CN112068678A

CN112068678A - Big data server with good heat dissipation performance

Info

Publication number: CN112068678A
Application number: CN202010936432.9A
Authority: CN
Inventors: 刘晓明
Original assignee: Guangzhou Zhongyue Technology Co ltd
Current assignee: Guangzhou Zhongyue Technology Co ltd
Priority date: 2020-09-08
Filing date: 2020-09-08
Publication date: 2020-12-11

Abstract

The invention discloses a big data server with good heat dissipation performance, which comprises a server box body, wherein an air duct is arranged at the bottom of the server box body, an air cooler is arranged inside the air duct, and an exhaust fan is fixedly connected to the upper surface of the server box body. According to the invention, by arranging the exhaust fan, when electronic elements in the server box body are radiated, the exhaust fan is controlled to operate, hot air in the server box body is extracted through the exhaust pipe and the conical air collecting hopper and then is exhausted through the exhaust pipe, meanwhile, the air cooler is controlled to operate to convey cold air to the inside of the server box body, so that the temperature in the server box body is reduced, the water pump is controlled to synchronously operate to extract cooling water in the cooling water tank, the cooling water is repeatedly guided by circulation of the circulation water guide pipe to cool and radiate the inside of the server box body by water cooling, and the air cooling is matched to cool, so that the radiating efficiency of the inside of the server box body is improved by combining the air cooling mode and the water cooling mode, and.

Description

Big data server with good heat dissipation performance

Technical Field

The invention relates to the field of big data servers, in particular to a big data server with good heat dissipation performance.

Background

With the rapid development of the internet era, the number of network big data servers is rapidly increased, a big data server cabinet is used for placing network servers and is convenient for unified management, a server cabinet is used for assembling and installing panels, plug-in components, plug-in boxes, electronic elements, devices, mechanical parts and components to form an integral installation box, the server cabinet is composed of a frame and a cover plate, generally has a cuboid shape and is placed on the ground. It provides adaptive environment and safety protection for normal operation of electronic equipment.

The existing big data server has the following problems,

1. the background of the large data server normally works and runs uninterruptedly for a long time, so the heat dissipation performance of the installation box is very important for internal electronic elements, the existing server box body is usually completed in a fan air cooling mode during heat dissipation, the heat dissipation performance is single, the heat dissipation efficiency is low in a hot and high-temperature environment, the heat dissipation effect is poor, and the service life of the internal electronic elements is further influenced.

2. When the server box body is radiating through the air-cooled form of fan, the dust screen is generally installed to its wind channel department, in order to play dustproof effect, prevents dust to inside electronic component, but all through bolt fastening formula during the dust screen installation, because of the dust screen needs regularly to dismantle the clearance to it is comparatively inconvenient when the dismouting to lead to the dust screen.

Disclosure of Invention

The present invention has been made in an effort to provide a large data server having excellent heat dissipation properties, which can effectively solve the problems described in the background art.

In order to achieve the purpose, the invention adopts the technical scheme that:

a big data server with good heat dissipation performance comprises a server box body, wherein an air channel is arranged at the bottom of the server box body, an air cooler is arranged inside the air channel, an air exhauster is fixedly connected to the upper surface of the server box body, an air exhaust pipe is fixedly communicated with the input end of the air exhauster, an exhaust pipe is fixedly communicated with the output end of the air exhauster, the air exhaust pipe penetrates through and extends into the server box body, a conical air collecting hopper is fixedly communicated with one end of the air exhaust pipe, a cooling water tank is arranged on the left side of the server body, a water pump is arranged inside the cooling water tank, a circulating water guide pipe is fixedly communicated with the output end of the water pump, the circulating water guide pipe penetrates into and penetrates out of the server box body, one end of the circulating water guide pipe extends into the cooling water tank, and shutters are arranged on two sides, the server box comprises a server box body and is characterized in that a group of radiating fins are fixedly connected inside the server box body, a dust screen is arranged at the bottom of the air channel, side lugs are fixedly connected to two sides of the dust screen, rubber clamping blocks are fixedly connected to one sides of the side lugs, and two clamping grooves are formed in the bottom of the server box body.

Preferably, the circulating water guide pipe is wound and attached to the inner wall of the server box body and is located right above the air duct.

Preferably, a set of the heat dissipation fins is respectively located at two positions of the louver.

Preferably, a group of the heat dissipation fins is arranged in a staggered manner with the circulating water guide pipe.

Preferably, the two rubber clamping blocks extend into the two clamping grooves respectively, and the two rubber clamping blocks are in size transition fit.

Preferably, the lower surface of the server box body is fixedly connected with two mutually symmetrical block-up blocks.

Preferably, the dust screen and the air duct are tightly attached to each other, and cooling water is arranged in the cooling water tank.

Preferably, the method further comprises the following steps: the system comprises a temperature sensor, a singlechip, an alarm and an intelligent condenser;

the temperature sensor is arranged at the top end of the server box body;

the single chip microcomputer is arranged at the left end of the outer side of the server box body;

the alarm is placed at the right end of the outer side of the server box body;

the intelligent condenser is arranged at the left end of the inner side of the server box body;

the single chip microcomputer is connected with the temperature sensor, the alarm and the intelligent condenser;

the temperature sensor is used for acquiring a temperature value in the big data server after heat dissipation, and judging whether the heat dissipation performance of the big data server is good or not according to the temperature value, and the specific work flow comprises the following steps:

step 1: the temperature sensor is used for acquiring a first temperature value after heat dissipation in the server box body and a second temperature value when heat dissipation is not performed at the last moment;

step 2: the single chip microcomputer is used for acquiring a temperature difference value based on the second temperature value and the first temperature value;

meanwhile, converting the temperature difference value and a preset standard temperature difference value into a unified format, and establishing a first mapping relation between the unified format and an identifiable format;

and step 3: the single chip microcomputer is further used for judging the relation between the temperature difference value and a standard temperature difference value based on the first mapping relation;

if different fields appear in the first mapping relation, judging that the temperature difference value is smaller than or equal to the standard temperature difference value, and further determining that the heat dissipation performance of the big data server is good;

and 4, step 4: otherwise, controlling an indicator light of the alarm to flicker, and simultaneously controlling the intelligent condenser to work;

and 5: repeating the steps 1-3, and determining whether the intelligent condenser stops working or not based on the first mapping relation obtained in the repeated steps;

if the fields in the first mapping relation obtained based on the repeated steps are completely the same, the single chip microcomputer controls the intelligent condenser to stop working;

otherwise, the single chip microcomputer controls the alarm to alarm in a vibration mode, and meanwhile, the intelligent condenser continues to work until the fields in the corresponding first mapping relation are completely the same.

Preferably, the method further comprises the following steps: a computer, a humidity sensor;

the humidity sensor is arranged at the right end of the inner side of the server box body;

wherein, the computer is connected with the humidity sensor and the water pump;

humidity transducer is used for acquireing the inside humidity of server box, simultaneously, the computer is used for according to humidity judges whether to start the water pump cools down, and concrete working process includes:

the humidity sensor is used for acquiring a humidity value in the server box body;

the computer is used for comparing the humidity value with a preset humidity value,

if the humidity value is equal to or greater than the preset humidity value, the water pump is not started to cool; otherwise, calculating the current temperature value in the server box body according to the humidity value;

wherein W represents a current temperature value in the server box, η represents a heat transfer coefficient of the gas inside the server box, a represents a length of the server box, b represents a width of the server box, h represents a height of the server box, and W represents_iThe heat generated by the ith electronic component is shown, i represents the number of the electronic components in the server box body, and i is 1, 2 and 3 …; m represents the humidity enthalpy value inside the server box body, and q represents the humidity value inside the server box body;

the computer is also used for calculating the working power of the water pump according to the current temperature value in the server box body;

wherein P represents the working power of the water pump, W represents the current temperature value in the server box, ξ represents the loss coefficient of the water pump during working, r represents the average rotating speed of the water pump, h represents the working lift of the water pump, ρ represents the liquid density in the cooling water tank, D represents the impeller diameter of the water pump,

represents the inlet and outlet aperture of the water pump, h represents the working efficiency of the water pump, lg (-) represents the pair with 10 as the baseA number function;

meanwhile, calculating the working time of the water pump based on the working power of the water pump;

wherein t represents the working time of the water pump, F represents the acting force of the water pump under the action of the current working power, h represents the working lift of the water pump, and P represents the working power of the water pump;

and the computer is also used for controlling the water pump to work according to the working power in the working time.

Compared with the prior art, the invention has the following beneficial effects:

1. the big data server with good heat dissipation performance is characterized in that the exhaust fan is arranged, when electronic elements in the server box body are radiated, the exhaust fan is controlled to operate, the hot air in the server box body is exhausted through the exhaust pipe and the conical air collecting hopper, the air cooler is controlled to operate to convey cold air to the inside of the server box body, the temperature in the server box body is further reduced, the water pump is controlled to operate synchronously to extract cooling water in the cooling water tank, the cooling water is repeatedly guided by the circulation water guide pipe to cool and radiate the inside of the server box body by water cooling, and the air cooling and the water cooling are matched, so that the heat dissipation efficiency in the server box body is improved, the service life of the electronic elements in the server box body is further prolonged, under the environment of special hot high temperature, two shutters can be opened, and heat conduction is realized by matching with the heat dissipation fins, further make heat dispersion better, through setting up the dust screen, the protection of preventing dust is located to the wind channel, when the clearance need be dismantled to the collection dirt more on the dust screen, will incline the rubber fixture block on the ear hard slightly extract from the draw-in groove can, when installing the dust screen, aim at two draw-in grooves respectively with two rubber fixture blocks, accomplish the installation in the draw-in groove with strength with the card income of rubber fixture block, consequently, it is very convenient to the dismouting of dust screen, need not with the help of the appurtenance instrument is supplementary, the cleaning efficiency to the dust screen has been improved.

2. The method comprises the steps of obtaining a first temperature value after heat dissipation in a server box body and a second temperature value when heat dissipation is not conducted at the last moment through a temperature sensor, obtaining a temperature difference value more accurately, converting the temperature difference value and a preset standard temperature difference value into a unified format through a data unification algorithm, establishing a first mapping relation between the unified format and a recognizable format, and improving accuracy of data comparison.

3. The humidity sensor is used for acquiring the humidity value inside the server box body, and then the humidity value is compared with the preset humidity value accurately through the computer, so that whether the water pump is cooled down is determined rapidly, if the humidity value is equal to or larger than the preset humidity value, the water pump is not started to cool down, otherwise, the temperature value in the server box body is calculated accurately according to the humidity value, the working power of the water pump is calculated, the working time of the water pump is calculated through the working power, and then the water pump can work according to the working time and the working power of the water pump, and the safety and the reliability of the device are improved greatly.

Drawings

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is an enlarged view of the structure of FIG. 1 at A in accordance with the present invention;

FIG. 3 is a schematic side view of a blind according to the present invention;

FIG. 4 is a schematic diagram of a single-chip microcomputer control connection according to the present invention;

FIG. 5 is a schematic diagram of the computer control connection of the present invention.

In the figure: 1. a server box body; 2. an air duct; 3. an air cooler; 4. an exhaust fan; 5. an exhaust pipe; 6. an exhaust duct; 7. a conical wind collecting hopper; 8. a cooling water tank; 9. a water pump; 10. a circulating water conduit; 11. a blind window; 12. a heat dissipating fin; 13. a dust screen; 14. a lateral ear; 15. a rubber clamping block; 16. a card slot; 17. and a block for raising.

Detailed Description

In order to make the technical means, the creation characteristics, the achievement purposes and the effects of the invention easy to understand, the technical scheme of the invention is further elaborated below.

As shown in fig. 1-3, in the present embodiment, a big data server with good heat dissipation performance includes a server box 1, an air duct 2 is disposed at the bottom of the server box 1, an air cooler 3 is disposed inside the air duct 2, an air extractor 4 is fixedly connected to the upper surface of the server box 1, an input end of the air extractor 4 is fixedly communicated with an exhaust pipe 5, an output end of the air extractor 4 is fixedly communicated with an exhaust pipe 6, the exhaust pipe 5 penetrates and extends into the server box 1, one end of the exhaust pipe 5 is fixedly communicated with a tapered air collecting hopper 7, a cooling water tank 8 is disposed at the left side of the server body 1, a water pump 9 is disposed inside the cooling water tank 8, an output end of the water pump 9 is fixedly communicated with a circulating water conduit 10, the circulating water conduit 10 penetrates and extends out of the server box 1, one end of the circulating water conduit 10 extends into the cooling water tank 8, two sides, a set of radiating fins 12 is fixedly connected to the inside of the server box 1, a dust screen 13 is arranged at the bottom of the air duct 2, side lugs 14 are fixedly connected to the two sides of the dust screen 13, rubber clamping blocks 15 are fixedly connected to one sides of the two side lugs 14, and two clamping grooves 16 are formed in the bottom of the server box 1.

In this embodiment, preferably, the circulating water guide pipe 10 is wound and attached to the inner wall of the server box 1 and located right above the air duct 2, the circulating water guide pipe 10 is reasonably arranged in the server box 1, and meanwhile, the circulating water guide pipe 10 is further cooled by matching with air cooling, so that the heat dissipation effect is improved.

In this embodiment, preferably, a set of heat dissipation fins 12 are respectively located at the two louvers 11, and when the louvers 11 are opened, the heat flow inside the server box 1 is guided out by the heat conduction of the heat dissipation fins 12.

In this embodiment, preferably, the group of heat dissipation fins 12 are disposed in a staggered manner with respect to the circulation water conduit 10, so as to improve the rationality of the internal structural layout of the server box 1.

In this embodiment, it is preferred, two rubber fixture blocks 15 extend to the inside of two draw-in grooves 16 respectively, and both size transition fit, have improved the stability to after dust screen 13 installs, simultaneously through the setting of rubber material, are convenient for extract the fixture block from draw-in groove 16.

In this embodiment, preferably, the lower fixed surface of the server box 1 is connected with two mutually symmetrical block cushions 17, and the block cushions 17 are arranged to support the bottom of the server box 1 conveniently, and simultaneously make somebody a mere figurehead the bottom of the server box, so that the air cooler 3 blows air to the inside of the server box 1.

In this embodiment, preferably, the dust screen 13 and the air duct 2 are closely attached to each other, and the cooling water is provided inside the cooling water tank 8, so that the dust-proof effect of the dust screen 13 on the air duct 2 is improved.

When the server is used, the exhaust fan 4 is arranged, when electronic elements in the server box body 1 are radiated, the exhaust fan 4 is controlled to operate, hot air in the server box body 1 is exhausted through the exhaust pipe 5 and the conical air collecting hopper 7, the cold air is simultaneously controlled to operate to convey cold air to the inside of the server box body 1, so that the temperature in the server box body 1 is reduced, the water pump 9 is controlled to synchronously operate, cooling water in the cooling water tank 8 is extracted, circulating flow guide of the circulating water guide pipe 10 is repeatedly carried out, water cooling and heat radiation are carried out on the inside of the server box body 1, air cooling and water cooling are matched, the heat radiation efficiency of the inside of the server box body 1 is improved through combination of air cooling and water cooling, the service life of the electronic elements in the server is prolonged, and under the special hot and high-temperature environment, still can be through opening two shutter 11, and through the heat conduction of cooperation radiating fin 12, further make heat dispersion better, through setting up dust screen 13, to wind channel 2 department dustproof protection, when dust collection more needs dismantle the clearance on dust screen 13, will incline the rubber fixture block 15 on the ear 14 slightly hard and extract from draw-in groove 16 can, with the clearance when installing dust screen 13, aim at two draw-in grooves 16 respectively with two rubber fixture blocks 15, the installation is accomplished in the draw-in groove 16 is blocked into to rubber fixture block 15 card with strength, consequently, the dismouting to dust screen 13 is very convenient, need not with the help of external force instrument is supplementary, the cleaning efficiency to dust screen 13 has been improved.

The present invention provides a big data server with good heat dissipation, as shown in fig. 4, further comprising: the system comprises a temperature sensor, a singlechip, an alarm and an intelligent condenser;

the temperature sensor is arranged at the top end of the server box body 1;

the single chip microcomputer is arranged at the left end of the outer side of the server box body 1;

the alarm is placed at the right end of the outer side of the server box body 1;

the intelligent condenser is arranged at the left end of the inner side of the server box body 1;

step 1: the temperature sensor is used for acquiring a first temperature value after heat dissipation inside the server box body 1 and a second temperature value when heat dissipation is not performed at the last moment;

In this embodiment, the unified format may be that the environment in which the method description data of the system is compared is consistent.

In this embodiment, the recognizable format may be a format that is recognizable for the data, and the recognizable format includes a uniform format.

In this embodiment, the different field may be a data field with the unified format removed within the range of recognizable formats.

The working principle and the beneficial effects of the technical scheme are as follows: the method comprises the steps of obtaining a first temperature value after heat dissipation inside a server box body 1 and a second temperature value when heat dissipation is not conducted at the last moment through a temperature sensor, obtaining a temperature difference value more accurately, converting the temperature difference value and a preset standard temperature difference value into a uniform format through a data uniform algorithm, establishing a first mapping relation between the uniform format and a recognizable format, and improving accuracy of data comparison.

The present invention provides a big data server with good heat dissipation, as shown in fig. 5, further comprising: a computer, a humidity sensor;

the humidity sensor is arranged at the right end of the inner side of the server box body 1;

wherein, the computer is connected with the humidity sensor and the water pump 9;

humidity transducer is used for acquireing the inside humidity of server box 1, simultaneously, the computer is used for the basis humidity judges whether to start water pump 9 cools down, and concrete working process includes:

the humidity sensor is used for acquiring a humidity value inside the server box body 1;

if the humidity value is equal to or greater than the preset humidity value, the water pump 9 is not started to cool; otherwise, calculating the current temperature value in the server box body 1 according to the humidity value;

wherein W represents a current temperature value in the server casing 1, η represents a heat transfer coefficient of the gas inside the server casing 1, a represents a length of the server casing 1, b represents a width of the server casing 1, h represents a height of the server casing 1, and W represents a heat transfer coefficient of the gas inside the server casing 1_iRepresents the amount of heat generated by the ith electronic component, i represents the number of electronic components in the server casing 1, and i is 1, 2, 3 …; m represents the humidity enthalpy value inside the server box 1, q represents the humidity value inside the server box 1;

the computer is also used for calculating the working power of the water pump 9 according to the current temperature value in the server box body 1;

wherein, P represents the working power of the water pump 9, W represents the current temperature value in the server box 1, ξ represents the loss coefficient of the water pump 9 during working, r represents the average rotating speed of the water pump 9, h represents the working lift of the water pump 9, ρ represents the liquid density in the cooling water tank 8, D represents the impeller diameter of the water pump 9,

the inlet and outlet caliber of the water pump 9 is represented, h represents the working efficiency of the water pump 9, and lg (·) represents a logarithmic function with a base 10 as a base;

meanwhile, the working time of the water pump 9 is calculated based on the working power of the water pump 9;

wherein t represents the working time of the water pump 9, E represents the acting force of the water pump 9 under the action of the current working power, h represents the working lift of the water pump 9, and P represents the working power of the water pump 9;

and the computer is also used for controlling the water pump 9 to work according to the working power in the working time.

In this embodiment, the loss factor may be a loss generated by friction or the like when the water pump 9 operates.

The working principle and the beneficial effects of the technical scheme are as follows: the humidity sensor is used for acquiring the humidity value inside the server box body 1, and then the humidity value is compared with the preset humidity value accurately through the computer, so that whether the water pump 9 is cooled down is determined rapidly, if the humidity value is equal to or larger than the preset humidity value, the water pump 9 is not started, otherwise, the temperature value inside the server box body 1 is calculated accurately according to the humidity value, the working power of the water pump 9 is calculated, the working time of the water pump 9 is calculated through the working power, and then the device can work according to the working time and the working power of the water pump 9, and therefore the safety and the reliability of the device are improved greatly.

The foregoing shows and describes the general principles and broad features of the present invention and advantages thereof. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, which are described in the specification and illustrated only to illustrate the principle of the present invention, but that various changes and modifications may be made therein without departing from the spirit and scope of the present invention, which fall within the scope of the invention as claimed. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims

1. The utility model provides a good heat dissipation's big data server which characterized in that: the server box comprises a server box body (1), wherein an air channel (2) is arranged at the bottom of the server box body (1), an air cooler (3) is arranged inside the air channel (2), an air exhauster (4) is fixedly connected to the upper surface of the server box body (1), an air exhaust pipe (5) is fixedly communicated with the input end of the air exhauster (4), an exhaust pipe (6) is fixedly communicated with the output end of the air exhauster (4), the air exhaust pipe (5) penetrates through and extends into the server box body (1), a conical air collecting hopper (7) is fixedly communicated with one end of the air exhaust pipe (5), a cooling water tank (8) is arranged on the left side of the server body (1), a water pump (9) is arranged inside the cooling water tank (8), a circulating water guide pipe (10) is fixedly communicated with the output end of the water pump (9), and the circulating water guide pipe (10) penetrates through the server box body (1), the one end of circulation aqueduct (10) extends to the inside of cooling water tank (8), the both sides of server box (1) all are provided with shutter (11), a set of radiating fin (12) of inside fixedly connected with of server box (1), the bottom in wind channel (2) is provided with dust screen (13), the equal fixedly connected with side ear (14) in both sides of dust screen (13), two the equal fixedly connected with rubber fixture block (15) in one side of side ear (14), two draw-in grooves (16) have been seted up to the bottom of server box (1).

2. The big data server with good heat dissipation performance of claim 1, wherein: the circulating water guide pipe (10) is wound and attached to the inner wall of the server box body (1) and is located right above the air duct (2).

3. The big data server with good heat dissipation performance of claim 1, wherein: and a group of radiating fins (12) are respectively positioned at the positions of the two shutters (11).

4. The big data server with good heat dissipation performance of claim 1, wherein: and the group of radiating fins (12) are arranged in a staggered manner with the circulating water guide pipe (10).

5. The big data server with good heat dissipation performance of claim 1, wherein: the two rubber clamping blocks (15) respectively extend into the two clamping grooves (16), and the two rubber clamping blocks are in size transition fit.

6. The big data server with good heat dissipation performance of claim 1, wherein: the lower surface of the server box body (1) is fixedly connected with two mutually symmetrical heightening blocks (17).

7. The big data server with good heat dissipation performance of claim 1, wherein: the dustproof net (13) and the air duct (2) are tightly attached to each other, and cooling water is arranged in the cooling water tank (8).

8. The big data server with good heat dissipation performance of claim 1, further comprising: the system comprises a temperature sensor, a singlechip, an alarm and an intelligent condenser;

the temperature sensor is arranged at the top end of the server box body (1);

the single chip microcomputer is arranged at the left end of the outer side of the server box body (1);

the alarm is placed at the right end of the outer side of the server box body (1);

the intelligent condenser is arranged at the left end of the inner side of the server box body (1);

step 1: the temperature sensor is used for acquiring a first temperature value after heat dissipation inside the server box body (1) and a second temperature value when heat dissipation is not performed at the last moment;

9. The big data server with good heat dissipation performance of claim 1, further comprising: a computer, a humidity sensor;

the humidity sensor is arranged at the right end of the inner side of the server box body (1);

wherein, the computer is connected with the humidity sensor and the water pump (9);

the humidity sensor is used for acquiring the humidity inside the server box body (1), meanwhile, the computer is used for judging whether the water pump (9) is started to cool according to the humidity, and the specific working process comprises the following steps:

the humidity sensor is used for acquiring a humidity value inside the server box body (1);

if the humidity value is equal to or greater than the preset humidity value, the water pump (9) is not started to cool;

otherwise, calculating the current temperature value in the server box body (1) according to the humidity value;

wherein W represents a current temperature value in the server box (1), η represents a heat transfer coefficient of the gas inside the server box (1), a represents a length of the server box (1), b represents a width of the server box (1), h represents a height of the server box (1), and W represents a temperature value in the server box (1), and_irepresents the heat generated by the ith electronic component, i represents the number of the electronic components in the server box body (1), and i is 1, 2 and 3 …; m represents the humidity enthalpy value inside the server box body (1), and q represents the humidity value inside the server box body (1);

the computer is also used for calculating the working power of the water pump (9) according to the current temperature value in the server box body (1);

wherein P represents the working power of the water pump (9), W represents the current temperature value in the server box body (1), xi represents the loss coefficient of the water pump (9) in working, r represents the average rotating speed of the water pump (9), h represents the working lift of the water pump (9), P represents the liquid density in the cooling water tank (8), and D represents the impeller diameter of the water pump (9),

the inlet and outlet caliber of the water pump (9) is represented, h represents the working efficiency of the water pump (9), and lg (·) represents a logarithmic function with a base 10 as a base;

meanwhile, the working time of the water pump (9) is calculated based on the working power of the water pump (9);

wherein t represents the working time of the water pump (9), F represents the acting force of the water pump (9) under the action of the current working power, h represents the working lift of the water pump (9), and P represents the working power of the water pump (9);

and the computer is also used for controlling the water pump (9) to work according to the working power in the working time.