotate, the first brush plate 144 drives the second telescopic assembly 145 to rotate, the second telescopic assembly 145 drives the second brush plate 146 to rotate, after the second brush plate 146 rotates to contact with the convex part of the cooling tower 1, the second telescopic assembly 145 shortens to drive the second brush plate 146 to move inwards, after the second brush plate 146 rotates to separate from the convex part of the cooling tower 1, the second telescopic assembly 145 extends to drive the second brush plate 146 to move outwards and backwards, the second brush plate 146 cleans the scale in the cooling tower 1 to achieve the effect of cleaning the scale by the second brush plate 146, when the temperature in the cooling tower 1 is lower than the preset value of the temperature sensor 141, the control module controls the second driving motor 143 to stop working, the first brush plate 144, the second telescoping assembly 145, and the second brush plate 146 are then deactivated.

When the temperature in cooling tower 1 is less than the temperature sensor 141 default, make control module control solenoid valve 153 work, outlet pipe 8 passageway is opened to solenoid valve 153, the back is opened to outlet pipe 8 passageway, control module control water pump 152 work, hot water after the cooling is accomplished in water pump 152 to cooling tower 1 extracts, make the hot water after the cooling is accomplished flow through outlet pipe 8, when the hot water level after the cooling is accomplished reaches level sensor 151 default in cooling tower 1, make control module control solenoid valve 153 stop work, make solenoid valve 153 close outlet pipe 8 passageway.

Leave over the steam back in cooling tower 1, steam can waft on metal screen panel 163, and metal screen panel 163 cools down steam for steam turns into the drop of water, and the drop of water drops through metal screen panel 163 and drops in cooling tower 1, and in the impurity entering steam for preventing in the air, air guide frame 162 blocks the impurity in the air.

After leaving over the incrustation scale in the cooling tower 1, when flabellum 9 rotates and produces the cold wind, the air current drives cyclic annular sponge brush 173 upward movement, and the flexible subassembly 172 of third upwards shortens, and after flabellum 9 stopped to produce cold wind, the flexible subassembly 172 of third extended downwards, and the flexible subassembly 172 of third drives cyclic annular sponge brush 173 downstream, and the incrustation scale of cyclic annular sponge brush 173 in to cooling tower 1 cleans.

While the disclosure has been described with respect to a limited number of embodiments, those skilled in the art, having benefit of this disclosure, will appreciate that various other embodiments can be devised which do not depart from the scope of the invention as disclosed herein. Accordingly, the scope of the invention should be limited only by the attached claims.

Claims

1. An energy-saving cooling tower, characterized by comprising:

the cooling tower (1) is arranged on the base (2);

the lower side of the cooling tower (1) is provided with six first fixing frames (3);

the lower sides of the six first fixing frames (3) are provided with first telescopic assemblies (4);

universal wheels (5) are rotationally arranged on the six first telescopic assemblies (4);

the cooling tower (1) is provided with a water inlet component (6), and the water inlet component (6) is arranged on the cooling tower (1);

the cooling tower (1) is provided with an air inlet pipe (7), and the air inlet pipe (7) is arranged on the cooling tower (1);

a water outlet pipe (8) is arranged on the cooling tower (1);

the cooling tower comprises an air guide mechanism (11), wherein the air guide mechanism (11) is arranged in the cooling tower (1);

the fan blades (9) are arranged on the air guide mechanism (11);

the cooling tower (1) is provided with a heat dissipation mechanism (12);

the air guide mechanism (11) comprises:

the water flow sensor (111) is arranged on the water inlet component (6);

the cooling tower comprises a first driving motor (112), wherein the first driving motor (112) is installed on the upper side inside the cooling tower (1);

the output shaft of the first driving motor (112) is connected with the rotating shaft (113), and the rotating shaft (113) is connected with the fan blades (9);

the lower side of the rotating shaft (113) is provided with the mounting block (114);

the heat dissipation mechanism (12) includes:

the upper side in the cooling tower (1) is provided with a first heat dissipation frame (121);

the second heat dissipation frame (122) is arranged on the upper side inside the cooling tower (1) in a sliding mode;

the two sides of the cooling tower (1) are respectively provided with a fixing ring (123), and the fixing rings (123) are connected with the second heat dissipation frame (122);

the cooling fin (124), the cooling tower (1) is equipped with the cooling fin (124) on the underside;

still include moving mechanism (13), moving mechanism (13) includes:

the first driving motor (112) is provided with a digital Hall magnetic sensor (131);

the magnetic steel (132) is arranged on the rotating shaft (113);

the second fixing frames (133) are arranged on two sides of the cooling tower (1);

the electric push rods (134) are mounted on the two second fixing frames (133), and telescopic rods of the electric push rods (134) are connected with the second heat dissipation frame (122);

still include clean mechanism (14), clean mechanism (14) includes:

the temperature sensor (141), the inside of the cooling tower (1) is provided with the temperature sensor (141);

the middle part of the lower side of the cooling tower (1) is provided with a third fixing frame (142);

the second driving motor (143) is mounted on the third fixing frame (142);

a first brush plate (144) is arranged on the output shaft of the second driving motor (143);

the two sides of the first brush plate (144) are provided with second telescopic assemblies (145);

the two second telescopic assemblies (145) are respectively provided with a second brush plate (146);

still including accuse valve mechanism (15), accuse valve mechanism (15) includes:

the liquid level sensor (151) is arranged at the lower side inside the cooling tower (1);

the water pump (152), the water pump (152) is installed under the cooling tower (1);

the electromagnetic valve (153) is arranged on the water outlet pipe (8);

the cooling tower is characterized by further comprising a control box (10), the control box (10) is installed on the upper side of the cooling tower (1), a switching power supply, a control module and a power module are installed in the control box (10), the switching power supply supplies power for the energy-saving cooling tower, the output end of the switching power supply is electrically connected with the power module, the power module is connected with a power main switch through a circuit, and the control module is electrically connected with the power module; the control module is connected with a DS1302 clock circuit and a 24C02 circuit; the water flow sensor (111), the digital Hall magnetic sensor (131), the temperature sensor (141) and the liquid level sensor (151) are all electrically connected with the control module, and the first driving motor (112), the second driving motor (143), the electromagnetic valve (153), the electric push rod (134) and the water pump (152) are all connected with the control module through the relay control module.

2. An energy-saving cooling tower as claimed in claim 1, further comprising an adsorption mechanism (16), wherein the adsorption mechanism (16) comprises:

the upper side of the cooling tower (1) is provided with six fourth fixing frames (161), and the number of the fourth fixing frames (161) is six;

the air guide frames (162) are connected among the six fourth fixing frames (161), and the air guide frames (162) are connected with the cooling tower (1);

the metal net covers (163) are arranged on the lower side of the air guide frame (162), and the number of the metal net covers (163) is four.

3. An energy saving cooling tower as claimed in claim 2, further comprising descaling means (17), wherein the descaling means (17) comprises:

the cooling tower comprises fixing blocks (171), wherein the fixing blocks (171) are arranged inside the cooling tower (1), and the number of the fixing blocks (171) is three;

the three fixed blocks (171) are respectively provided with a third telescopic component (172);

an annular sponge brush (173) is connected between the three third telescopic assemblies (172).