CN220087838U - Multistage scheduling platform - Google Patents

Abstract

The utility model relates to a multistage dispatching platform, which relates to the technical field of dispatching platforms and comprises a platform body, a fan, a water cooling component, a control component and a dispatching component; the platform body comprises an operation table and a case, the case is fixedly arranged at the bottom end of the operation table, one side of the case is provided with an air inlet, and the other side of the case is provided with an air outlet; the fan is fixedly arranged in the case and is positioned at the opening of the air outlet; the water cooling component is positioned in the case and used for radiating the case; the control component is positioned in the case and used for controlling the water cooling component to work; the scheduling component is positioned in the chassis and is used for carrying out resource allocation on the intelligent building. The utility model has the effect of improving the heat dissipation efficiency of the multi-stage dispatching platform.

Description

Multistage scheduling platform

Technical Field

The utility model relates to the technical field of scheduling platforms, in particular to a multi-stage scheduling platform.

Background

The multi-stage scheduling platform is mainly used for reasonably distributing and arranging resources, personnel, equipment and the like according to actual conditions so as to coordinate the operation of the resources, personnel, equipment and the like, thereby achieving the expected aim and effect; the multi-stage dispatching platform is mainly applied to intelligent building technology, so that the effectiveness of property management is improved.

At present, in order to prevent the service life of internal circuits or electronic components from being influenced by the excessive internal temperature of a common multi-stage dispatching platform, heat dissipation holes are usually formed in the multi-stage dispatching platform.

When the multi-stage dispatching platform is used, the multi-stage dispatching platform is cooled by means of air flow, and the cooling efficiency is low.

Disclosure of Invention

In order to improve the heat dissipation efficiency of the multi-stage scheduling platform, the utility model provides the multi-stage scheduling platform.

The utility model provides a multistage scheduling platform, which adopts the following technical scheme:

a multi-stage dispatching platform comprises a platform body, a fan, a water cooling assembly, a control assembly and a dispatching assembly; the platform body comprises an operation table and a case, the case is fixedly arranged at the bottom end of the operation table, one side of the case is provided with an air inlet, and the other side of the case is provided with an air outlet; the fan is fixedly arranged in the case and is positioned at the opening of the air outlet; the water cooling component is positioned in the case and used for radiating the case; the control component is positioned in the case and used for controlling the water cooling component to work; the scheduling component is positioned in the chassis and is used for carrying out resource allocation on the intelligent building.

Through adopting above-mentioned technical scheme, during the use, scheduling subassembly carries out the resource allocation to intelligent building's mutual end, and the fan is outside with the steam of quick-witted incasement along the gas outlet discharge machine case, and control assembly is according to the work of quick-witted incasement temperature control water-cooling subassembly for when the fan is outside the hot gas of multistage dispatch platform along the gas outlet discharge machine case, water-cooling subassembly carries out the water-cooling to the quick-witted case, makes multistage dispatch platform's radiating efficiency improve.

Optionally, the water cooling assembly comprises a water tank, a water pump, a water inlet pipe, a driving pipe and a water outlet pipe; the water tank is positioned at one side of the chassis, which is close to the air inlet, and is fixedly connected with the chassis; the water pump is fixedly arranged at the top end of the water tank, the water inlet end of the water pump is communicated with the water tank, one end of the water inlet pipe is communicated with the water outlet end of the water pump, the water inlet pipe is used for carrying out water cooling heat dissipation on the machine case, the driving pipe is vertically arranged, the top end of the driving pipe is communicated with the water inlet pipe, and the driving pipe is used for carrying out water cooling heat dissipation on the machine case; one end of the water outlet pipe is communicated with the driving pipe, the other end of the water outlet pipe is communicated with the water tank, and the water outlet pipe is used for carrying out water cooling and heat dissipation on the chassis.

Through adopting above-mentioned technical scheme, after control assembly detects the temperature rise in the quick-witted incasement, control assembly control water pump work, and the water pump flows the liquid in the water tank to the actuating tube through the inlet tube, and the liquid in the actuating tube flows the water tank through the outlet pipe in, and the circulation is changed to the water completion in inlet tube, actuating tube and the outlet pipe, and the quick-witted case can carry out the water-cooling for multistage dispatch platform easily dispels the heat, thereby has improved multistage dispatch platform's radiating efficiency.

Optionally, the control assembly includes a temperature sensor and a controller; the temperature sensor is fixedly arranged in the case and is used for outputting a temperature signal; the controller is fixedly arranged on the water pump and is electrically connected with the temperature sensor, responds to a temperature signal output by the temperature sensor and is used for controlling the water pump to work.

Through adopting above-mentioned technical scheme, when quick-witted case temperature risees, temperature sensor detects the temperature in the quick-witted case, and with temperature signal output to the controller, the controller responds to temperature signal, and control water pump work, and the circulation is accomplished to the water in inlet tube, actuating tube and the outlet pipe is changed for the quick-witted case can carry out water-cooling, thereby has improved multistage dispatch platform's radiating efficiency.

Optionally, the scheduling component comprises a transformer box, a control box, a data storage box and a network server; the bottom of vary voltage case with quick-witted case bottom fixed connection, the control box with the top fixed connection of vary voltage case, the bottom of data storage case with the bottom fixed connection of machine case, and be located one side of vary voltage case, the network server with the top fixed connection of data storage case.

Through adopting above-mentioned technical scheme, when multistage dispatch platform used, the voltage of transformer tank adjustment electrical apparatus for the consumer voltage is easily adjusted, and the network server is used for guaranteeing the stability of video and conversation, and the data storage box is used for the dispatch data to the last month, makes the property company can monitor management to all district property personnel, carries out resource configuration with intelligent building simultaneously.

Optionally, be provided with drive assembly on the drive tube, drive assembly includes drive flabellum and drive shaft, the drive flabellum is located the quick-witted incasement, and vertical setting, the drive flabellum with the coaxial setting of fan, the one end of drive shaft with drive flabellum fixed connection, and the other end with fan fixed connection.

By adopting the technical scheme, when the temperature in the case rises, the water pump works, the liquid in the driving pipe flows downwards to drive the driving fan blades to work, the driving fan blades rotate, the driving fan blades drive the driving shaft to rotate, the driving shaft drives the fan to work, and the fan discharges hot air in the multi-stage dispatching platform out of the case along the air outlet; when the temperature of the case is not increased, the driving component drives the fan to stop working, so that the flow of air in the case is reduced, and dust is not easy to generate in the case.

Optionally, a dust removing component is disposed on the chassis, and the dust removing component is used for removing dust from air entering the chassis.

Through adopting above-mentioned technical scheme, when the intra-chassis air flows, the dust removal subassembly removes dust to the air that gets into the machine case to make the intra-chassis be difficult for getting into the dust.

Optionally, the dust removing assembly comprises a dust removing box and a partition plate; the dust removing box is positioned on one side of the chassis, which is close to the air inlet, and is fixedly connected with the chassis, an air inlet is formed in one side of the dust removing box, an air outlet is formed in the other side of the dust removing box, and the air outlet is communicated with the air inlet; the baffle is vertical to be set up in the dust removal case, and is located the air intake with between the air outlet, the top of baffle with dust removal case fixed connection, the baffle bottom with the dust removal case bottom leaves the distance, the dust removal incasement is preset with liquid, and the liquid level is located the baffle bottom with between the air intake.

Through adopting above-mentioned technical scheme, when the intra-chassis air flows, the air outside the machine case flows to the dust removal incasement through the air intake, and the liquid in the dust removal incasement adsorbs the dust in the air, and the air after the absorption flows to the intra-chassis from the air outlet for the intra-chassis is difficult for getting into the dust.

Optionally, the dust removal subassembly is still including the sponge that absorbs water, the sponge that absorbs water sets up vertically, and is located the opening part of air outlet.

Through adopting above-mentioned technical scheme, the dust removal subassembly is still including the sponge that absorbs water, the sponge that absorbs water is vertical to be set up, and is located the opening part of air outlet.

In summary, the present utility model includes at least one of the following beneficial technical effects:

the fan and the water cooling assembly are arranged, so that the multistage dispatching platform is easy to dissipate heat, and the heat dissipation efficiency of the multistage dispatching platform is improved;

the multi-level scheduling platform can carry out resource allocation on the intelligent building by setting the scheduling component;

through setting up the dust removal subassembly for the quick-witted incasement is difficult for getting into the dust.

Drawings

FIG. 1 is a schematic diagram of an embodiment of the present utility model;

FIG. 2 is a cross-sectional view of an embodiment of the present utility model;

FIG. 3 is an enlarged view of a portion of FIG. 2 at A;

fig. 4 is a partial enlarged view at B in fig. 2.

Reference numerals illustrate:

1. a platform body; 11. an operation table; 12. a chassis; 121. an air inlet; 122. an air outlet;

2. a fan;

3. a water cooling assembly; 31. a water tank; 32. a water pump; 33. a water inlet pipe; 34. a driving tube; 35. a water outlet pipe;

4. a control assembly; 41. a temperature sensor; 42. a controller;

5. a scheduling component; 51. a transformer box; 52. a control box; 53. a data storage box; 54. a network server;

6. a drive assembly; 61. driving the fan blades; 62. a drive shaft;

7. a dust removal assembly; 71. a dust removal box; 711. an air inlet; 712. an air outlet; 72. a partition plate; 73. a water absorbing sponge.

Detailed Description

The utility model is described in further detail below with reference to fig. 1-4.

The embodiment of the utility model discloses a multi-stage scheduling platform. Referring to fig. 1 to 4, a multi-stage scheduling platform includes a platform body 1, a fan 2, a water cooling assembly 3, a control assembly 4, a scheduling assembly 5, a driving assembly 6, and a dust removing assembly 7. The platform body 1 comprises an operation table 11 and a case 12, wherein the case 12 is vertically arranged at the bottom end of the operation table 11 and is fixedly connected with the operation table 11. Fan 2 is located within chassis 12 and is configured to dissipate heat from chassis 12 by cooling air. The water cooling assembly 3 is located in the case 12, and is used for performing water cooling heat dissipation on the case 12. The control assembly 4 is located in the case 12 and is used for controlling the water cooling assembly 3 to work. The scheduling component 5 is located within the chassis 12 and is used to configure resources for the intelligent building. The driving assembly 6 is located in the case 12 and is used for driving the fan 2 to rotate. The dust removal assembly 7 is located within the chassis 12 and is used to remove dust from air entering the chassis 12.

When the intelligent building intelligent dust removal system is used, the scheduling component 5 performs resource allocation on the interactive end of the intelligent building, the control component 4 controls the water cooling component 3 to work according to the temperature in the case 12, the water cooling component 3 performs water cooling and cooling on the case 12, the driving component 6 drives the fan 2 to rotate, the fan 2 discharges hot air in the case 12 out of the case 12, and the dust removal component 7 removes dust from air entering the case 12.

Referring to fig. 3 and 4, an air inlet 121 is formed at one side of the cabinet 12, and the air inlet 121 has a rectangular hole shape. An air outlet 122 is formed in one side, away from the air inlet 121, of the case 12, and the air outlet 122 is rectangular. The fan 2 is fixedly connected with the case 12, and is vertically disposed at an opening of the air outlet 122.

Referring to fig. 1 and 2, the water cooling assembly 3 includes a water tank 31, a water pump 32, a water inlet pipe 33, a driving pipe 34, and a water outlet pipe 35. The water tank 31 is rectangular, is vertically arranged, is positioned on one side of the case 12 close to the air inlet 121, and is fixedly connected with the case 12. The water pump 32 is vertically arranged and fixedly arranged at the top end of the water tank 31, and the water inlet end of the water pump 32 is communicated with the water tank 31.

The water inlet pipe 33 is circular tubular, one end of the water inlet pipe 33 is communicated with the water outlet pipe 35 of the water pump 32, and the other end is embedded at the top end of the case 12. The driving pipe 34 is rectangular and tubular, and is vertically arranged, and the top end of the driving pipe 34 is communicated with one end of the water inlet pipe 33, which is far away from the water pump 32. The water outlet pipe 35 is circular tubular, one end of the water outlet pipe 35 is communicated with the driving pipe 34, and the other end is communicated with the water tank 31.

Referring to fig. 2, the control assembly 4 includes a temperature sensor 41 and a controller 42. The temperature sensor 41 is fixedly provided in the cabinet 12 and is used for outputting a temperature signal. The controller 42 is fixedly arranged on the water pump 32 and is electrically connected with the temperature sensor 41, and the controller 42 is responsive to a temperature signal output by the temperature sensor 41 and is used for controlling the water pump 32 to work.

When the temperature of the case 12 increases, the temperature sensor 41 detects the temperature in the case 12 and outputs a temperature signal to the controller 42, the controller 42 responds to the temperature signal and controls the water pump 32 to operate, the water pump 32 flows the liquid in the water tank 31 to the driving pipe 34 through the water inlet pipe 33, the liquid in the driving pipe 34 flows into the water tank 31 through the water outlet pipe 35, and the water in the water inlet pipe 33, the driving pipe 34 and the water outlet pipe 35 is circularly replaced, so that the case 12 can be cooled by water.

Referring to fig. 2, the dispatch assembly 5 includes a transformer box 51, a control box 52, a data storage box 53, and a web server 54. The transformer box 51 is rectangular box-shaped and vertically arranged, and the bottom end of the transformer is fixedly connected with the bottom end of the case 12. The control box 52 is rectangular box-shaped and vertically arranged, and the bottom end of the control box 52 is fixedly connected with the top end of the transformer box 51.

The data storage box 53 is rectangular and vertically arranged, and the bottom end of the data storage box 53 is fixedly connected with the bottom end of the case 12 and is positioned on one side of the transformer box 51. The web server 54 is rectangular box-shaped and vertically arranged, and the bottom end of the web server 54 is fixedly connected with the top end of the data storage box 53.

When the multi-stage dispatching platform is used, the voltage of the electric appliance is adjusted by the voltage transformation box 51, so that the voltage of the electric appliance is easy to adjust, the network server 54 is used for guaranteeing stability of video and conversation, the data storage box 53 is used for dispatching data in a month, so that a property company can monitor and manage all community property personnel, and meanwhile, resource allocation is carried out with an intelligent building.

Referring to fig. 4, the driving assembly 6 includes driving blades 61 and a driving shaft 62. The driving fan blade 61 is vertically arranged and is positioned in the case 12, and the driving fan blade 61 is coaxially arranged with the fan 2. The driving shaft 62 is in a circular rod shape and is horizontally arranged, one end of the driving shaft 62 is fixedly connected with the driving fan blades 61, and the other end of the driving shaft 62 is fixedly connected with the fan 2.

When the temperature in the machine case 12 rises, the water pump 32 works, liquid in the driving pipe 34 flows downwards to drive the driving fan blades 61 to work, the driving fan blades 61 rotate, the driving fan blades 61 drive the driving shaft 62 to rotate, the driving shaft 62 drives the fan 2 to work, and the fan 2 discharges hot air in the multi-stage dispatching platform out of the machine case 12 along the air outlet 122; when the temperature of the case 12 is not increased, the driving component 6 drives the fan 2 to stop working, so that the air flow in the case 12 is reduced, and dust is not easy to generate in the case 12.

Referring to fig. 1 to 3, the dust removing assembly 7 includes a dust removing box 71, a partition 72, and a water absorbing sponge 73. The dust removing box 71 is rectangular and vertically arranged, and the dust removing box 71 is positioned on one side of the case 12 close to the air inlet 121 and fixedly connected with the case 12. An air inlet 711 is formed in one side, away from the case 12, of the dust removal box 71, and the air inlet 711 is rectangular hole-shaped. An air outlet 712 is formed in one side, close to the case 12, of the dust removal box 71, the air outlet 712 is rectangular hole-shaped and is communicated with the air inlet 121, and the air outlet 712 is opposite to the air inlet 711.

The baffle 72 is rectangular plate-shaped, and vertically arranged in the dust removal box 71, the top end of the baffle 72 is fixedly connected with the top end of the dust removal box 71, the bottom end of the baffle is spaced from the bottom wall of the dust removal box 71, and under the action of the baffle 72, air enters the dust removal box 71 from the air inlet 711 and flows to the air outlet 712 along a V-shaped track. The dust removing box 71 is provided with liquid, and the liquid level is positioned between the bottom end of the partition plate 72 and the air inlet 711. The water absorbing sponge 73 is vertically arranged and is positioned at the opening of the air outlet 712, and the water absorbing sponge 73 is used for absorbing moisture in the air flowing out of the air outlet 712.

When air in the case 12 flows, air outside the case 12 flows into the dust removal case 71 through the air inlet 711, dust in the air is adsorbed by liquid in the dust removal case 71, the adsorbed air flows into the case 12 from the air outlet 712, and water molecules in the air are adsorbed by the water absorption sponge 73, so that dust is not easy to generate in the case 12.

The implementation principle of the multistage scheduling platform in the embodiment of the utility model is as follows: when the multi-stage dispatching platform is used, the voltage of the electric appliance is regulated by the voltage transformation box 51, the network server 54 is used for guaranteeing the stability of videos and calls, the data storage box 53 is used for dispatching data in a month, when the temperature of the machine case 12 is increased, the temperature sensor 41 detects the temperature in the machine case 12 and outputs a temperature signal to the controller 42, the controller 42 responds to the temperature signal and controls the water pump 32 to work, the water pump 32 flows liquid in the water tank 31 to the driving pipe 34 through the water inlet pipe 33, the liquid in the driving pipe 34 flows into the water tank 31 through the water outlet pipe 35, when the liquid in the driving pipe 34 flows downwards, the driving fan blade 61 is driven to work, the driving fan blade 61 is driven to rotate, the driving fan 62 is driven to drive the driving shaft 62 to work, the fan 2 discharges hot air in the multi-stage dispatching platform out of the machine case 12 along the air outlet 122, air outside the machine case 12 flows into the dust removal box 71 through the air inlet 711, the liquid in the dust removal box 71 adsorbs dust in the air, the adsorbed air flows into the machine case 12 from the air outlet 712, and the water absorption 73 adsorbs water molecules in the air, so that the multi-stage dispatching platform can easily dissipate heat, and the heat when the multi-stage dispatching platform is cooled, and the multi-stage dispatching platform is enabled.

The above embodiments are not intended to limit the scope of the present utility model, so: all equivalent changes in structure, shape and principle of the utility model should be covered in the scope of protection of the utility model.

Claims (8)

1. A multi-level scheduling platform, characterized by: comprises a platform body (1), a fan (2), a water cooling component (3), a control component (4) and a scheduling component (5); the platform body (1) comprises an operation table (11) and a machine case (12), wherein the machine case (12) is fixedly arranged at the bottom end of the operation table (11), one side of the machine case (12) is provided with an air inlet (121), and the other side of the machine case is provided with an air outlet (122); the fan (2) is fixedly arranged in the case (12) and is positioned at the opening of the air outlet (122); the water cooling assembly (3) is positioned in the case (12) and is used for radiating heat of the case (12); the control assembly (4) is positioned in the case (12) and is used for controlling the water cooling assembly (3) to work; the scheduling component (5) is positioned in the chassis (12) and is used for carrying out resource allocation on the intelligent building.

2. The multi-level scheduling platform of claim 1, wherein: the water cooling assembly (3) comprises a water tank (31), a water pump (32), a water inlet pipe (33), a driving pipe (34) and a water outlet pipe (35); the water tank (31) is positioned at one side of the machine case (12) close to the air inlet (121) and is fixedly connected with the machine case (12); the water pump (32) is fixedly arranged at the top end of the water tank (31), the water inlet end of the water pump (32) is communicated with the water tank (31), one end of the water inlet pipe (33) is communicated with the water outlet end of the water pump (32), the water inlet pipe (33) is used for carrying out water cooling and heat dissipation on the machine case (12), the driving pipe (34) is vertically arranged, the top end of the driving pipe is communicated with the water inlet pipe (33), and the driving pipe (34) is used for carrying out water cooling and heat dissipation on the machine case (12); one end of the water outlet pipe (35) is communicated with the driving pipe (34), the other end of the water outlet pipe is communicated with the water tank (31), and the water outlet pipe (35) is used for carrying out water cooling heat dissipation on the machine case (12).

3. The multi-level scheduling platform of claim 2, wherein: the control assembly (4) comprises a temperature sensor (41) and a controller (42); the temperature sensor (41) is fixedly arranged in the case (12) and is used for outputting a temperature signal; the controller (42) is fixedly arranged on the water pump (32) and is electrically connected with the temperature sensor (41), and the controller (42) responds to a temperature signal output by the temperature sensor (41) and is used for controlling the water pump (32) to work.

4. A multi-level scheduling platform according to claim 3, wherein: the dispatching assembly (5) comprises a transformation box (51), a control box (52), a data storage box (53) and a network server (54); the bottom of vary voltage case (51) with quick-witted case (12) bottom fixed connection, control box (52) with the top fixed connection of vary voltage case (51), the bottom of data storage case (53) with the bottom fixed connection of machine case (12), and be located one side of vary voltage case (51), network server (54) with the top fixed connection of data storage case (53).

5. The multi-level scheduling platform of claim 2, wherein: the novel fan is characterized in that a driving assembly (6) is arranged on the driving tube (34), the driving assembly (6) comprises driving fan blades (61) and a driving shaft (62), the driving fan blades (61) are arranged in the case (12) and are vertically arranged, the driving fan blades (61) are coaxially arranged with the fan (2), one end of the driving shaft (62) is fixedly connected with the driving fan blades (61), and the other end of the driving shaft is fixedly connected with the fan (2).

6. The multi-level scheduling platform of claim 1, wherein: the dust removal assembly (7) is arranged on the case (12), and the dust removal assembly (7) is used for removing dust from air entering the case (12).

7. The multi-level scheduling platform of claim 6, wherein: the dust removing assembly (7) comprises a dust removing box (71) and a partition plate (72); the dust removing box (71) is positioned on one side of the machine case (12) close to the air inlet (121) and is fixedly connected with the machine case (12), an air inlet (711) is formed in one side of the dust removing box (71), an air outlet (712) is formed in the other side of the dust removing box, and the air outlet (712) is communicated with the air inlet (121); the dust removal device is characterized in that the partition plate (72) is vertically arranged in the dust removal box (71) and is positioned between the air inlet (711) and the air outlet (712), the top end of the partition plate (72) is fixedly connected with the dust removal box (71), the bottom end of the partition plate (72) is kept away from the bottom end of the dust removal box (71), liquid is preset in the dust removal box (71), and the liquid level is positioned between the bottom end of the partition plate (72) and the air inlet (711).

8. The multi-level scheduling platform of claim 7, wherein: the dust removal assembly (7) further comprises a water absorption sponge (73), wherein the water absorption sponge (73) is vertically arranged and is positioned at the opening of the air outlet (712).