CN219717841U - Intelligent intensive energy-saving bus - Google Patents

Abstract

The utility model discloses an intelligent intensive energy-saving bus, which belongs to the technical field of intelligent buses and is characterized in that two side plates are arranged between two connecting top plates, a plurality of groups of copper bars are arranged between the two side plates, a heat radiating plate is arranged on the side wall of the side plate, a plurality of groups of heat radiating fins are arranged on the side wall of the heat radiating plate, the connecting top plates, the side plates and the heat radiating plate can be connected and fixed through insulating bolts, the copper bars can be installed, when the temperature of heat generated by the copper bars is lower, the heat is transferred to the heat radiating plate through the side plates and is brought out of the heat through the heat radiating fins to perform physical heat radiation through contact with air, when the temperature of the generated heat is higher, the heat between the copper bars and the air between the connecting plates and the side plates can be circularly cooled through a heat radiating mechanism, so that the physical heat radiation can be performed when the temperature of the heat generated by the copper bars is lower, and the air circulation refrigeration can be performed when the temperature is higher, and the heat radiation is performed rapidly and efficiently.

Description

An intelligent and intensive energy-saving busbar

Technical field

The utility model relates to the technical field of intelligent busbars, in particular to an intelligent and intensive energy-saving busbar.

Background technique

A busbar refers to a common path on which multiple devices are connected in the form of parallel branches. Therefore, the busbar will carry a large amount of power during use, and the temperature of the busbar will increase as the working time increases. The process of rising, and the increase in temperature will inevitably cause an increase in bus resistance, thereby increasing power consumption. At the same time, long-term high temperature will also cause the normal use of the bus and reduce the normal service life of the bus. Therefore, the heat dissipation of the bus has become indispensable today. Neglected problem.

The current announcement is: Chinese utility model patent CN216252071U, which discloses an intelligent GIS busbar device, including an external light, a busbar passing through the casing, and a first fixing plate fixedly connected to both sides of the front side of the casing, and the first fixed plate on the left side. The servo motor is fixedly connected to the fixed plate. The output end of the servo motor is connected to a screw rod. The screw rod is rotationally connected to the first fixed plate. The first sliding plate is screwed to the screw rod. Both sides of the rear side of the casing are fixedly connected to the servo motor. The second fixed plate has a polished rod fixedly connected between the two sets of second fixed plates. A second sliding plate is slidingly connected to the polished rod. A cleaning component is connected between the first sliding plate and the second sliding plate. The screw rod is driven by a servo motor to rotate. A sliding plate moves along the screw rod. The first sliding plate drives the cleaning component to move. The cleaning component drives the second sliding plate to move along the guide rod. The cleaning component cleans the dust on the top of the external light. It has a good cleaning effect on the top of the shell and can avoid accidents caused by Dust affects the heat dissipation inside the exterior light.

Although this patent has the function of cleaning the busbar casing and preventing dust from affecting the heat dissipation inside the casing, it does not have the function of energy-saving physical heat dissipation and mechanical heat dissipation and cooling of the busbar according to the temperature of the heat generated by the busbar.

Utility model content

1. Technical problems to be solved

The utility model provides an intelligent and intensive energy-saving busbar, aiming to solve the problem that the existing busbar device does not have the functions of energy-saving physical heat dissipation and mechanical heat dissipation and cooling of the busbar according to the temperature of the heat generated by the busbar.

2.Technical solutions

The utility model is realized in this way. An intelligent intensive energy-saving busbar includes a connecting top plate. Two side plates are provided between the two connecting top plates. A plurality of sets of copper bars are provided between the two side plates. , a heat dissipation plate is provided on the side wall of the side plate, and a plurality of sets of heat dissipation fins are provided on the side wall of the heat dissipation plate. The connection between the top plate, the side plate and the heat dissipation plate is fixed by insulating bolts. The connection A heat dissipation mechanism is provided on the top of the top plate;

The heat dissipation mechanism includes an insulating sealing plate, a hot air outlet, a cold air inlet, a connecting pipe, a condenser and a circulating fan. The insulating sealing plate is arranged between the connecting top plate and the side plate. The hot air outlet and the cold air inlet are respectively provided through the The top of the connecting roof is connected to the top. The communication pipe is arranged above the connecting roof and its two ends are connected with the hot air outlet and the cold air inlet respectively. The condenser is bolted to the side wall of the connecting roof and both ends are connected and matched with the communication pipe. The condenser is on the side close to the cold air inlet. The circulating fan is bolted to the side wall connected to the roof and both ends are connected and matched with the communication pipe. The circulating fan is close to the hot air outlet.

In order to insulate and protect the copper bar without affecting the heat dissipation effect of the copper bar, as an intelligent intensive energy-saving busbar of the present invention, a PVC insulating sleeve is sleeved on the side wall of the copper bar. , there are multiple heat dissipation holes on the side wall of the PVC insulation sleeve.

In order to allow space between multiple groups of copper bars to improve the heat dissipation effect of the multiple groups of copper bars, as an intelligent intensive energy-saving busbar of the present invention, multiple groups of copper bars are provided between the multiple groups of copper bars. separate blocks.

In order to improve the heat absorption efficiency of the heat sink, as an intelligent intensive energy-saving busbar of the present invention, a plurality of heat conductive plates are fixedly connected to the side walls of the heat sink plate, and the heat conductive plates and the side plates are touch.

In order to limit the position of the heat conduction plate and facilitate the installation of the heat conduction plate, as an intelligent intensive energy-saving busbar of the present invention, a limit strip is fixedly connected to the side wall of the side plate, and the limit strip is fixedly connected to the side wall of the side plate. The bit strip is in contact with the heat sink.

In order to achieve a stable support effect for the connecting pipe, as an intelligent intensive energy-saving busbar of the present invention, a plurality of sets of support blocks are provided on the top surface of the connecting top plate, and the connecting pipe is sleeved on the support block. internal.

In order to achieve the protective effect of the condenser and the circulating fan, as an intelligent intensive energy-saving busbar of the present invention, two sliders are provided on the top surface of the connecting top plate, and the side walls of the slider are A T-shaped slot is provided on the top, and a protective cover is provided slidingly inside the T-shaped slot.

In order to limit the position of the protective cover inside the T-shaped slot, as an intelligent and intensive energy-saving busbar of the present invention, plugs are inserted into both ends of the T-shaped slot.

3. Beneficial effects

Compared with the existing technology, the beneficial effects of this utility model are:

This intelligent and intensive energy-saving busbar is set up to connect the top plate, side plates, copper bars, heat dissipation plates, heat dissipation fins, insulating bolts and heat dissipation mechanisms. When in use, the insulating bolts can be used to connect the top plate, side plates and heat dissipation plates. The connection is fixed and the copper bar can be installed. When the heat generated by the copper bar is low, the heat is transferred to the heat sink through the side plate, and the heat is brought out through contact with the air through the heat dissipation fins for physical heat dissipation. When the heat generated When the temperature is high, the heat dissipation mechanism can circulate and cool the air between the copper bar and the connecting plate and side plate to quickly and efficiently dissipate heat from the copper bar. In this way, physical heat dissipation can be performed when the heat generated by the copper bar is low. , when the temperature is high, air circulation refrigeration is used to quickly and efficiently dissipate heat from the copper row.

Description of drawings

Figure 1 is an overall structural diagram of the utility model;

Figure 2 is a schematic diagram of the heat conducting plate and limiting strip of the present invention;

Figure 3 is a left side view of the utility model;

Figure 4 is a three-dimensional cross-sectional view at A-A in Figure 3 of the present invention;

Figure 5 is a schematic diagram of the slider, T-shaped groove and protective cover of the present utility model;

Figure 6 is a schematic diagram of the PVC insulation sleeve, heat dissipation holes and separation blocks of the present utility model.

Description of numbers in the figure:

1. Connect the top plate; 21. Side plates; 22. Copper rows; 23. Heat dissipation plate; 24. Radiation fins; 25. Insulation bolts; 3. Heat dissipation mechanism; 31. Insulation sealing plate; 32. Hot air outlet; 33. Air conditioning inlet ; 34. Connecting pipe; 35. Condenser; 36. Circulation fan; 41. PVC insulation sleeve; 42. Heat dissipation hole; 5. Separation block; 6. Heat conduction plate; 7. Limit bar; 8. Support block; 91. Slider; 92. T-shaped slot; 93. Protective cover; 10. Plug.

Detailed ways

In order to make the purpose, technical solutions and advantages of the present utility model more clear, the utility model will be further described in detail below with reference to the drawings and embodiments. It should be understood that the specific embodiments described here are only used to explain the present invention and are not intended to limit the present invention.

In the description of the present invention, it should be understood that the terms "length", "width", "upper", "lower", "front", "back", "left", "right", "vertical" The orientations or positional relationships indicated by "horizontal", "top", "bottom", "inner", "outer", etc. are based on the orientations or positional relationships shown in the drawings, and are only for the convenience of describing the present utility model and simplifying the description. It is not intended to indicate or imply that the device or element referred to must have a specific orientation, be constructed and operate in a specific orientation, and therefore cannot be construed as a limitation of the present invention. In addition, in the description of the present invention, "plurality" means two or more than two, unless otherwise clearly and specifically limited.

Please refer to Figures 1 to 6. The present utility model provides a technical solution: an intelligent and intensive energy-saving busbar, including a connecting top plate 1. Two side plates 21 are provided between the two connecting top plates 1. The two side plates 21 A plurality of sets of copper bars 22 are provided in between, a heat dissipation plate 23 is provided on the side wall of the side plate 21, and a plurality of sets of heat dissipation fins 24 are provided on the side wall of the heat dissipation plate 23, connecting the top plate 1, the side plate 21 and the heat dissipation plate 23. It is connected and fixed by insulating bolts 25, and a heat dissipation mechanism 3 is provided on the top of the connecting top plate 1;

The heat dissipation mechanism 3 includes an insulating sealing plate 31, a hot air outlet 32, a cold air inlet 33, a connecting pipe 34, a condenser 35 and a circulating fan 36. The insulating sealing plate 31 is arranged between the top plate 1 and the side plate 21, and the hot air outlet 32 and the cold air The inlets 33 are respectively arranged through the top of the connecting roof 1. The communication pipe 34 is arranged above the connecting roof 1 and both ends are respectively connected with the hot air outlet 32 and the cold air inlet 33. The condenser 35 is bolted to the side wall of the connecting roof 1 and Both ends are connected and matched with the communication pipe 34. The condenser 35 is close to the side of the cold air inlet 33. The circulation fan 36 is bolted to the side wall connecting the roof 1 and both ends are connected and matched with the communication pipe 34. The circulation fan 36 is close to the hot air outlet 32. side.

In this embodiment, by connecting the top plate 1, the side plates 21, the copper bars 22, the heat dissipation plate 23, the heat dissipation fins 24, the insulating bolts 25 and the heat dissipation mechanism 3, in use, the top plate 1 and the side plates can be connected through the insulating bolts 25. The connection and fixation between the board 21 and the heat sink 23 allows the copper bar 22 to be installed. When the heat generated by the copper bar 22 is at a low temperature, the heat is transferred to the heat sink 23 through the side plate 21 and is connected to the heat sink 24 through the heat sink fins 24. The air contact brings out the heat for physical heat dissipation. When the generated heat temperature is high, the heat dissipation mechanism 3 can circulate and cool the air between the copper bar 22 and the connecting plate and the side plate 21 to quickly and efficiently cool the copper bar 22 Carry out heat dissipation, so that physical heat dissipation can be carried out when the temperature of the heat generated by the copper row 22 is low, and air circulation refrigeration can be performed to quickly and efficiently dissipate the heat of the copper row 22 when the temperature is high; by setting the insulating sealing plate 31, the hot air outlet 32, and the cold air inlet 33. The connecting pipe 34, the condenser 35 and the circulation fan 36 can form a sealed space between the top plate 1, the side plate 21 and the copper bar 22 through the insulating sealing plate 31. When a high internal temperature is detected, the circulation fan 36 The hot air inside is sucked out through the hot air outlet 32 and discharged to the condenser 35. After the condenser 35, the air is converted into cold air and enters the interior through the cold air inlet 33 to cool the copper row 22. In this way, the air circulation of the copper row 22 is realized. Cooling and heat dissipation.

As a technical optimization solution of the present invention, a PVC insulating sleeve 41 is connected to the side wall of the copper bar 22, and a plurality of heat dissipation holes 42 are provided on the side wall of the PVC insulating sleeve 41.

In this embodiment, by arranging PVC insulation sleeve 41 and heat dissipation holes 42, the copper bar 22 can be insulated and protected. At the same time, the heat generated by the copper bar 22 can be quickly dissipated through the heat dissipation holes 42 without affecting the heat dissipation of the copper bar 22. .

As a technical optimization solution of the present invention, multiple partition blocks 5 are provided between multiple groups of copper bars 22 .

In this embodiment, by arranging the partition block 5, there is a space between the multiple groups of copper bars 22, which can improve the heat dissipation effect of the multiple groups of copper bars 22.

As a technical optimization solution of the present invention, a plurality of heat conduction plates 6 are fixedly connected to the side walls of the heat dissipation plate 23, and the heat conduction plates 6 are in contact with the side plates 21.

In this embodiment, by arranging the thermal conductive plate 6, the heat generated by the copper bar 22 can be quickly transferred to the heat dissipation plate 23 for heat dissipation.

As a technical optimization solution of the present invention, the limiting strip 7 is fixedly connected to the side wall of the side plate 21 , and the limiting strip 7 is in contact with the heat dissipation plate 23 .

In this embodiment, by providing the limiting strip 7 , the space between the heat conducting plate 6 and the side plate 21 can be limited, thereby facilitating the installation of the heat conducting plate 6 .

As a technical optimization solution of the present invention, multiple sets of support blocks 8 are provided on the top surface of the connecting top plate 1 , and the communication pipes 34 are sleeved inside the support blocks 8 .

In this embodiment, by providing the support block 8, the communication pipe 34 can be stably supported.

As a technical optimization solution of the present invention, two slide bars 91 are provided on the top surface of the connecting top plate 1. A T-shaped groove 92 is provided on the side wall of the slide bar 91, and a protective cover is provided for sliding inside the T-shaped groove 92. 93.

In this embodiment, the condenser 35 and the circulation fan 36 can be protected by providing the slide bar 91, the T-shaped groove 92 and the protective cover 93.

As a technical optimization solution of the present invention, plugs 10 are respectively inserted into both ends of the T-shaped slot 92 .

In this embodiment, by providing the plug 10, the protective cover 93 inside the T-shaped groove 92 can be limited.

Working principle: First, the top plate 1, the side plate 21 and the heat sink 23 can be connected and fixed through the insulating bolts 25, and the copper bar 22 can be installed. The top plate 1 and the side plate 21 can be connected through the insulating sealing plate 31. A sealed space is formed between the copper bar 22 and the copper bar 22. When the temperature of the heat generated by the copper bar 22 is low, the heat conductive plate 6 quickly transfers the heat generated by the copper bar 22 to the heat sink 23, and the heat is taken out through the contact between the heat dissipation fins 24 and the air. Physical heat dissipation is performed. When a high internal temperature is detected, the circulating fan 36 sucks out the hot air inside through the hot air outlet 32 and discharges it to the condenser 35. After the condenser 35, the hot air is converted into cold air and enters the internal copper exhaust through the cold air inlet 33. 22 performs cooling and heat dissipation. In this way, physical heat dissipation is achieved when the heat generated by the copper bar 22 is low, and air circulation refrigeration is performed to quickly and efficiently dissipate heat from the copper bar 22 when the temperature is high.

The above are only preferred embodiments of the present utility model and are not intended to limit the present utility model. Any modifications, equivalent substitutions and improvements made within the spirit and principles of the present utility model shall be included in the present utility model. within the scope of protection.

Claims (8)

1. An intelligent and intensive energy-saving busbar, including a connecting top plate (1), characterized in that: two side plates (21) are provided between the two connecting top plates (1), and the two side plates (21) are arranged between the two connecting top plates (1). Multiple sets of copper bars (22) are provided between 21), a heat dissipation plate (23) is provided on the side wall of the side plate (21), and a plurality of sets of heat dissipation fins are provided on the side wall of the heat dissipation plate (23). (24), the connecting top plate (1), the side plate (21) and the heat dissipation plate (23) are connected and fixed by insulating bolts (25), and a heat dissipation mechanism (3) is provided on the top of the connecting top plate (1) ; The heat dissipation mechanism (3) includes an insulating sealing plate (31), a hot air outlet (32), a cold air inlet (33), a connecting pipe (34), a condenser (35) and a circulating fan (36). The insulating sealing plate (31) is provided between the connecting top plate (1) and the side plate (21). The hot air outlet (32) and the cold air inlet (33) are respectively provided through the top of the connecting top plate (1). The connecting pipe (34) ) is arranged above the connecting top plate (1) and both ends are connected to the hot air outlet (32) and the cold air inlet (33) respectively. The condenser (35) is bolted to the side wall of the connecting top plate (1) and has both ends. The condenser (35) is connected to and matched with the communication pipe (34) on the side close to the cold air inlet (33). The circulation fan (36) is bolted to the side wall connecting the top plate (1) and both ends are connected to the connecting pipe (34). The pipes (34) are connected and matched, and the circulation fan (36) is close to the side of the hot air outlet (32). 2. An intelligent intensive energy-saving busbar according to claim 1, characterized in that: a PVC insulating sleeve (41) is sleeved on the side wall of the copper bar (22), and the PVC insulating sleeve (41) ) is provided with a plurality of heat dissipation holes (42) on the side wall. 3. An intelligent and intensive energy-saving busbar according to claim 1, characterized in that a plurality of separation blocks (5) are provided between the plurality of groups of copper bars (22). 4. An intelligent and intensive energy-saving busbar according to claim 1, characterized in that: a plurality of heat conduction plates (6) are fixedly connected to the side walls of the heat dissipation plate (23), and the heat conduction plates (6) ) is in contact with the side plate (21). 5. An intelligent intensive energy-saving busbar according to claim 1, characterized in that: a limit bar (7) is fixedly connected to the side wall of the side plate (21), and the limit bar (7) Contact with the heat sink (23). 6. An intelligent and intensive energy-saving busbar according to claim 1, characterized in that: multiple sets of support blocks (8) are provided on the top surface of the connecting top plate (1), and the connecting pipe (34) Socketed inside the support block (8). 7. An intelligent intensive energy-saving busbar according to claim 1, characterized in that: two slide bars (91) are provided on the top surface of the connecting top plate (1), and the slide bars (91) A T-shaped slot (92) is provided on the side wall, and a protective cover (93) is slidably provided inside the T-shaped slot (92). 8. An intelligent intensive energy-saving busbar according to claim 7, characterized in that plugs (10) are inserted into both ends of the T-shaped slot (92).