CN111655001A - Mobile layered calculation cabinet with real-time high-temperature monitoring function - Google Patents

Mobile layered calculation cabinet with real-time high-temperature monitoring function Download PDF

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Publication number
CN111655001A
CN111655001A CN202010489816.0A CN202010489816A CN111655001A CN 111655001 A CN111655001 A CN 111655001A CN 202010489816 A CN202010489816 A CN 202010489816A CN 111655001 A CN111655001 A CN 111655001A
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China
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pressure
cabin
groups
heat dissipation
pipes
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CN202010489816.0A
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Chinese (zh)
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CN111655001B (en
Inventor
史金钢
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Shenzhen Yuntian Changxiang Information Technology Co ltd
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Individual
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    • HELECTRICITY
    • H05ELECTRIC TECHNIQUES NOT OTHERWISE PROVIDED FOR
    • H05KPRINTED CIRCUITS; CASINGS OR CONSTRUCTIONAL DETAILS OF ELECTRIC APPARATUS; MANUFACTURE OF ASSEMBLAGES OF ELECTRICAL COMPONENTS
    • H05K7/00Constructional details common to different types of electric apparatus
    • H05K7/20Modifications to facilitate cooling, ventilating, or heating
    • H05K7/20218Modifications to facilitate cooling, ventilating, or heating using a liquid coolant without phase change in electronic enclosures
    • H05K7/20272Accessories for moving fluid, for expanding fluid, for connecting fluid conduits, for distributing fluid, for removing gas or for preventing leakage, e.g. pumps, tanks or manifolds
    • GPHYSICS
    • G01MEASURING; TESTING
    • G01KMEASURING TEMPERATURE; MEASURING QUANTITY OF HEAT; THERMALLY-SENSITIVE ELEMENTS NOT OTHERWISE PROVIDED FOR
    • G01K11/00Measuring temperature based upon physical or chemical changes not covered by groups G01K3/00, G01K5/00, G01K7/00 or G01K9/00
    • GPHYSICS
    • G01MEASURING; TESTING
    • G01LMEASURING FORCE, STRESS, TORQUE, WORK, MECHANICAL POWER, MECHANICAL EFFICIENCY, OR FLUID PRESSURE
    • G01L19/00Details of, or accessories for, apparatus for measuring steady or quasi-steady pressure of a fluent medium insofar as such details or accessories are not special to particular types of pressure gauges
    • HELECTRICITY
    • H05ELECTRIC TECHNIQUES NOT OTHERWISE PROVIDED FOR
    • H05KPRINTED CIRCUITS; CASINGS OR CONSTRUCTIONAL DETAILS OF ELECTRIC APPARATUS; MANUFACTURE OF ASSEMBLAGES OF ELECTRICAL COMPONENTS
    • H05K7/00Constructional details common to different types of electric apparatus
    • H05K7/14Mounting supporting structure in casing or on frame or rack
    • HELECTRICITY
    • H05ELECTRIC TECHNIQUES NOT OTHERWISE PROVIDED FOR
    • H05KPRINTED CIRCUITS; CASINGS OR CONSTRUCTIONAL DETAILS OF ELECTRIC APPARATUS; MANUFACTURE OF ASSEMBLAGES OF ELECTRICAL COMPONENTS
    • H05K7/00Constructional details common to different types of electric apparatus
    • H05K7/20Modifications to facilitate cooling, ventilating, or heating
    • H05K7/20218Modifications to facilitate cooling, ventilating, or heating using a liquid coolant without phase change in electronic enclosures
    • H05K7/20281Thermal management, e.g. liquid flow control
    • GPHYSICS
    • G01MEASURING; TESTING
    • G01LMEASURING FORCE, STRESS, TORQUE, WORK, MECHANICAL POWER, MECHANICAL EFFICIENCY, OR FLUID PRESSURE
    • G01L19/00Details of, or accessories for, apparatus for measuring steady or quasi-steady pressure of a fluent medium insofar as such details or accessories are not special to particular types of pressure gauges
    • G01L2019/0053Pressure sensors associated with other sensors, e.g. for measuring acceleration, temperature

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  • Engineering & Computer Science (AREA)
  • Microelectronics & Electronic Packaging (AREA)
  • Physics & Mathematics (AREA)
  • General Physics & Mathematics (AREA)
  • Thermal Sciences (AREA)
  • Cooling Or The Like Of Electrical Apparatus (AREA)

Abstract

The invention discloses a mobile layered calculating cabinet with a real-time high-temperature monitoring function, which comprises a cabinet body, a plurality of component laminated plates, a low-pressure heat dissipation mechanism and a plurality of groups of pressure and temperature collecting mechanisms matched with the laminated plates, the cabinet body is internally provided with a plurality of component layer plates from top to bottom in sequence, a low-pressure heat dissipation mechanism is arranged in the cabinet body, a plurality of groups of pressure and temperature collection mechanisms are arranged in the component layer plates, the low-pressure heat dissipation mechanism is fixed with the layered plate, the low-pressure heat dissipation mechanism cools the interior of the cabinet body, the low-pressure heat dissipation mechanism accelerates the heat dissipation of the solution through a low-pressure space, the pressure and temperature collecting mechanism monitors the temperature inside the cabinet body, and the pressure and temperature collecting mechanism monitors the change of the temperature through the change of the air pressure.

Description

Mobile layered calculation cabinet with real-time high-temperature monitoring function
Technical Field
The invention relates to the technical field of computer cabinets, in particular to a mobile layered computer cabinet with a real-time high-temperature monitoring function.
Background
As is known, a computing cabinet is an auxiliary device used in daily life for storing and protecting a computer and related control equipment thereof, and is widely used in the field of placement devices, but the current computing cabinet has low intelligence degree, can only be manually controlled, is inconvenient to use, and has no way of manually staring at and controlling the temperature in the particular computing cabinet at any time.
In actual life, the computing cabinet generates more heat in the using process of elements, so that the internal elements can be damaged if the heat is not dissipated timely, the heat dissipation effect of the existing computing cabinet is poor, intelligent control cannot be performed according to needs, the use is complex, and the cost is increased.
The existing board of placing is fixed connection with the inner wall of the cabinet body, can't adjust the distance between two adjacent boards of placing, and the too big then of distance between the adjacent board of placing causes the waste of the internal space of cabinet easily, and the undersize of distance between the adjacent board of placing then is not convenient for install computer and relevant controlgear, is not convenient for according to the height of computer and relevant equipment and rationally distributes the internal space of the cabinet body.
Therefore, a mobile hierarchical computing rack with real-time high temperature monitoring is needed to solve the above problems.
Disclosure of Invention
The invention aims to provide a mobile layered type computing cabinet with a real-time high-temperature monitoring function, which is used for solving the problems in the prior art.
In order to achieve the purpose, the invention provides the following technical scheme: the utility model provides a remove layer-stepping has calculation rack of real-time high temperature monitoring function, this calculation rack include the cabinet body, a plurality of component plywoods, low pressure heat dissipation mechanism, with a plurality of groups pressure temperature measurement mechanism that the layering board matches, the internal portion of cabinet has set gradually a plurality of component plywoods from last down, the internal low pressure heat dissipation mechanism that is provided with of cabinet, a plurality of groups pressure temperature measurement mechanism sets up in the layering board, low pressure heat dissipation mechanism is fixed with the layering board, and low pressure heat dissipation mechanism cools down the internal portion of cabinet, and low pressure heat dissipation mechanism is through the heat dissipation of low pressure space solution with higher speed, pressure temperature measurement mechanism monitors the internal portion temperature of cabinet, and pressure temperature measurement mechanism passes through the change of. The change of atmospheric pressure carries out the centralized monitoring when temperature measurement mechanism rises through the temperature to the collection, learns the situation of change of the internal portion temperature of cabinet through the weak change of atmospheric pressure, and the heat of the internal portion of cabinet is taken away through the oil that specific heat capacity is big to low pressure heat dissipation mechanism to make the partial vaporization in the low pressure space of oil, accelerate the heat dissipation of oil, make oil absorb the heat fast in the cabinet body, release heat, thereby reduce the high temperature that the internal plant of cabinet during operation produced.
According to a preferred technical scheme, the low-pressure heat dissipation mechanism comprises a liquid storage cabin and a heat dissipation cabin, wherein the liquid storage cabin is arranged at the upper end inside the cabinet body, the heat dissipation cabin is arranged at the lower end inside the cabinet body, and the heat dissipation cabin is connected with a liquid storage cabin through a pipeline; the pressure and temperature collecting and measuring mechanism comprises a pressure collecting cabin and a pressure measuring cabin, wherein the pressure collecting cabin converts the temperature change of the laminated plate into the air pressure change, the pressure measuring cabin measures the air pressure change, and the pressure collecting cabin is connected with a temperature measuring cabin pipeline; the laminated board is connected with the cabinet body in a sliding mode, at least four groups of supporting columns are arranged on the laminated board, locking blocks are arranged at one ends of the four groups of supporting columns, and the four groups of locking blocks are located in the cabinet body. The cabinet body is the layering board, the installation of low pressure heat dissipation mechanism provides the support, protect electrical equipment on the layering board simultaneously, the stock solution cabin is stored oil, the heat dissipation cabin makes oil in low pressure space part vaporization and makes oil accelerate the radiating process, the pressure measurement cabin turns into the atmospheric pressure change with the temperature variation of layering board, the pressure measurement cabin measures the atmospheric pressure change, the layering board is installed for electrical equipment and is provided the support in the cabinet body, the while layering board provides the support for the installation of pressure measurement mechanism, the support column is transmitted the locking piece with gravity on the layering board on, the locking piece is fixed for the layering board and is provided the support in the cabinet body.
According to the preferable technical scheme, an annular air bag is arranged in the pressure collecting cabin, a plurality of groups of radiating fins are arranged on the upper end face inside the pressure collecting cabin, a heat insulating layer is arranged on the outer surface of the annular air bag, the annular air bag is connected with a temperature measuring cabin through a pipeline, and a pressure sensor is arranged in the temperature measuring cabin. When the electrical equipment work of lamination board top and when producing the temperature, the lamination board distributes the temperature to the collection ballasting in through the fin, and make the temperature rise in the collection ballasting, when the temperature risees in the collection ballasting, atmospheric pressure grow in the collection ballasting is and extrude annular gasbag, annular gasbag concentrates and transmits the temperature measurement cabin to the atmospheric pressure in the collection ballasting, make the atmospheric pressure increase in the temperature measurement cabin, the heat insulation layer makes the air in the annular gasbag not receive the influence of temperature in the collection ballasting, thereby avoid air among the annular gasbag to be heated and influence the temperature measurement accuracy, pressure sensor collects the change data of atmospheric pressure in the temperature measurement cabin.
According to the preferable technical scheme, circulation pipes are arranged in the layered plates, the circulation pipes are located below the pressure and temperature collecting and measuring mechanism and are S-shaped pipelines, short pipes are arranged on two sides of each inflection point on the circulation pipes, the short pipes are distributed on two sides of the layered plates and communicated with the circulation pipes, electromagnetic valves are arranged in the short pipes, one ends of the circulation pipes are connected with the pipeline of the liquid storage cabin, and one ends of the short pipes in one side of the layered plates are connected with the pipeline of the liquid storage cabin. The runner pipe is the inside passageway that provides of oil flow partition plate, the flow time of S type pipeline extension oil in the layering board, a plurality of groups of nozzle stub are split into multiunit direct current pipeline with S type pipeline, the solenoid valve is controlled switching on and closing of nozzle stub, when the temperature of layering board is not high, oil flows to the other end from the one end of S type pipeline, when the rising rate of layering board temperature is greater than the flow velocity of oil, solenoid valve work makes nozzle stub and S type pipeline intercommunication, make oil flow from organizing direct current pipeline, thereby accelerate the heat dissipation of layering board.
As preferred technical scheme, be provided with the support frame in the stock solution cabin, be provided with three at least extraction pumps of group on the support frame, three groups the extraction pump all with heat dissipation cabin pipe connection, turn right from a left side and set gradually No. I feed liquor pipe, No. II feed liquor pipe, No. III feed liquor pipe in below one side of stock solution cabin, all be provided with a plurality of groups solenoid valve in No. I feed liquor pipe, No. II feed liquor pipe, No. III feed liquor pipe, the one end pipe connection of runner pipe on No. I feed liquor pipe and a plurality of component plywood, No. II feed liquor pipe, No. III feed liquor pipe respectively with the short pipe connection of a plurality of component plywood one side. The support frame provides the support for the installation of aspiration pump, the oil after the aspiration pump extracts the heat dissipation from the heat dissipation cabin, the stock solution cabin infuses oil through three feed liquor pipes of group to the runner pipe, when the temperature of layering board is not high, the stock solution cabin is through No. I feed liquor pipe transmission oil in to the runner pipe, when the rising speed of layering board temperature is greater than the mobile speed of oil, the stock solution cabin is through No. I feed liquor pipe, No. II feed liquor pipe, No. III feed liquor pipe infuses oil to the direct current pipeline simultaneously, accelerate the cooling of layering board.
As preferred technical scheme, turn right from a left side and have set gradually pressurized cabin, heat dissipation pump, low-pressure pipe, concentrated cabin inside the heat dissipation cabin, heat dissipation pump one end and pressurized cabin pipe connection, the heat dissipation pump other end and low-pressure pipe connection, the other end and the concentrated cabin pipe connection of low-pressure pipe, the other end of concentrated cabin is from last No. III drain pipes, No. II drain pipes, No. I drain pipes of down having set gradually. The oil after the pressure boost cabin is cooled down is stored, the heat-radiating pump pours the oil pumped from the low-pressure pipe into the pressure boost cabin, along with the continuous increase of oil, the air storage space in the pressure boost cabin constantly reduces to make the atmospheric pressure in the pressure boost cabin increase, the air in the low-pressure pipe is pumped to the heat-radiating pump, make the inside low-pressure space that becomes of low-pressure pipe, the oil of high temperature that the concentrated cabin flowed out from the layering board is concentrated, No. III drain pipe, No. II drain pipe, No. I drain pipe transmit the oil that flows out in the layering board, make the oil flow to concentrate the under-deck.
As a preferred technical scheme, at least three groups of transmission pipes are arranged on one side above the pressurizing cabin, the three groups of transmission pipes penetrate through the heat dissipation cabin and are respectively connected with the three groups of extraction pump pipelines, the No. III liquid outlet pipe and the No. II liquid outlet pipe are respectively connected with a plurality of groups of short pipe pipelines on the other side of the layered plate, and the No. I liquid outlet pipe is connected with the other end pipelines of the circulation pipes on the layered plate. The transmission pipe transmits the oil after heat dissipation in the pressurizing cabin, so that the oil in the pressurizing cabin enters the liquid storage cabin along the transmission pipe under the pumping of the pumping pump.
As a preferred technical scheme, a throttle valve is arranged between the low-pressure pipe and the concentration cabin, a plurality of groups of heat dissipation plates are arranged on the low-pressure pipe, and the heat dissipation plates penetrate through the low-pressure pipe. The flow between the throttle valve to low-pressure pipe and the concentrated cabin is controlled, when the air of heat dissipation pump in to the low-pressure pipe is extracted, form the low pressure space in making the low-pressure pipe through the throttle effect of throttle valve, the throttle valve limits the volume of producing oil of concentrated cabin simultaneously, make the little flow of oil in the concentrated cabin enter into the low-pressure pipe, after oil that has the temperature enters into the low pressure space, partial oil that has the temperature can vaporize in low pressure environment, thereby accelerate the heat dissipation of oil, the cooling panel increases the area of contact of low-pressure pipe and the oil after the vaporization, accelerate the radiating rate of oil.
As a preferred technical scheme, the internal portion of cabinet is provided with four at least groups of adjustment tank, four groups of adjustment tank two liang a set of and set up respectively on the internal mutually opposite terminal surface of cabinet, the adjustment tank is C type groove, is provided with the teeth of a cogwheel on the opposite terminal surface in the adjustment tank, the locking piece is located the adjustment tank, and the both sides of locking piece and the teeth of a cogwheel meshing. The adjusting groove provides a channel for adjusting the position of the layered plate in the cabinet body, and the gear teeth provide support for fixing the locking block in the adjusting groove.
According to the preferable technical scheme, the locking block comprises a shell and a gravity rod, a pressing block, at least two groups of locking plates and at least two groups of pulley blocks are sequentially arranged in the shell from top to bottom, the gravity rod is located between the two groups of locking plates and penetrates through the shell, gravity balls are arranged at the upper end and the lower end of the gravity rod and at the upper end of the gravity rod and are respectively connected with the pressing block and the two groups of locking plates in a sliding mode, a plurality of groups of springs are arranged between the locking plates and the shell, the lower end faces of the two groups of locking plates are respectively connected with the two groups of pulley blocks in a sliding mode, one ends of the two groups of locking plates penetrate through the shell, and. The shell provides support for the installation of the gravity rod, the pressing block and the locking plates, the pressing block transmits the gravity transmitted by the support column to the gravity ball, the acting force of the gravity ball on the locking plates is increased, the pulley block reduces the friction force between the locking plates and the shell, the gravity ball is positioned between the two groups of locking plates, gear teeth are arranged on the end faces of the locking plates, when the locking plates slide out of the shell, the gear teeth on the locking plates are meshed with the gear teeth in the adjusting groove, so that the locking blocks are fixed in the adjusting groove, the gravity ball at the upper end is contacted with the two groups of locking plates, when the gravity ball moves downwards under the action of the self gravity, due to the support of the two groups of locking plates on the gravity ball at the upper end, the gravity ball at the lower end is superposed on the gravity ball at the upper end through the gravity rod, the gravity ball at the upper end acts on the two groups of locking plates, the two groups of locking plates decompose the gravity, and obtain the power moving towards two sides, so that the, thereby make the locking piece fix in the adjustment tank, pass through the support column when the layering board with gravity action on the gravity ball for the effort increase of gravity ball to two sets of jam plates, make the connection between locking piece and the adjustment tank more stable.
Compared with the prior art, the invention has the beneficial effects that:
1. this device carries out temperature measurement to the lamination board of direct and electrical equipment contact, the temperature variation with the lamination board turns into atmospheric pressure change, when there is slight change in the temperature, atmospheric pressure in the pressure collecting cabin will increase, atmospheric pressure will carry out comprehensive extrusion to the gasbag, make the air among the gasbag enter into the temperature measurement cabin, make the atmospheric pressure increase in the temperature measurement cabin, enlarge temperature variation through atmospheric pressure change, and monitor the change of atmospheric pressure through pressure sensor, obtain the temperature variation of lamination board, and finally obtain the temperature variation in the calculation rack, for traditional mode through the internal temperature of a plurality of temperature measurement sensor fixed point monitoring cabinets, this mode is more direct, and detect all electrical equipment's on the lamination board temperature condition simultaneously, higher high efficiency.
2. This device carries out the heat absorption cooling through the oil bisection plywood that specific heat capacity is big, thereby reduce the temperature of the internal portion of cabinet, the heat pump makes become the low pressure space in the low pressure pipe through the air among the extraction low pressure pipe, simultaneously concentrate the pipe through throttle valve control to the flow of transmission oil in the low pressure pipe, make the oil that has the temperature in the concentrated pipe in the low pressure pipe that enters into, the oil that the small amount has the temperature is in the partial vaporization of low pressure space, thereby accelerate the heat dissipation progress of oil, for traditional mode through forced air cooling or water-cooling, the cooling mode of this device is simpler, fast.
3. This device is fixed through the position of locking piece halving layer board, the locking piece is fixed self at the cabinet internally through gravity, and after installing electrical equipment on the layering board, the layering board transmits gravity on the locking piece internals, thereby make the connection between the locking piece and the cabinet body fastening more, and along with the increase of weight, the firmness also increases thereupon, when needs halving layer board adjusting position, only need hold up the gravity ball on the locking piece, just can relieve being connected between the locking piece and the cabinet body, for traditional mode through the screw fixation layering board, this device carries out convenience through the mode of the fixed layering board of locking piece, and is swift.
Drawings
FIG. 1 is a schematic view of an overall structure installation of a mobile layered computing rack with real-time high temperature monitoring function according to the present invention;
FIG. 2 is a front view of the interior components of a mobile hierarchical computing rack with real-time high temperature monitoring capabilities of the present invention;
FIG. 3 is a right side view of the internal structure of a mobile layered computing rack with real-time high temperature monitoring capability according to the present invention;
FIG. 4 is a top view of the overall structure of a mobile hierarchical computing rack with real-time high temperature monitoring capability according to the present invention;
FIG. 5 is a top view of a layered panel of a mobile layered computing rack with real-time high temperature monitoring capabilities of the present invention;
FIG. 6 is a front half-sectional view of a movable tiered computing rack with real-time high temperature monitoring capabilities;
FIG. 7 is a schematic diagram of an internal structure of a layered board of a mobile layered computing rack with real-time high temperature monitoring function according to the present invention;
FIG. 8 is a schematic diagram showing a connection relationship between a centralized compartment and a low-pressure pipe of a mobile layered computing rack with a real-time high-temperature monitoring function according to the present invention;
FIG. 9 is a schematic diagram showing a connection relationship between a low-voltage tube and a heat dissipation plate of a mobile layered computing rack with a real-time high-temperature monitoring function according to the present invention;
FIG. 10 is a schematic diagram of an internal structure of a lock block of a mobile layered computer cabinet with real-time high temperature monitoring function according to the present invention;
FIG. 11 is a schematic diagram illustrating a connection relationship between a housing and a lock plate of a lock block of a mobile layered computer cabinet with a real-time high temperature monitoring function according to the present invention.
The reference numbers are as follows: 1. a cabinet body; 2. a low-voltage heat dissipation mechanism; 3. a pressure-collecting temperature-measuring mechanism; 4. a laminate; 5. a locking block; 1-1, adjusting tank; 2-1, a liquid storage cabin; 2-2, a heat dissipation cabin; 2-11, a support frame; 2-12, I liquid inlet pipe; 2-13, II liquid inlet pipe; 2-14, III liquid inlet pipe; 2-15, a pump; 2-21, a pressurizing cabin; 2-22, a heat-dissipating pump; 2-23, low-pressure pipe; 2-24, a centralized cabin; 2-25, III liquid outlet pipe; 2-26, No. II drain pipe; 2-27, No. I drain pipe; 2-28, a throttle valve; 2-29, a conveying pipe; 2-30 parts of a heat dissipation plate; 3-1, collecting ballast; 3-2, a pressure measuring cabin; 3-11, annular air bag; 3-12, a heat sink; 3-21, a pressure sensor; 4-1, a circulating pipe; 4-2, short pipe; 5-1, a shell; 5-2, locking plates; 5-3, a gravity rod; 5-4, pressing blocks; 5-5, gravity ball; 5-6 and a spring.
Detailed Description
The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.
Example (b): as shown in fig. 1-11, a remove layer-stepping has calculation rack of real-time high temperature monitoring function, this calculation rack includes the cabinet body 1, a plurality of component plywood 4, low pressure heat dissipation mechanism 2, a plurality of groups pressure temperature measurement mechanism 3 that matches with the plywood, 1 inside of cabinet body installs a plurality of component plywood 4 from last to down in proper order, install low pressure heat dissipation mechanism 2 in the cabinet body 1, a plurality of groups pressure temperature measurement mechanism 3 sets up in the plywood 4, low pressure heat dissipation mechanism 2 is fixed with the plywood 4, low pressure heat dissipation mechanism 2 cools down 1 inside of cabinet body, low pressure heat dissipation mechanism 2 accelerates the heat dissipation of solution through the low pressure space, pressure temperature measurement mechanism 3 monitors the internal temperature of cabinet body 1, pressure temperature measurement mechanism 3 monitors the change of temperature through atmospheric pressure change.
The computer cabinet further comprises a control system, the control system is electrically connected with all the pumps, the pressure sensors and all the electromagnetic valves in the computer cabinet, the control system controls the pumps and the electromagnetic valves and receives electric signals transmitted by the pressure sensors, and the control system controls the pumps and the electromagnetic valves according to the signals transmitted by the pressure sensors.
At least four groups of adjusting grooves 1-1 are processed in the cabinet body 1, every two groups of the four groups of adjusting grooves 1-1 are respectively positioned on the mutually opposite end surfaces in the cabinet body 1, the adjusting grooves 1-1 are C-shaped grooves, and gear teeth are processed on the mutually opposite end surfaces in the adjusting grooves 1-1.
In the embodiment, three groups of layered plates 4 are taken as an example, support columns 4-1 are welded on end faces of two sides of the three groups of layered plates 4 at positions corresponding to the adjusting grooves 1-1, locking blocks 5 are mounted at one ends of the four groups of support columns 4-1, and the locking blocks 5 are located in the adjusting grooves 1-1.
The lock block 5 comprises a shell 5-1 and a gravity rod 5-3, wherein a press block 5-4, at least two groups of lock plates 5-2 and at least two groups of pulley blocks 5-3 are sequentially arranged in the shell 5-1 in a sliding manner from top to bottom, the gravity rod 5-3 is fixedly arranged between the two groups of lock plates 5-2, the lower end of the gravity rod 5-3 penetrates through the shell 5-1, the upper end and the lower end of the gravity rod 5-3 are respectively welded with a gravity ball 5-5, the upper end of the upper gravity ball 5-5 is in sliding connection with the press block 5-4, the two sides of the lower end of the upper gravity ball 5-5 are in sliding connection with the two groups of lock plates 5-2, the two sides of the two groups of lock plates 5-2 are respectively welded with a baffle, a plurality of springs 5-6 are arranged between the baffle and the shell 5-1, and the end surfaces of the two groups of lock, the lower end surfaces of the two groups of locking plates 5-2 are respectively connected with the two groups of pulley blocks 5-3 in a sliding way, one end of the two groups of locking plates 5-2 penetrates through the shell 5-1, the end surface of one end of the two groups of locking plates 5-2 penetrating through the shell 5-1 is welded with gear teeth, when the lock plate 5-2 extends out of the shell 5-1 under the action of the gravity ball 5-5, the lock plate 5-2 compresses the spring through the baffle plate, simultaneously the gear teeth on the lock plate 5-2 are meshed with the gear teeth in the adjusting groove 1-1, so that the whole locking block 5 is fixed in the adjusting groove 1-1, when the gravity ball 5-5 is lifted by external force and the gravity ball 5-5 does not apply gravity to the locking plate 5-2, the two groups of locking plates 5-2 are retracted into the shell 5-1 under the action of the spring, so that the locking block 5 can slide in the adjusting groove 1-1 at will.
The three groups of the layered plates 4 are also internally provided with circulation pipes 4-1, the circulation pipes 4-1 are positioned below the pressure and temperature collecting and measuring mechanism 3, the circulation pipes 4-1 are S-shaped pipelines with two inflection points, short pipes 4-2 are welded on two sides of each inflection point on the circulation pipes 4-1, the short pipes 4-2 are distributed on two sides of the layered plates 4, two short pipes 4-2 are arranged on two sides of the layered plates 4, the short pipes 4-2 are communicated with the circulation pipes 4-1, electromagnetic valves 4-3 are arranged in each short pipe 4-2, one end of each circulation pipe 4-1 is connected with the liquid storage cabin 2-1 through a pipeline, one end of each group of short pipes 4-2 on one side of the layered plates 4 is connected with the liquid storage cabin 2-1 through a pipeline, the other end of each group of short pipes 4-1 is connected with the heat dissipation cabin 2-2 through a pipeline, and one end of each group of short pipes.
The pressure and temperature collecting and measuring mechanism 3 comprises a pressure and temperature collecting cabin 3-1 and a pressure measuring cabin 3-2, the pressure and temperature collecting and measuring mechanism 3 is arranged inside the component layer plates 4, the pressure and temperature collecting and measuring mechanism 3 monitors the temperature change of each layer plate 4, the pressure and temperature collecting cabin 3-1 converts the temperature change of the layer plate 4 into the air pressure change, the pressure measuring cabin 3-2 measures the air pressure change, and the pressure collecting cabin 3-1 is connected with the temperature measuring cabin 3-2 through a pipeline;
an annular air bag 3-11 is arranged in the pressure collecting cabin 3-1, a plurality of groups of radiating fins 3-12 are welded on the upper end surface inside the pressure collecting cabin 3-1, the outer surface of the annular air bag 3-11 is coated with heat insulating materials, the annular air bag 3-11 is connected with a temperature measuring cabin 3-2 through a pipeline, a pressure sensor 3-21 is arranged in the temperature measuring cabin 3-2, when the temperature inside the pressure-collecting cabin 3-1 rises so that the air pressure inside the pressure-collecting cabin 3-1 increases, thereby extruding the annular air bag 3-11, leading the air in the annular air bag 3-11 to enter the temperature measuring cabin 3-2, leading the annular air bag 3-11 to concentrate the air pressure in the pressure collecting cabin 3-1 and transmit the air pressure into the temperature measuring cabin 3-2, so that the air pressure in the temperature measuring cabin 3-2 is increased, and the pressure sensor 3-21 detects the air pressure change in the temperature measuring cabin 3-2.
The low-pressure heat dissipation mechanism 2 comprises a liquid storage cabin 2-1 and a heat dissipation cabin 2-2, wherein the liquid storage cabin 2-1 is positioned at the upper end inside the cabinet body 1, the heat dissipation cabin 2-2 is positioned at the lower end inside the cabinet body 1, and the heat dissipation cabin 2-2 is connected with the liquid storage cabin 2-1 through a pipeline;
a support frame 2-11 is welded in the liquid storage cabin 2-1, at least three groups of extraction pumps 2-15 are fixed on the support frame 2-11, the three groups of extraction pumps 2-15 are all connected with the heat dissipation cabin 2-2 by pipelines, a No. I liquid inlet pipe 2-12, a No. II liquid inlet pipe 2-13 and a No. III liquid inlet pipe 2-14 are sequentially welded on the left side of the lower part of the liquid storage cabin 2-1 from left to right, the No. I liquid inlet pipe 2-12, the No. II liquid inlet pipe 2-13 and the No. III liquid inlet pipe 2-14 are all fixed in the inner wall of the shell 1, two groups of electromagnetic valves are respectively installed in the No. I liquid inlet pipe 2-12, the No. II liquid inlet pipe 2-13 and the No. III liquid inlet pipe 2-14 from top to bottom, a control system changes the flow direction of oil in the liquid inlet pipe by, No. II liquid inlet pipes 2-13 and No. III liquid inlet pipes 2-14 are respectively provided with an oil outlet above each electromagnetic valve, corrugated pipes are respectively arranged at two oil outlets of the No. I liquid inlet pipes 2-12, the No. I liquid inlet pipes 2-12 are connected with one end of a circulating pipe 4-1 on a plurality of component laminated plates 4 through corrugated pipes, corrugated pipes are respectively arranged at each oil outlet of the No. II liquid inlet pipes 2-13 and No. III liquid inlet pipes 2-14, and the No. II liquid inlet pipes 2-13 and No. III liquid inlet pipes 2-14 are respectively connected with short pipes 4-2 on one side of three component laminated plates 4 through corrugated pipes.
Two groups of electric fans are arranged on the right side of the heat dissipation cabin 2-2, the electric fans accelerate air circulation in the heat dissipation cabin 2-2, the electric fans are fixed on the inner wall of the shell 1, a pressurizing cabin 2-21, a heat dissipation pump 2-22, a low-pressure pipe 2-23 and a concentration cabin 2-24 are sequentially arranged in the heat dissipation cabin 2-2 from left to right, one end of the heat dissipation pump 2-22 is connected with the pressurizing cabin 2-21 through a pipeline, the other end of the heat dissipation pump 2-22 is connected with an oil outlet end pipeline of the low-pressure pipe 2-23, the other end of the low-pressure pipe 2-23 is provided with a throttle valve 2-28, the other end of the throttle valve 2-28 is connected with the concentration cabin 2-24 through a pipeline, a plurality of groups of heat dissipation plates 2-30 are welded on the low-pressure, no. III liquid outlet pipes 2-25, No. II liquid outlet pipes 2-26 and No. I liquid outlet pipes 2-27 are sequentially arranged at the other ends of the concentration cabins 2-24 from top to bottom, No. I liquid outlet pipes 2-27, No. II liquid outlet pipes 2-26 and No. III liquid outlet pipes 2-25 are all fixedly arranged in the inner wall of the shell 1, two oil inlets are sequentially processed on the No. I liquid outlet pipes 2-27, No. II liquid outlet pipes 2-26 and No. III liquid outlet pipes 2-25 from top to bottom, and corrugated pipes are arranged at each oil inlet of the No. I liquid outlet pipes 2-27, No. II liquid outlet pipes 2-26 and No. III liquid outlet pipes 2-25.
At least three groups of transmission pipes 2-29 are welded on one side above the pressurizing cabin 2-21, the three groups of transmission pipes 2-29 are all fixed inside the inner wall of the shell 1, the lower ends of the three groups of transmission pipes 2-29 penetrate through the heat dissipating cabin 2-2 and are respectively connected with three groups of extraction pumps 2-15 through pipelines, the No. III liquid outlet pipes 2-25 and the No. II liquid outlet pipes 2-26 are respectively connected with short pipes 4-2 on the other sides of the plurality of component laminated plates 4 through corrugated pipes, and the No. I liquid outlet pipes 2-27 are connected with the other end of the circulation pipes 4-1 on the three groups of laminated plates 4 through corrugated pipes.
The oil outlets on the liquid inlet pipes 2-12, the liquid inlet pipes 2-13 and the liquid inlet pipes 2-14 are numbered respectively, the two oil outlets on the liquid inlet pipes 2-12 are numbered as the oil outlet 1A and the oil outlet 1B sequentially from top to bottom, the two oil outlets on the liquid inlet pipes 2-13 are numbered as the oil outlet 2A and the oil outlet 2B sequentially from top to bottom, and the two oil outlets on the liquid inlet pipes 2-14 are numbered as the oil outlet 3A and the oil outlet 3B sequentially from top to bottom.
The electromagnetic valves on the liquid inlet pipes 2-12, 2-13 and 2-14 are numbered respectively, the two electromagnetic valves on the liquid inlet pipes 2-12 are numbered as a 1C electromagnetic valve and a 1D electromagnetic valve from top to bottom, the two electromagnetic valves on the liquid inlet pipes 2-13 are numbered as a 2C electromagnetic valve and a 2D electromagnetic valve from top to bottom, and the two electromagnetic valves on the liquid inlet pipes 2-14 are numbered as a 3C electromagnetic valve and a 3D electromagnetic valve from top to bottom.
The three groups of the laminated plates 4 are respectively numbered as a 1# laminated plate, a 2# laminated plate and a 3# laminated plate from top to bottom, electromagnetic valves in the short pipes 4-2 are respectively numbered, the electromagnetic valves in the two groups of short pipes 4-2 on the left side of the laminated plate 4 are numbered as 4A electromagnetic valves and 4B electromagnetic valves, and the electromagnetic valves in the two groups of short pipes 4-2 on the right side of the laminated plate 4 are numbered as 5A electromagnetic valves and 5B electromagnetic valves.
The oil inlet end of a flow pipe 4-1 in the 1# stratified plate corresponds to an oil outlet of 1A, the two groups of short pipes 4-2 on the left side correspond to an oil outlet of 2A and an oil outlet of 3A respectively, the oil outlet end of the flow pipe 4-1 in the 1# stratified plate corresponds to the oil inlet end of a No. I liquid outlet pipe 2-27, and the two groups of short pipes 4-2 on the right side correspond to the oil inlet ends of a No. II liquid outlet pipe 2-26 and a No. III liquid outlet pipe 2-25 respectively.
The oil inlet end of a flow pipe 4-1 in the 2# stratified plate corresponds to a 2B oil outlet, the two groups of short pipes 4-2 on the left correspond to the 1B oil outlet and the 3B oil outlet respectively, the oil outlet end of the flow pipe 4-1 in the 2# stratified plate corresponds to an oil inlet at the upper end of a No. I liquid outlet pipe 2-27, and the two groups of short pipes 4-2 on the right correspond to oil inlets at the upper ends of a No. II liquid outlet pipe 2-26 and a No. III liquid outlet pipe 2-25 respectively.
The oil inlet end of a flow pipe 4-1 in the 3# laminated plate corresponds to the oil outlet end of a No. III liquid inlet pipe 2-14, the two groups of short pipes 4-2 on the left side correspond to the oil outlet ends of a No. I liquid inlet pipe 2-12 and a No. II liquid inlet pipe 2-13 respectively, the oil outlet end of the flow pipe 4-1 in the 3# laminated plate corresponds to the oil inlet at the lower end of a No. I liquid outlet pipe 2-27, and the two groups of short pipes 4-2 on the right side correspond to the oil inlets at the lower ends of a No. II liquid outlet pipe 2-26 and a No..
When the electromagnetic valves in all the short pipes 4-2 in each layered plate 4 are closed, the circulating pipe 4-1 is a complete S-shaped pipeline, when the electromagnetic valves in all the short pipes 4-2 are opened, the circulating pipe 4-1 is changed into three groups of direct current pipelines, the circulating pipe 4-1 is the S-shaped pipeline in the initial state, and the electromagnetic valves in all the short pipes 4-2 are closed.
When the laminated plate 4 is not at temperature, the 1C electromagnetic valve in the liquid inlet pipe 2-12I is closed, the liquid inlet pipe 2-12I pumps oil into the laminated plate 1# through the oil outlet 1A, the 2D electromagnetic valve in the liquid inlet pipe 2-13 II is closed, the liquid inlet pipe 2-13 II pumps oil into the laminated plate 2# through the oil outlet 2B, the two groups of electromagnetic valves in the liquid inlet pipe 2-14 III are not closed, and the liquid inlet pipe 2-14 III pumps oil into the laminated plate 3# through the oil outlet.
The working principle of the invention is as follows:
the three groups of layered plates 4 are respectively fixed on the cabinet body 1 through the locking blocks 5, and the layered plates 4 transmit gravity to the locking blocks 5 through the support columns 4-1, so that the locking blocks 5 are more tightly connected with the adjusting grooves 1-1.
When the gravity ball 5-5 moves downwards under the action of self gravity, because the gravity ball 5-5 at the upper end is supported by the two groups of locking plates 5-2, the gravity ball 5-5 at the lower end superposes the gravity on the gravity ball 5-5 at the upper end through the gravity rod 5-3, the gravity ball 5-5 at the upper end acts on the two groups of locking plates 5-2, the two groups of locking plates 5-2 decompose the gravity and obtain the power moving towards two sides, so that the two groups of locking plates 5-2 extend out of the shell 5-1 and are contacted with the adjusting groove 1-1 through gear teeth, the locking block 5 is fixed in the adjusting groove 1-1, when the gravity acts on the gravity ball 5-5 through the support column 4-1 and the press block 5-4 by the layered plate 4, the acting force of the gravity ball 5-5 on the two groups of locking plates 5-2 is increased, so that the connection between the locking piece 5 and the adjusting groove 1-1 is more stable.
When the electric appliances on the layered plate 4 start to work, the temperature of the layered plate 4 starts to rise, the temperature in the pressure collecting cabin 3-1 positioned inside the layered plate 4 also rises, the air pressure inside the pressure collecting cabin 3-1 is increased due to the rise of the temperature in the pressure collecting cabin 3-1, the annular air bag 3-11 is extruded by the increased air pressure, the annular air bag 3-11 intensively transmits the air pressure change in the pressure collecting cabin 3-1 to the temperature measuring cabin 3-2, the air pressure in the temperature measuring cabin 3-2 is increased, the air pressure in the temperature measuring cabin 3-2 is increased along with the continuous increase of the temperature of the laminated plate 4, the pressure sensor 3-21 monitors the air pressure in the temperature measuring cabin 3-2, and the data of the monitored air pressure change is transmitted to a control system, so that the control system controls a pump to fill oil into the laminated plate 4.
The extraction pumps 2-15 extract oil in the pressurizing chambers 2-21, the oil flows into the corresponding laminated plates 4 through the No. I liquid inlet pipes 2-12, the No. II liquid inlet pipes 2-13 and the No. III liquid inlet pipes 2-14 respectively, the heat dissipation pumps 2-22 extract air in the low-pressure pipes 2-23, air in the circulation pipes 4-1, the liquid outlet pipes and the concentration chambers 2-24 flows to the low-pressure pipes 2-23, the flow speed of the oil in each pipeline is accelerated, the temperature on the laminated plates 4 is taken away through the circulation of the oil in the laminated plates 4, the temperature of the laminated plates 4 is reduced, and finally the oil with the temperature is concentrated in the concentration chambers 2-24.
When the heat dissipation pump 2-22 pumps air in the low-pressure pipe 2-23, a low-pressure space is formed in the low-pressure pipe 2-23 through the throttling action of the throttle valve 2-28, meanwhile, the throttle valve 2-28 limits the oil output of the concentration cabin 2-24, so that a small flow of oil in the concentration cabin 2-24 enters the low-pressure pipe 2-23, after the oil with the temperature enters the low-pressure space, part of the oil with the temperature can be vaporized in a low-pressure environment, the heat dissipation of the oil is accelerated, and the heat dissipation plate 2-30 increases the contact area of the low-pressure pipe 2-23 and the vaporized oil, so that the heat dissipation speed of the oil is accelerated.
When the air pressure in the temperature measuring chamber 3-2 in one group of the three groups of the layered plates 4 is continuously increased (namely, the temperature of the layered plate 4 is continuously increased) and exceeds the flowing speed of oil in the circulating pipe 4-1, the control system controls the electromagnetic valves in all the short pipes 4-2 on the layered plate 4 to be opened, and simultaneously controls the corresponding electromagnetic valves in the liquid inlet pipe to be closed or opened, so that the three groups of the liquid inlet pipes simultaneously infuse the oil into the layered plate 4, the flowing speed and the flowing quantity of the oil in the layered plate 4 are accelerated, and meanwhile, the control system gives an alarm to the outside to remind a worker to check the condition in the computer cabinet.
It will be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential attributes thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Claims (10)

1. The utility model provides a remove layer-stepping has real-time high temperature monitoring function's calculation rack which characterized in that: this calculate rack includes the cabinet body (1), a plurality of component plywood (4), low pressure heat dissipation mechanism (2), with a plurality of groups pressure temperature measurement mechanism (3) that the layering board matches, the cabinet body (1) is inside from last to having set gradually a plurality of component plywood (4) down, be provided with low pressure heat dissipation mechanism (2), a plurality of groups in the cabinet body (1) pressure temperature measurement mechanism (3) set up in layering board (4) gathers, low pressure heat dissipation mechanism (2) is fixed with layering board (4), and low pressure heat dissipation mechanism (2) is cooled down to cabinet body (1) inside, and low pressure heat dissipation mechanism (2) accelerates the heat dissipation of solution through the low pressure space, pressure temperature measurement mechanism (3) is monitored cabinet body (1) inside temperature to gathering, and pressure temperature measurement mechanism (3) passes through the change of atmospheric pressure monitoring temperature.
2. The mobile hierarchical computing rack with real-time high temperature monitoring function of claim 1, wherein: the low-pressure heat dissipation mechanism (2) comprises a liquid storage cabin (2-1) and a heat dissipation cabin (2-2), the liquid storage cabin (2-1) is arranged at the upper end inside the cabinet body (1), the heat dissipation cabin (2-2) is arranged at the lower end inside the cabinet body (1), and the heat dissipation cabin (2-2) is connected with the liquid storage cabin (2-1) through a pipeline; the pressure and temperature collecting and measuring mechanism (3) comprises a pressure collecting cabin (3-1) and a pressure measuring cabin (3-2), wherein the pressure collecting cabin (3-1) converts the temperature change of the laminated plate (4) into the air pressure change, the pressure measuring cabin (3-2) measures the air pressure change, and the pressure collecting cabin (3-1) is connected with the temperature measuring cabin (3-2) through a pipeline; the laminated board (4) is connected with the cabinet body (1) in a sliding mode, at least four groups of supporting columns (4-1) are arranged on the laminated board (4), locking blocks (5) are arranged at one ends of the four groups of supporting columns (4-1), and the four groups of locking blocks (5) are located in the cabinet body (1).
3. The mobile hierarchical computing rack with real-time high temperature monitoring function of claim 2, wherein: the temperature measuring cabin is characterized in that an annular air bag (3-11) is arranged in the pressure collecting cabin (3-1), a plurality of groups of radiating fins (3-12) are arranged on the upper end face inside the pressure collecting cabin (3-1), a heat insulating layer is arranged on the outer surface of the annular air bag (3-11), the annular air bag (3-11) is connected with the temperature measuring cabin (3-2) through a pipeline, and a pressure sensor (3-21) is arranged in the temperature measuring cabin (3-2).
4. The mobile hierarchical computing rack with real-time high temperature monitoring function of claim 3, wherein: circulation pipes (4-1) are arranged in the plurality of groups of the layered plates (4), the circulation pipes (4-1) are located below the pressure and temperature collecting and measuring mechanism (3), the circulation pipes (4-1) are S-shaped pipelines, short pipes (4-2) are arranged on two sides of each inflection point on the circulation pipes (4-1), the short pipes (4-2) are distributed on two sides of the layered plates (4), the short pipes (4-2) are communicated with the circulation pipes (4-1), electromagnetic valves (4-3) are arranged in the short pipes (4-2), one end of the circulation pipe (4-1) is connected with a pipeline of the liquid storage cabin (2-1), and one ends of the short pipes (4-2) in a plurality of groups on one side of the layered plates (4) are connected with a pipeline of the liquid storage cabin (2-1).
5. The mobile hierarchical computing rack with real-time high temperature monitoring function of claim 4, wherein: the liquid storage tank is characterized in that a support frame (2-11) is arranged in the liquid storage tank (2-1), at least three groups of extraction pumps (2-15) are arranged on the support frame (2-11), the three groups of extraction pumps (2-15) are all connected with a heat dissipation tank (2-2) through pipelines, a No. I liquid inlet pipe (2-12), a No. II liquid inlet pipe (2-13) and a No. III liquid inlet pipe (2-14) are sequentially arranged on one side of the lower portion of the liquid storage tank (2-1) from left to right, a plurality of groups of electromagnetic valves are arranged in the No. I liquid inlet pipe (2-12), the No. II liquid inlet pipe (2-13) and the No. III liquid inlet pipe (2-14), the No. I liquid inlet pipe (2-12) is connected with one end pipeline of circulation pipes (4-1) on a plurality of component laminated plates (4), and the No. II liquid, The III liquid inlet pipe (2-14) is respectively connected with short pipes (4-2) at one side of the component laminated plates (4).
6. The mobile hierarchical computing rack with real-time high temperature monitoring function of claim 5, wherein: the heat dissipation cabin (2-2) is internally provided with a pressurization cabin (2-21), a heat dissipation pump (2-22), a low-pressure pipe (2-23) and a concentration cabin (2-24) from left to right in sequence, one end of the heat dissipation pump (2-22) is connected with the pressurization cabin (2-21) through a pipeline, the other end of the heat dissipation pump (2-22) is connected with the low-pressure pipe (2-23) through a pipeline, the other end of the low-pressure pipe (2-23) is connected with the concentration cabin (2-24) through a pipeline, and the other end of the concentration cabin (2-24) is provided with a No. III liquid outlet pipe (2-25), a No. II liquid outlet pipe (2-26) and a No. I liquid outlet pipe (2-27) from top to bottom.
7. The mobile hierarchical computing rack with real-time high temperature monitoring function of claim 6, wherein: at least three groups of transmission pipes (2-29) are arranged on one side above the pressurizing cabin (2-21), the three groups of transmission pipes (2-29) penetrate through the heat dissipation cabin (2-2) and are respectively connected with the three groups of extraction pumps (2-15) through pipelines, the No. III liquid outlet pipes (2-25) and the No. II liquid outlet pipes (2-26) are respectively connected with short pipes (4-2) on the other side of the laminated plate (4) in a plurality of groups through pipelines, and the No. I liquid outlet pipes (2-27) are connected with the other end of circulation pipes (4-1) on the laminated plate (4) in a plurality of groups through pipelines.
8. The mobile hierarchical computing rack with real-time high temperature monitoring function of claim 7, wherein: a throttle valve (2-28) is arranged between the low-pressure pipe (2-23) and the centralized cabin (2-24), a plurality of groups of heat dissipation plates (2-30) are arranged on the low-pressure pipe (2-23), and the heat dissipation plates (2-30) penetrate through the low-pressure pipe (2-23).
9. The mobile hierarchical computing rack with real-time high temperature monitoring function of claim 8, wherein: the improved cabinet is characterized in that at least four groups of adjusting grooves (1-1) are arranged in the cabinet body (1), every two of the four groups of adjusting grooves (1-1) are in one group and are respectively arranged on opposite end faces in the cabinet body (1), the adjusting grooves (1-1) are C-shaped grooves, gear teeth are arranged on the opposite end faces in the adjusting grooves (1-1), the locking block (5) is located in the adjusting grooves (1-1), and two sides of the locking block (5) are meshed with the gear teeth.
10. The mobile hierarchical computing rack with real-time high temperature monitoring function of claim 9, wherein: the lock block (5) comprises a shell (5-1) and a gravity rod (5-3), wherein a pressing block (5-4), at least two groups of lock plates (5-2) and at least two groups of pulley blocks (5-3) are sequentially arranged in the shell (5-1) from top to bottom, the gravity rod (5-3) is positioned between the two groups of lock plates (5-2), the gravity rod (5-3) penetrates through the shell (5-1), gravity balls (5-5) are arranged at the upper end and the lower end of the gravity rod (5-3), the gravity balls (5-5) at the upper end are respectively in sliding connection with the pressing block (5-4) and the two groups of lock plates (5-2), a plurality of groups of springs (5-6) are arranged between the two groups of lock plates (5-2) and the shell (5-1), and the lower end faces of the two groups of lock plates (5-2) are respectively in sliding connection with the two groups of And one end of each of the two locking plates (5-2) penetrates through the shell (5-1), and gear teeth are arranged on the end face of each of the two locking plates (5-2) penetrating through one end of the shell (5-1).
CN202010489816.0A 2020-06-02 2020-06-02 Mobile layered calculation cabinet with real-time high-temperature monitoring function Active CN111655001B (en)

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Citations (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN207427683U (en) * 2017-11-06 2018-05-29 河南大林橡胶通信器材有限公司 A kind of new network cabinet
CN207939885U (en) * 2018-03-26 2018-10-02 重庆海联职业技术学院 A kind of moisture-proof computer cabinet of multi-function dust-proof
CN209390573U (en) * 2018-10-17 2019-09-13 吉林省智慧互联信息科技有限公司 A kind of network server cabinet
CN209994782U (en) * 2019-05-24 2020-01-24 九州职业技术学院 Heat dissipation device installed on network cabinet
CN210610070U (en) * 2019-05-13 2020-05-22 深圳市博安特科技有限公司 Rack for data computer lab

Patent Citations (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN207427683U (en) * 2017-11-06 2018-05-29 河南大林橡胶通信器材有限公司 A kind of new network cabinet
CN207939885U (en) * 2018-03-26 2018-10-02 重庆海联职业技术学院 A kind of moisture-proof computer cabinet of multi-function dust-proof
CN209390573U (en) * 2018-10-17 2019-09-13 吉林省智慧互联信息科技有限公司 A kind of network server cabinet
CN210610070U (en) * 2019-05-13 2020-05-22 深圳市博安特科技有限公司 Rack for data computer lab
CN209994782U (en) * 2019-05-24 2020-01-24 九州职业技术学院 Heat dissipation device installed on network cabinet

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