CN110206348A - A kind of Intelligentized machine room controling adjustment device - Google Patents

Abstract

The invention discloses an intelligent machine room control and adjustment device, which comprises a machine room box body, a component support plate is fixedly installed in the machine room box body, a drainage cavity is formed between the component support plate and the inside of the machine room box body, and a detection box body is arranged outside the machine room box body , the machine room box is located on one side of the detection box, and a water storage tank is placed. The cavity in the water storage tank and the cavity in the detection box are connected through a suction pipe, and a frequency conversion water pump is installed on the suction pipe; when water accumulates in the machine room, First of all, the accumulated water enters the drainage cavity, which will not affect the equipment placed on the upper part of the component support plate. The frequency conversion water pump pumps the accumulated water in the drainage cavity into the water storage tank through the suction pipe, and timely removes the accumulated water entering the machine room. Discharge and reduce power consumption. During this process, the equipment does not move all the time, which ensures the stability of the wiring between the equipment, and can also quickly recede the accumulated water in the equipment room.

Description

An intelligent computer room control and adjustment device

technical field

The invention relates to the neighborhood of a computer room, in particular to an intelligent computer room control and adjustment device.

Background technique

Big data refers to a collection of data that cannot be captured, managed, and processed by conventional software tools within a certain period of time. It requires a new processing model to have stronger decision-making power, insight and discovery, and process optimization capabilities to adapt to massive and high growth rates. and diverse information assets.

When there is a lot of rain, it will cause water to enter the central computer room. If water enters the central computer room, it may cause some important equipment to be soaked in water, resulting in equipment damage and economic losses.

Existing patents, such as patent application number CN201611183284.8 for an anti-bubble device for important equipment in a big data center computer room, patent application number CN201611029212.8 for a waterproof base for important equipment in an automated operation and maintenance computer room, patent application number CN201611183342.7 is an anti-immersion protection device for equipment in a large data center computer room. When water is found in the computer room, the above-mentioned patents all prevent the equipment in the fixed box from entering the computer room by lifting the entire fixed box where the equipment is placed. After the accumulated water inside recedes naturally, put down the fixed box again. In this way, the equipment can be prevented from being flooded when the equipment room is flooded, but there are the following defects:

1. When there is a lot of rain, when water is found in the machine room, the entire fixed box where the equipment is placed is lifted to avoid water ingress of the equipment in the fixed box. During the lifting process, the power consumption is relatively large;

2. During the lifting process, it is easy to cause the wiring between the equipment to be unstable, resulting in abnormal operation of the equipment;

3. After hoisting, wait for the accumulated water in the computer room to recede naturally, and the water in the computer room will recede slowly.

Contents of the invention

The purpose of the present invention is to provide an intelligent computer room control and adjustment device. When water accumulates in the machine room, the accumulated water will first enter the drainage cavity without affecting the equipment placed on the upper part of the component support plate. The frequency conversion water pump will drain the water through the suction pipe. The accumulated water in the cavity is pumped into the water storage tank, and the accumulated water entering the machine room is discharged in time to reduce power consumption. During this process, the equipment does not move all the time, ensuring the stability of the wiring between the equipment and The accumulated water in the computer room can be receded quickly.

The purpose of the present invention can be achieved through the following technical solutions:

An intelligent machine room control and adjustment device, comprising a machine room box, characterized in that a component support plate is fixedly installed in the machine room box, the width of the component support plate is smaller than the width of the machine room box, and the distance between the component support plate and the inside of the machine room box A drainage chamber is formed between them, and at least one lower drain hole is opened on the element support plate.

The side wall of the box body of the machine room is provided with a drainage groove connected with the drainage cavity, and a detection box is arranged outside the drainage groove, and the inside of the detection box is connected with the drainage groove. A floating block is arranged in the detection box, and the upper end of the floating block is fixed and installed with a slide. The rod and the slide rod run through the detection box;

A switch installation strip is fixedly installed on the top of the detection box, wherein the switch installation strip is located on one side of the slide bar and is sequentially installed with a first pressure sensor, a second pressure sensor and a third pressure sensor.

An extruding seat is fixedly installed on the top of the slide bar, and the extruding seat is located on one side of the switch installation bar to be provided with symmetrically distributed telescopic rods.

The box body of the machine room is located on one side of the detection box, and a water storage tank is placed. The top of the water storage tank is higher than the top of the box body of the machine room. A frequency conversion water pump is installed, and the frequency conversion water pump is fixedly installed on the top of the water storage tank.

A drain port is fixedly installed on the water storage tank, an electric valve is installed in the drain port, an outer drain pipe is fixedly installed in the drain port, and a water level sensor is installed in the water storage tank.

Further, the bottom of the cavity inside the detection box is lower than the bottom of the drainage cavity.

Further, a filter plate is fixedly installed on the drain tank, and filter holes are opened in an array on the filter plate.

Further, the nozzle of the suction pipe located in the detection box is located at the bottom end of the cavity inside the detection box.

Further, symmetrically distributed support blocks are fixedly installed on the back side of the machine room box, and a main cooling pipe is fixedly installed on the supporting block. One end of the main cooling pipe is closed, and the other end communicates with the inner cavity of the water storage tank.

The cooling main pipeline is provided with main pipeline interfaces arranged in an array, and on-off valves are fixedly installed on the main pipeline interfaces.

Cooling units are fixedly installed on both sides of the equipment in the box body of the machine room, and the cooling unit is fixedly connected to the main pipeline interface through a water pipe joint.

Further, the cooling unit includes a cooling support base, a cooling pipe and a water pipe, wherein the cooling support base is fixedly installed in the machine room box through bolts, and the upper end of the cooling support base is provided with fixed blocks distributed in an array, and the upper ends of the fixed blocks are fixedly installed with Cooling pipes distributed in an array, among which the cooling pipes are ring-shaped, and the cooling pipes are connected through connecting pipes, and the cooling pipes located outside are connected with water pipes, which run through the machine room box, and the water pipes are fixedly connected to the main pipe interface through water pipe joints .

Further, a condensed water discharge channel is fixedly installed on the fixed block, wherein the condensed water discharge channel is located directly below the cooling pipe.

Further, the inner wall of the cooling tube is provided with a wiring board, and the wiring board is provided with an array of wiring holes.

Further, the upper end of the machine room box is fixedly equipped with an air inlet bin, and an air inlet is opened on the back side of the air inlet bin, and an air inlet slot connected with the inner cavity of the machine room box is opened in the air inlet bin, and the air inlet slot is provided on both sides. The symmetrically distributed slide rails are slidably connected with a blower mounting seat, and a blower fan is fixedly installed on the blower mounting seat.

A threaded rod is installed in the air inlet chamber, wherein the threaded rod is connected to the side wall of the air inlet chamber in rotation, the threaded rod runs through the blower mounting seat, and the threaded rod and the blower mounting seat are connected through thread fit, and one end of the threaded rod is fixedly installed with a motor , wherein the output end of the motor is fixedly connected with the threaded rod, and the motor is fixedly installed on the air inlet chamber.

Further, an exhaust hole is opened at the lower end of the machine room box away from the detection box, and an exhaust motor is fixedly installed at the exhaust hole.

The upper end of the back side of the machine room box is provided with symmetrically distributed moisture discharge holes, a moisture exhaust fan is fixedly installed at the moisture discharge holes, and a humidity sensor is installed in the machine room box body.

Beneficial effects of the present invention:

1. In the present invention, when water accumulates in the machine room, the accumulated water first enters the drainage cavity, which will not affect the equipment placed on the upper part of the element support plate. The frequency conversion water pump pumps the accumulated water in the drainage cavity into the water storage tank through the suction pipe In the computer room, the accumulated water in the computer room is discharged in time to reduce power consumption. During this process, the equipment does not move all the time, which ensures the stability of the wiring between the equipment, and can also quickly remove the accumulated water in the computer room. recede;

2. The present invention uses the principle of the connecting device, the accumulated water in the water storage tank enters the cooling pipe, and the accumulated water in the cooling pipe absorbs the heat around the equipment, thereby cooling the equipment. This cooling method is compared with traditional fans or air conditioners. Cool down and save energy;

3. The present invention moves the blower motor mounting seat along the slide rails to move the blower directly above the high-heating equipment to perform fixed-point heat dissipation to speed up the heat dissipation of high-heating equipment.

Description of drawings

The present invention will be further described below in conjunction with the accompanying drawings.

Fig. 1 is a structural schematic diagram of an intelligent machine room control and adjustment device of the present invention;

Fig. 2 is a partial structure schematic diagram of the present invention;

Fig. 3 is a structural schematic diagram of different viewing angles of the present invention;

Fig. 4 is the schematic diagram of the enlarged structure of place A of the present invention;

Fig. 5 is a schematic diagram of a partial structure of the present invention;

Fig. 6 is a schematic diagram of enlarged structure at B of the present invention;

Fig. 7 is a schematic structural diagram of different viewing angles of the present invention;

Fig. 8 is a schematic diagram of a partial structure of the present invention.

Detailed ways

The following will clearly and completely describe the technical solutions in the embodiments of the present invention with reference to the accompanying drawings in the embodiments of the present invention. Obviously, the described embodiments are only some, not all, embodiments of the present invention. Based on the embodiments of the present invention, all other embodiments obtained by persons of ordinary skill in the art without creative efforts fall within the protection scope of the present invention.

In describing the present invention, it is to be understood that the terms "opening", "upper", "lower", "thickness", "top", "middle", "length", "inner", "surrounding" etc. Indicating orientation or positional relationship is only for the convenience of describing the present invention and simplifying the description, and does not indicate or imply that the components or elements referred to must have a specific orientation, be constructed and operated in a specific orientation, and therefore cannot be construed as limiting the present invention .

As shown in Figure 1, an intelligent computer room control and adjustment device includes a computer room box 1, a component support plate 11 is fixedly installed in the machine room box 1, the width of the component support plate 11 is smaller than the width of the machine room box 1, and the component support plate 11 and the inner side of the machine room box body 1 form a drainage cavity 12, and at least one lower drain hole 111 is opened on the component support plate 11; when in use, the equipment is installed on the upper end of the component support plate 11, when the machine room enters water, the accumulated water first Accumulated in the drainage cavity 12, during the next process, the accumulated water at the upper end of the element support plate 11 is discharged into the drainage cavity 12 through the lower drain hole, so as to avoid accumulation of accumulated water on the element support plate 11.

As shown in Figure 3 and Figure 6, the side wall of the machine room box 1 is provided with a drainage groove 121 communicating with the drainage chamber 12, and the outside of the drainage groove 121 is provided with a detection box 2, and the inside of the detection box 2 is connected with the drainage groove 121, and the detection The box body 2 is provided with a floating block 21, and the upper end of the floating block 21 is fixedly installed with a slide bar 22, and the slide bar 22 runs through the detection box body 2; when in use, when water accumulation occurs in the drainage chamber 12, the accumulated water in the drainage chamber 12 will be discharged from the drainage chamber 12. The water tank 121 is discharged into the detection box 2. At this time, the floating block 21 floats on the upper end of the accumulated water in the detection box 2, and changes with the height of the accumulated water in the detection box 2. At the same time, the floating block 21 drives the slide bar 22 Moving up and down.

The bottom of the inner cavity of the detection box 2 is lower than the bottom of the drainage chamber 12 , and all accumulated water in the drainage chamber 12 can enter the detection box 2 from the drainage groove 121 .

A filter plate 122 is fixedly installed on the drain tank 121, and filter holes distributed in an array are arranged on the filter plate 122; when the accumulated water in the drain chamber 12 is discharged from the drain tank 121 to the detection box 2, the filtration on the filter plate 122 The holes filter the stagnant water to prevent sundries from entering the detection box body 2 .

As shown in Figure 3 and Figure 4, the top of the detection box 2 is fixedly installed with a switch installation bar 3, wherein the switch installation bar 3 is located on the side of the slide bar 22, and the first pressure sensor 32 and the second pressure sensor are installed sequentially from bottom to top. 33 and the third pressure sensor 34; Simultaneously, the extruding seat 34 is fixedly installed on the top of the slide bar 22, and the extruding seat 34 is positioned at the side of the switch installation bar 3 and is provided with a symmetrically distributed telescopic rod 35, and the top of the telescopic rod 35 is provided with an extruding Block 36, extruding spring 37 is sleeved on telescoping rod 35; During use, extruding spring 37 diastole makes extruding block 36 extrude switch installation bar 3 all the time, when extruding block 36 extrudes to first pressure sensor 32, the first When the second pressure sensor 33 or the third pressure sensor 34 is used, the first pressure sensor 32 , the second pressure sensor 33 or the third pressure sensor 34 generates pressure induction at this moment.

When the extruding block 36 is in contact with the first pressure sensor 32, the bottom of the floating block 21 is attached to the bottom of the cavity in the detection box 2. During this process, the first pressure sensor 32 generates pressure induction, and then As accumulated water enters the detection box 2, the height of the accumulated water gradually increases, and the extruding block 36 gradually breaks away from the first pressure sensor 32 along with the height of the accumulated water, and slides to the second pressure sensor 33 and the third pressure sensor 34 in sequence.

The machine room box 1 is located on one side of the detection box 2, and a water storage tank 4 is placed. The top of the water storage tank 4 is higher than the top of the machine room box 1. The water pipe 41 is connected, the water pump 41 is equipped with a frequency conversion water pump 42, and the frequency conversion water pump 42 is fixedly installed on the top of the water storage tank 4; the frequency conversion water pump 42 is started, and the frequency conversion water pump 42 pumps the accumulated water in the detection box 2 into the water tank through the water suction pipe 41. In the water storage tank 4, the accumulated water in the machine room box 1 is recovered.

The mouth of the suction pipe 41 located in the detection box 2 is located at the bottom of the inner cavity of the detection box 2 to ensure that the frequency conversion water pump 42 will completely extract the accumulated water in the detection box 2 .

When in use, when the first pressure sensor 32 generates pressure induction, the first pressure sensor 32 transmits the pressure induction signal to the controller, and the controller detects whether the frequency conversion water pump 42 is turned on. If the frequency conversion water pump 42 is on, the controller turns off the frequency conversion water pump 42. The water pump 42, if the variable frequency water pump 42 is in the closed state, it will not be processed;

When the accumulated water enters the machine room box 1, the accumulated water in the detection box 2 gradually rises until the extrusion block 36 is squeezed to the second pressure sensor 33, and when the second pressure sensor 33 generates pressure induction, the first The second pressure sensor 33 transmits the pressure sensing signal to the controller, and the controller turns on the frequency conversion water pump 42, and the frequency conversion water pump 42 pumps the accumulated water in the detection box 2 into the water storage tank 4 with a small displacement. The speed of accumulated water in box 1 of the machine room is less than the discharge volume of variable frequency water pump 42. At this time, the height of the accumulated water in detection box 2 is lowered. When the first pressure sensor 32 contacts, the controller closes the frequency conversion water pump 42 at this time, and the accumulated water in the corresponding drainage chamber 12 is completely discharged; At this time, the height of the water level in the detection box 2 continues to rise until the extrusion block 36 is squeezed to the third pressure sensor 34. When the third pressure sensor 34 generates pressure induction, the third pressure sensor 34 will send the pressure induction signal Transmission to the controller, the controller controls the output frequency of the variable frequency water pump 42, so that the variable frequency water pump 42 outputs the maximum frequency, and the water accumulated in the detection box 2 is forcefully drawn out. When 36 is re-extruded to the second pressure sensor 33, the controller controls the frequency conversion water pump 42 to switch to small displacement pumping; avoiding to drain water by forcefully pumping out the frequency conversion water pump 42 all the time, increasing energy consumption.

A drain port 43 is fixedly installed on the water storage tank 4, and an electric valve is installed in the drain port 43. The electric valve opens or closes the drain port 43, and an outer drain pipe is fixedly installed in the drain port 43. 44. A water level sensor is installed in the water storage tank 4. The water level sensor detects the water level in the water storage tank 4. When the water level in the water storage tank 4 is close to the top of the inner cavity of the water storage tank 4, the controller controls the electric valve to drain water. The mouth 43 is opened, and now the accumulated water in the water storage tank 4 is discharged into the outer drain pipe 44 through the drain port 43, and the outer drain pipe 44 discharges the accumulated water into the sewer; when the water level in the water storage tank 4 is lower than When the machine room box body 1 is at the top, the controller controls the electric valve to close the drain port 43 .

As shown in Figure 7, symmetrically distributed support blocks 13 are fixedly installed on the back side of the machine room box 1, and the main cooling pipe 5 is fixedly installed on the supporting block 13. One end of the main cooling pipe 5 is closed, and the other end is connected to the inner cavity of the water storage tank 4 Connected, at this moment, the accumulated water in the water storage tank 4 enters in the cooling main pipeline 5.

As shown in FIG. 8 , main pipeline interfaces 51 are arranged in an array on the cooling main pipeline 5 , and on-off valves 52 are fixedly installed on the main pipeline interfaces 51 .

Cooling units 6 are fixedly installed on both sides of the equipment in the machine room box 1 , and the cooling units 6 are fixedly connected to the main pipeline interface 51 through the water pipe joint 53 .

As shown in Figure 8, the cooling unit 6 includes a cooling support base 61, a cooling pipe 62, and a water pipe 63, wherein the cooling support base 61 is fixedly installed in the machine room box 1 by bolts, and the upper end of the cooling support base 61 is provided with an array of fixed Block 64, the upper end of the fixed block 64 is fixedly equipped with cooling pipes 62 distributed in arrays, wherein the cooling pipes 62 are annular, and the cooling pipes 62 are communicated through the connecting pipes 65, and the cooling pipes 62 located on the outside are connected with water pipes 63, and the water pipes 63 runs through the machine room box 1, wherein the water pipe 63 is fixedly connected with the main pipe interface 51 through the water pipe joint 53; After the pipe interface 51 is fixedly connected, the on-off valve 52 is manually opened. At this time, through the principle of the connector, the accumulated water in the water storage tank 4 enters the cooling pipe 62, and the heat around the equipment is absorbed by the accumulated water in the cooling pipe 62. , so as to cool down the equipment, because the accumulated water in the cooling pipe 62 and the accumulated water in the water storage tank 4 are kept connected at all times, so the heat absorbed by the accumulated water in the cooling pipe 62 is quickly transferred to the water storage tank 4, and the water is stored The accumulated water in the case 4 quickly radiates heat to the outside until returning to normal temperature.

A condensed water discharge channel 66 is fixedly installed on the fixed block 64, wherein the condensed water discharge channel 66 is located directly below the cooling pipe 62; In the water discharge channel 66 , the condensed water discharge channel 66 discharges the condensed water into the drain chamber 12 to prevent the condensed water from accumulating on the upper end of the component support plate 11 and thereby affecting the equipment.

The inner wall of the cooling pipe 62 is provided with a wiring board 67, and the wiring board 67 is provided with an array of wiring holes. When the equipment in the machine room box 1 needs to be wired with each other, the connecting wires are routed through the wiring holes to prevent the connecting wires from directly contacting with each other. The cooling pipes 62 are attached to each other, causing condensed water to flow to the device interface along with the connecting wires, causing damage to the device.

As shown in Figure 7 and Figure 2, the upper end of the machine room box 1 is fixedly equipped with an air inlet bin 7, and the back side of the air inlet bin 7 is provided with an air inlet 71, and the air inlet bin 7 is provided with a hole communicating with the inner cavity of the machine room box 1. Air inlet groove 72, air inlet groove 72 both sides are provided with the slide rail 73 of symmetrical distribution, slide rail 73 is connected with blower mount 74, and blower fan 75 is fixedly installed on the blower mount 74; The blower fan 75 blows air to cool down the inside of the machine room cabinet 1 .

Threaded rod 76 is installed in the air inlet bin 7, wherein the threaded rod 76 is connected with the side wall of the air inlet bin 7 rotatably, the threaded rod 76 runs through the blower mounting seat 74, and is connected by thread fit between the threaded rod 76 and the blower mounting seat 74, and the threaded rod 76 is connected with the air blower mounting seat 74. Rod 76 one end is fixedly installed with motor 77, and wherein motor 77 output ends are fixedly connected with threaded rod 76, and motor 77 is fixedly installed on the air inlet bin 7; The machine mounting base moves along the slide rail 73, and the air blower is moved to directly above the high-heating equipment to perform fixed-point heat dissipation to accelerate the heat dissipation of the high-heating equipment.

There is an exhaust hole 14 at the lower end of the side of the machine room box 1 away from the detection box 2, and an exhaust motor 141 is fixedly installed at the exhaust hole 14, and the exhaust motor 141 exhausts the inner cavity of the machine room box 1, so that the machine room box Air pressure balance is maintained in the body 1 .

There are symmetrically distributed moisture discharge holes 15 at the upper end of the back side of the computer room cabinet 1, and a moisture discharge fan 151 is fixedly installed at the moisture discharge holes 15, and a humidity sensor is installed in the computer room cabinet 1, and the humidity sensor controls the humidity in the computer room cabinet 1. To detect, when the humidity in the computer room cabinet 1 exceeds the set value, the humidity sensor transmits the signal to the controller, and the controller controls the dehumidification fan 151 to start the dehumidification fan 151, and the dehumidification fan 151 controls the computer room cabinet. 1 to discharge the moisture inside.

In the description of this specification, descriptions with reference to the terms "one embodiment", "example", "specific example" and the like mean that the specific features, structures, materials or characteristics described in conjunction with the embodiment or example are included in at least one embodiment of the present invention. In an embodiment or example. In this specification, schematic representations of the above terms do not necessarily refer to the same embodiment or example. Furthermore, the specific features, structures, materials or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

The basic principles, main features and advantages of the present invention have been shown and described above. Those skilled in the industry should understand that the present invention is not limited by the above-mentioned embodiments. What are described in the above-mentioned embodiments and the description only illustrate the principle of the present invention. Without departing from the spirit and scope of the present invention, the present invention will also have Variations and improvements are possible, which fall within the scope of the claimed invention.

Claims (10)

1. An intelligent machine room control and adjustment device, comprising a machine room box (1), is characterized in that, an element support plate (11) is fixedly installed in the machine room box (1), and the width of the element support plate (11) Smaller than the width of the machine room box (1), a drainage cavity (12) is formed between the component support plate (11) and the inner side of the machine room box (1), and at least one lower drain hole (111) is opened on the component support plate (11); The side wall of the machine room box (1) is provided with a drainage groove (121) communicating with the drainage cavity (12), and a detection box (2) is arranged on the outside of the drainage groove (121), and the inside of the detection box (2) is connected to the drainage chamber (12). The water tank (121) is connected, and the detection box (2) is provided with a floating block (21), and the upper end of the floating block (21) is fixedly installed with a slide bar (22), and the slide bar (22) runs through the detection box (2); The top of the detection box (2) is fixedly installed with a switch installation strip (3), wherein the switch installation strip (3) is located on the side of the slide bar (22) and is sequentially installed with the first pressure sensor (32), the second Two pressure sensors (33) and the third pressure sensor (34); An extruding seat (34) is fixedly installed on the top of the slide bar (22), and the extruding seat (34) is located at the side of the switch mounting strip (3) and is provided with symmetrically distributed telescopic rods (35), and the top of the telescopic rod (35) An extruding block (36) is provided, and an extruding spring (37) is sheathed on the telescopic rod (35); The machine room box (1) is located on one side of the detection box (2) and a water storage tank (4) is placed, the top of the water storage tank (4) is higher than the top of the machine room box (1), and the inside of the water storage tank (4) The mold cavity and the inner mold cavity of the detection box (2) are connected through a water pump (41), and a frequency conversion water pump (42) is installed on the water suction pipe (41), and the frequency conversion water pump (42) is fixedly installed in the water storage tank (4) top; The water storage tank (4) is equipped with a drain port (43) fixedly installed on the water storage tank (4), an electric valve is installed in the drain port (43), and an external drainage port is fixedly installed in the drain port (43). Pipe (44), a water level sensor is installed in the water storage tank (4). 2. An intelligent machine room control and adjustment device according to claim 1, characterized in that, the bottom of the cavity inside the detection box (2) is lower than the bottom of the drainage cavity (12). 3. An intelligent machine room control and adjustment device according to claim 1, characterized in that, a filter plate (122) is fixedly installed on the drainage tank (121), and an array of filter plates (122) is arranged on the filter plate (122). hole. 4. An intelligent computer room control and adjustment device according to claim 1, characterized in that, the mouth of the suction pipe (41) located in the detection box (2) is located in the inner cavity of the detection box (2) bottom end. 5. An intelligent computer room control and adjustment device according to claim 1, characterized in that symmetrically distributed support blocks (13) are fixedly installed on the back side of the machine room box (1), and on the support block (13) A cooling main pipeline (5) is fixedly installed, one end of the cooling main pipeline (5) is closed, and the other end communicates with the inner cavity of the water storage tank (4); The main pipeline interface (51) is distributed in an array on the cooling main pipeline (5), and the on-off valve (52) is fixedly installed on the main pipeline interface (51); Cooling units (6) are fixedly installed on both sides of the equipment in the machine room box (1), and the cooling unit (6) is fixedly connected to the main pipe interface (51) through a water pipe joint (53). 6. An intelligent computer room control and adjustment device according to claim 5, characterized in that, the cooling unit (6) includes a cooling support seat (61), a cooling pipe (62) and a water pipe (63), wherein The cooling support base (61) is fixedly installed in the machine room box (1) by bolts, the upper end of the cooling support base (61) is provided with fixed blocks (64) distributed in an array, and the upper ends of the fixed blocks (64) are fixedly installed with arrayed distribution The cooling pipe (62), wherein the cooling pipe (62) is annular, the cooling pipe (62) is communicated through the connecting pipe (65), and the cooling pipe (62) located on the outside is connected with a water pipe (63), and the water pipe (63 ) through the machine room box (1), wherein the water pipe (63) is fixedly connected to the main pipe interface (51) through the water pipe joint (53). 7. An intelligent machine room control and adjustment device according to claim 6, characterized in that, the fixed block (64) is fixedly installed with a condensed water discharge channel (66), wherein the condensed water discharge channel (66) is located at Right below the cooling pipe (62). 8. An intelligent machine room control and adjustment device according to claim 7, characterized in that, the inner wall of the cooling pipe (62) is provided with a wiring board (67), and the wiring board (67) is provided with array-distributed wiring hole. 9. An intelligent machine room control and adjustment device according to any one of claims 1-8, characterized in that, the upper end of the machine room box (1) is fixedly equipped with an air inlet bin (7), and the air inlet bin (7 ) has an air inlet (71) on the back side, and an air inlet slot (72) connected to the inner cavity of the machine room box (1) is opened in the air inlet bin (7). The slide rail (73), the slide rail (73) is slidably connected with a blower mounting seat (74), and the blower fan (75) is fixedly installed on the blower mounting seat (74); A threaded rod (76) is installed in the air inlet bin (7), wherein the threaded rod (76) is rotatably connected with the side wall of the air inlet bin (7), the threaded rod (76) runs through the blower mounting seat (74), and the threaded rod (76) and the blower mounting base (74) are connected by thread fit, and one end of the threaded rod (76) is fixedly equipped with a motor (77), wherein the output end of the motor (77) is fixedly connected with the threaded rod (76), and the motor (77) ) is fixedly installed on the air inlet bin (7). 10. An intelligent machine room control and adjustment device according to claim 9, characterized in that, the lower end of the machine room box (1) facing away from the detection box (2) is provided with an exhaust hole (14) for exhausting An exhaust motor (141) is fixedly installed at the air hole (14); The upper end of the back side of the machine room box (1) is provided with symmetrically distributed moisture discharge holes (15), and a moisture exhaust fan (151) is fixedly installed at the moisture discharge holes (15), and a humidity exhaust fan (151) is installed in the machine room box (1). sensor.