CN219087696U - High-heat-dissipation power saving equipment - Google Patents

Abstract

The utility model relates to a power technical field specifically discloses a high heat dissipation's power saving equipment, which comprises an outer shell, power supply unit, radiator unit and layering subassembly, set up in the shell and hold the chamber, power supply unit, radiator unit and layering subassembly all set up in holding the intracavity, layering subassembly will hold the chamber and separate into a plurality of placing chambers, power supply unit can place respectively in different placing chambers, avoid power supply unit's place position too concentrated for heat concentrates in same position, lead to local temperature too high, the condition of power supply unit fusing appears, power supply unit distributes with radiator unit and sets up, make the heat dispersion that holds the intracavity portion even, easy radiator unit dispels the heat, thereby improve power saving equipment's radiating efficiency. The power supply storage device has the effect of improving the heat dissipation efficiency of the power supply storage device.

Description

High-heat-dissipation power saving equipment

Technical Field

The application relates to the technical field of power supplies, in particular to a power supply saving device with high heat dissipation.

Background

The energy storage equipment is used as a movable power supply, can supply power for an electric appliance at any time and any place, and when the energy storage equipment is used for supplying power, the internal components of the energy storage equipment can generate heat with different degrees, and the larger the power is, the more the heat is generated, so that the related circuits or circuit boards in the power supply device are fused, and potential safety hazards are caused.

The energy storage power supply in the related art comprises a shell and a heat radiation component, wherein the heat radiation component is arranged in a containing cavity of the shell, the air inlet is opposite to the air outlet, the heat radiation component is positioned at the air outlet, the heat radiation component radiates heat for a plurality of components in the containing cavity, so that potential safety hazards are avoided, but cold air can only flow from a local area when the heat radiation component radiates heat in the energy storage power supply in the related art, and the heat radiation efficiency is low.

Therefore, when the energy storage power supply in the technical scheme works, the defect that the heat dissipation efficiency is low so that the loss is caused by internal components of the energy storage power supply exists.

Disclosure of Invention

In order to improve the radiating efficiency of the power saving device, the application provides a power saving device with high radiating performance.

The power saving equipment with high heat dissipation performance adopts the following technical scheme:

a high heat dissipation power saving device comprising:

a housing provided with a receiving cavity;

the power supply assembly is arranged in the accommodating cavity and is used for supplying power to the electric appliance;

the heat dissipation assembly is arranged in the accommodating cavity and is used for dissipating heat of the power supply assembly;

the layering assembly is arranged in the accommodating cavity, the accommodating cavity is divided into a plurality of accommodating cavities, and the heat dissipation assembly and the power supply assembly are placed in different accommodating cavities respectively.

Based on the above-mentioned technical scheme, the shell has been offered and has been held the chamber to be convenient for with radiating component and power supply module installation place the intracavity, the layering subassembly will hold the chamber and separate into a plurality of chambers of placing, and power supply module can be placed respectively in the different chambers of placing, avoids power supply module's place position too concentrated, makes the heat concentrate in same position, leads to local high temperature, appears the condition of power supply module fusing. The power supply assembly and the heat dissipation assembly are distributed, so that heat inside the accommodating cavity is dispersed uniformly, and the heat dissipation assembly is easy to dissipate heat, so that the heat dissipation efficiency of the power supply storage device is improved.

Preferably, the layered assembly comprises a first partition plate, the first partition plate divides the accommodating cavity into two accommodating cavities, the power assembly comprises a battery, an inverter and an uninterruptible power supply, the battery is located in one accommodating cavity, and the heat dissipation assembly, the inverter and the uninterruptible power supply are located in the other accommodating cavity.

Based on the technical scheme, the first division plate divides the accommodating cavity into two accommodating cavities, electricity is arranged in different cavities due to the battery, the inverter and the uninterrupted power source, and when the power supply assembly works, heat generated by the battery, the inverter and the uninterrupted power source is uniformly distributed, so that the heat dissipation assembly is convenient to dissipate heat.

Preferably, the placement chamber comprises a first placement chamber and a second placement chamber, the first placement chamber is located below the second placement chamber, and the battery is located in the first placement chamber.

Based on the technical scheme, the battery is placed in the first placement cavity, and the gravity center of the power saving equipment can be lowered, so that the placement of the power saving equipment is more stable.

Preferably, the first partition plate is provided with a bearing plate, the heat dissipation assembly, the inverter and the uninterruptible power supply are all arranged on the bearing plate, the bearing plate is connected with the first partition plate through a connecting piece, and a heat dissipation gap is formed between the bearing plate and the first partition plate.

Based on the technical scheme, a heat dissipation gap is formed between the bearing plate and the first partition plate, and heat generated by the battery positioned below during operation can be evenly distributed through the heat dissipation gap, so that heat dissipation of the heat dissipation assembly is facilitated.

Preferably, the two groups of the bearing plates are arranged adjacently, the heat dissipation assembly is arranged on one group of the bearing plates, and the inverter and the uninterruptible power supply are arranged on the other group of the bearing plates.

Based on the technical scheme, the radiating component, the inverter and the uninterrupted power source are arranged in a scattered manner, and the radiating component, the inverter and the uninterrupted power source are matched with each other to realize efficient heat radiation.

Preferably, the layered assembly further comprises a second divider dividing the receiving cavity into a third placement cavity, and the power assembly further comprises a power management system located within the third placement cavity.

Based on the technical scheme, the power management system is placed in the third placement cavity, layered arrangement of the power management system, the battery, the inverter and the uninterruptible power supply is realized, and heat dissipation is facilitated.

Preferably, the second placing chamber is located between the first placing chamber and the third placing chamber, and the heat dissipation component is located in the second placing chamber.

Based on the technical scheme, the heat dissipation assembly is arranged between the first placing cavity and the third placing cavity, so that heat dissipation of the heat dissipation assembly is facilitated.

Preferably, the housing comprises a ventilation plate, and a plurality of ventilation holes are formed in the ventilation plate.

Based on the above technical scheme, the ventilation hole on the ventilation board is used for ventilation.

Preferably, the ventilation board is connected with a mounting board, the mounting board with the setting of first division board looks perpendicular, be provided with connecting portion on the mounting board, connecting portion with first division board is connected.

Based on the technical scheme, the connecting part on the mounting plate is convenient for the mounting of the first division plate.

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

1. the power supply components are respectively placed in different placing cavities, so that the excessive concentration of heat generated during the operation of the power supply components is avoided, and the power supply components and the heat dissipation components are distributed, so that the heat inside the accommodating cavity is uniformly dispersed, the heat dissipation of the heat dissipation components is easy, and the heat dissipation efficiency of the power supply storage equipment is improved;

2. the battery is placed in the first placing cavity, and the heat dissipation assembly, the inverter and the uninterruptible power supply are placed in the second placing cavity, so that the heat dissipation assembly can dissipate heat conveniently;

3. the heat dissipation gap between the bearing plate and the first partition plate is beneficial to heat dissipation.

Drawings

Fig. 1 is a schematic perspective view showing a power saving apparatus with high heat dissipation in an embodiment of the present application.

Fig. 2 is a schematic diagram of a part of a structure of a power saving device with high heat dissipation in an embodiment of the present application, which is mainly used for an internal structure of the power saving device with high heat dissipation.

Fig. 3 is a schematic diagram illustrating the structure of fig. 2 from different viewing angles.

Reference numerals illustrate: 10. a housing; 11. a receiving chamber; 12. a first placement chamber; 13. a second placement chamber; 14. a third placement chamber; 15. a heat dissipation gap; 16. a ventilation board; 17. a mounting plate; 171. a connection part; 18. a connecting plate; 19. a vent hole; 20. a power supply assembly; 21. a battery; 22. an inverter; 23. an uninterruptible power supply; 24. a power management system; 30. a heat dissipation assembly; 31. a front fan; 32. a rear fan; 40. a layering assembly; 41. a first partition plate; 42. a second partition plate; 43. and a bearing plate.

Detailed Description

The present application is described in further detail below in conjunction with figures 1-3.

The embodiment of the application discloses a power saving device with high heat dissipation.

Referring to fig. 1 and 2, the power saving device with high heat dissipation comprises a housing 10, a power component 20, a heat dissipation component 30 and a layering component 40, wherein the housing 10 is provided with a containing cavity 11, the layering component 40 divides the containing cavity 11 into a plurality of placing cavities, the power component 20 and the heat dissipation component 30 are respectively placed in different placing cavities, heat is generated when the power component 20 works and dissipated into the placing cavities, and the heat dissipation component 30 dissipates the heat in the placing cavities.

Referring to fig. 2, the layering assembly 40 includes a first partition plate 41 and a second partition plate 42, the first partition plate 41 and the second partition plate 42 being disposed in parallel, the first partition plate 41 and the second partition plate 42 dividing the accommodating chamber 11 into three placement chambers, the uppermost placement chamber being the third placement chamber 14, the lowermost placement chamber being the first placement chamber 12, and the placement chamber between the first placement chamber 12 and the third placement chamber 14 being the second placement chamber 13.

Referring to fig. 2, the power supply assembly 20 includes a battery 21 and a power management system 24, and the battery 21 is placed in the first placement chamber 12, and the gravity center of the power saving device can be lowered by placing the battery 21 in the first placement chamber 12 due to the weight bias of the battery 21, so that the power saving device is more stable when placed. The power management system 24 is disposed in the third placement chamber 14, and the power management system 24 is configured to detect a state of the battery 21, thereby improving the utilization rate of the battery 21.

Referring to fig. 2 and 3, two sets of bearing plates 43 are disposed on the first partition plate 41, the two sets of bearing plates 43 are disposed adjacently, a gap is disposed between the two sets of bearing plates 43, the bearing plates 43 are connected with the first partition plate 41 through a connecting piece, wherein the connecting piece can be a fastening structure such as a screw rod, a bolt, etc., a heat dissipation gap 15 exists between the bearing plates 43 and the first partition plate 41, and heat generated when the battery 21 in the first placement chamber 12 works is evenly dissipated through the heat dissipation gap 15, so that the heat dissipation component 30 dissipates heat.

Referring to fig. 2 and 3, the heat dissipation assembly 30 is disposed on one set of the bearing plates 43, the inverter 22 and the uninterruptible power supply 23 are disposed on the other set of the bearing plates 43, and the heat dissipation assembly 30, the inverter 22 and the uninterruptible power supply 23 are disposed in a dispersed manner, and cooperate with each other to achieve efficient heat dissipation.

Referring to fig. 2 and 3, the heat dissipation assembly 30 includes four sets of heat dissipation fans, each of which is located in the second placement chamber 13, the four sets of heat dissipation fans are divided into three sets of front fans 31 and one set of rear fans 32, the rear fans 32 and the three sets of front fans 31 are disposed at opposite sides, and the three sets of front fans 31 are disposed at equal intervals and correspond to the inverter 22, the uninterruptible power supply 23 and the rear fans 32, respectively, so as to facilitate heat dissipation.

Referring to fig. 1 and 2, the housing 10 includes two sets of ventilation plates 16, two sets of mounting plates 17 and two sets of connecting plates 18, the ventilation plates 16, the mounting plates 17 and the connecting plates 18 are connected and combined to form the accommodating cavity 11, the two sets of ventilation plates 16 are disposed on two opposite sides, and a plurality of ventilation holes 19 are formed in the ventilation plates 16 so that the heat dissipation component 30 dissipates heat.

Referring to fig. 2, the mounting plate 17 is disposed perpendicular to the first partition plate 41, and a connection portion 171 is provided on the mounting plate 17, and the connection portion 171 is connected to the first partition plate 41 to facilitate the mounting of the first partition plate 41.

The implementation principle of the power saving equipment with high heat dissipation performance is as follows: the first partition plate 41 and the second partition plate 42 partition the accommodation chamber 11 into the first placement chamber 12, the second placement chamber 13, and the third placement chamber 14, and the battery 21 is placed in the first placement chamber 12 so that the center of gravity of the power supply storage device is lowered; the inverter 22, the uninterruptible power supply 23 and the heat dissipation assembly 30 are placed in the second placement chamber 13, the power management system 24 is placed in the third placement chamber 14, and the heat generated during the operation of the power assembly 20 is uniformly dispersed in a separated placement manner, so that the heat dissipation of the heat dissipation assembly 30 is easy, and the heat dissipation efficiency of the power storage device is improved.

The foregoing are all preferred embodiments of the present application, and are not intended to limit the scope of the present application in any way, therefore: all equivalent changes in structure, shape and principle of this application should be covered in the protection scope of this application.

Claims (9)

1. A high heat dissipation power saving device, comprising:

a housing (10) provided with a receiving chamber (11);

a power supply assembly (20) arranged in the accommodating cavity (11) and used for supplying power to the electric appliance;

the heat dissipation assembly (30) is arranged in the accommodating cavity (11) and is used for dissipating heat of the power supply assembly (20);

the layering assembly (40) is arranged in the accommodating cavity (11), and the accommodating cavity (11) is divided into a plurality of placing cavities so as to facilitate the heat dissipation assembly (30) and the power supply assembly (20) to be placed in different placing cavities respectively.

2. The high heat dissipation power storage device as defined in claim 1, wherein the layered assembly (40) includes a first partition plate (41), the first partition plate (41) partitions the accommodating chamber (11) into two placement chambers, the power assembly (20) includes a battery (21), an inverter (22) and an uninterruptible power supply (23), the battery (21) is located in one of the placement chambers, and the heat dissipation assembly (30), the inverter (22) and the uninterruptible power supply (23) are located in the other placement chamber.

3. The high heat dissipation power saving device according to claim 2, characterized in that the placement chambers comprise a first placement chamber (12) and a second placement chamber (13), the first placement chamber (12) being located below the second placement chamber (13), the battery (21) being located within the first placement chamber (12).

4. The high heat dissipation power saving device as set forth in claim 2, wherein a carrier plate (43) is provided on the first partition plate (41), the heat dissipation assembly (30), the inverter (22) and the uninterruptible power supply (23) are all provided on the carrier plate (43), the carrier plate (43) is connected with the first partition plate (41) through a connecting piece, and a heat dissipation gap (15) is formed between the carrier plate (43) and the first partition plate (41).

5. The high heat dissipation power saving device as set forth in claim 4, wherein the carrier plates (43) are provided in two groups, the two groups of the carrier plates (43) are disposed adjacently, the heat dissipation assembly (30) is disposed on one group of the carrier plates (43), and the inverter (22) and the uninterruptible power supply (23) are disposed on the other group of the carrier plates (43).

6. A high heat dissipation power saving device according to claim 3, wherein the layered assembly (40) further comprises a second dividing plate (42), the second dividing plate (42) dividing the receiving cavity (11) into a third placing chamber (14), the power assembly (20) further comprising a power management system (24), the power management system (24) being located within the third placing chamber (14).

7. The high thermal power savings device of claim 6, wherein the second placement chamber (13) is located between the first placement chamber (12) and the third placement chamber (14), the heat dissipating assembly (30) being located within the second placement chamber (13).

8. The high thermal power saving device according to claim 2, wherein the housing (10) comprises a ventilation plate (16), and the ventilation plate (16) is provided with a plurality of ventilation holes (19).

9. The high heat radiation power saving device according to claim 8, wherein the ventilation plate (16) is connected with a mounting plate (17), the mounting plate (17) is perpendicular to the first partition plate (41), a connection portion (171) is provided on the mounting plate (17), and the connection portion (171) is connected with the first partition plate (41).

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