CN114093717A - Energy-saving intelligent relay - Google Patents

Abstract

The invention relates to the technical field of relays, in particular to an energy-saving intelligent relay, which comprises: the relay boxing device comprises a base and a relay boxing body, wherein the relay boxing body is arranged on the outer side of the base and is connected with the base through a supporting assembly; the heat dissipation mechanism is arranged between the relay encasement and the base and used for discharging hot air in the relay encasement; the cooling mechanism is arranged on the outer side of the heat dissipation mechanism and is used for matching with the heat dissipation mechanism to realize the cooling of the relay boxing; wherein, heat dissipation mechanism includes: air guide radiator unit and coupling assembling through setting up heat dissipation mechanism and cooling body, at the in-process that accelerates the air flow, can be located the heat in the relay vanning is discharged rapidly, and heat dissipation mechanism and cooling body cooperation can carry out multiple cooling to the air that gets into in the relay vanning simultaneously to guarantee radiating high efficiency and validity.

Description

Energy-saving intelligent relay

Technical Field

The invention relates to the technical field of relays, in particular to an energy-saving intelligent relay.

Background

With the continuous promotion of the innovation of the electric power system in China, the development of the electric equipment and the electric power industry in China is rapid at present, and the scale and the power generation capacity of a power grid are listed as the first in the world; the urban and rural power utilization same-network price is realized, the power utilization problem of people without power is solved, a diversified power market system is formed, the electric appliance is an important basic element with large and wide range in a power grid, the intelligent power grid construction brings opportunities for the development of the intelligent electric appliance, the intellectualization of the power grid is closely related to the intellectualization of the switching electric appliance, and the relay is a switching electric appliance with large and wide range and is mainly used for frequently switching on or switching off an alternating current main circuit and can be controlled remotely.

Traditional relay often places the relay module and uses in the case, and when the relay module used, produced a large amount of heats, traditional relay device can't dispel the heat to inside, leads to internal relay to damage, consequently, to above current situation, an energy-saving intelligent relay of urgent need development to overcome not enough in the current practical application.

Disclosure of Invention

The present invention aims to provide an energy-saving intelligent relay to solve the problems in the background art.

In order to achieve the purpose, the invention provides the following technical scheme:

an energy-saving intelligent relay comprising:

the relay boxing device comprises a base and a relay boxing body, wherein the relay boxing body is arranged on the outer side of the base and is connected with the base through a supporting assembly;

the heat dissipation mechanism is arranged between the relay encasement and the base and used for discharging hot air in the relay encasement;

the cooling mechanism is arranged on the outer side of the heat dissipation mechanism and is used for matching with the heat dissipation mechanism to realize the cooling of the relay boxing;

wherein, heat dissipation mechanism includes:

the air guide heat dissipation assembly is arranged on the inner side of the base and used for driving outside air to flow and performing heat dissipation and purification;

and the connecting assembly is arranged between the air guide heat dissipation assembly and the relay box packing and is connected with the cooling mechanism for matching the hot air discharged by the heat guide heat dissipation assembly and the cooling mechanism and located in the relay box packing.

Compared with the prior art, the invention has the beneficial effects that:

when the device is in operation, the air guide heat dissipation assembly can absorb air, purify and cool the sucked air, and guide the processed outside air into the relay boxing inner side through the connecting assembly, so that the heat in the relay boxing can be quickly discharged, the heat dissipation of the device is realized, the cooling mechanism can cool the air in the connecting assembly again when the connecting assembly carries out air flow conveying, and the heat dissipation capacity and the cooling efficiency of the device are improved. Thereby ensuring the high efficiency and effectiveness of heat dissipation.

Drawings

Fig. 1 is a front view of an energy-saving intelligent relay.

Fig. 2 is a top view of a base in the energy-saving intelligent relay.

Fig. 3 is a top view of a heat dissipation box in the energy-saving intelligent relay.

Fig. 4 is a schematic structural diagram of a cooling plate in the energy-saving intelligent relay.

In the figure: 1-base, 2-support plate, 3-connecting box, 4-radiating box, 5-air inlet pipe, 6-air guide pipe, 7-air pump, 8-air pipe, 9-flow distribution plate, 10-fixed pipe, 11-movable pipe, 12-relay box, 13-elastic piece, 14-relay body, 15-temperature sensor, 16-air outlet hole, 17-connecting plate, 18-slide block, 19-slide groove, 20-water inlet pipe, 21-first water guide groove, 22-cooling plate, 23-cooling pipe, 24-water outlet pipe, 25-second water guide groove, 26-radiating hole, 27-water storage tank, 28-reflux box, 29-radiator, 30-heat absorbing block, 31-partition plate, 32-radiating fin, 33-a filter screen.

Detailed Description

The technical solution of the present patent will be described in further detail with reference to the following embodiments.

Reference will now be made in detail to embodiments of the present patent, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to the same or similar elements or elements having the same or similar function throughout. The embodiments described below with reference to the drawings are exemplary only for the purpose of explaining the present patent and are not to be construed as limiting the present patent.

Referring to fig. 1, in an embodiment of the present invention, an energy-saving intelligent relay includes: the relay box 12 is arranged on the outer side of the base 1 and is connected with the base 1 through a supporting component; the heat dissipation mechanism is arranged between the relay container 12 and the base 1 and used for discharging hot air in the relay container 12; the cooling mechanism is arranged on the outer side of the heat dissipation mechanism and is used for being matched with the heat dissipation mechanism to realize the cooling of the relay casing 12; wherein, heat dissipation mechanism includes: the air guide heat dissipation assembly is arranged on the inner side of the base 1 and used for driving outside air to flow, dissipate heat and purify; and the connecting assembly is arranged between the air guide heat dissipation assembly and the relay packing box 12 and is connected with the cooling mechanism for matching with the hot air discharged by the heat guide heat dissipation assembly and the cooling mechanism and located in the relay packing box 12.

In the embodiment, when the device is in operation, the air guide heat dissipation assembly can absorb air, purify and cool the sucked air, and guide the processed outside air into the inside of the relay packing box 12 through the connecting assembly, so that the heat in the relay packing box 12 can be rapidly discharged, thereby realizing the heat dissipation of the device, the cooling mechanism can cool the air in the connecting assembly again while the connecting assembly carries out air flow conveying, thereby improving the heat dissipation capacity and the cooling efficiency of the device, compared with the prior relay device, the heat dissipation device can not dissipate the heat inside of the relay device, and by arranging the heat dissipation mechanism and the cooling mechanism, the heat in the relay packing box 12 can be rapidly discharged in the process of accelerating the air flow, and meanwhile, the heat dissipation mechanism can be matched with the cooling mechanism to carry out multiple cooling on the air entering the relay packing box 12, thereby ensuring the high efficiency and effectiveness of heat dissipation.

In one embodiment of the present invention, the air guide and heat dissipation assembly includes: the heat dissipation assemblies are arranged at two ends of the inner side of the base 1, are fixedly connected with the base 1 through air inlet pipes 5 and are used for purifying and cooling the outside air entering the device; the air pump 7 is arranged between the heat dissipation assemblies on the two sides, and the input end of the air pump 7 is connected with the heat dissipation assemblies through the air guide pipes 6; and the gas pipe 8 is arranged between the connecting component and the air pump 7 and fixedly connected with the base 1.

In this embodiment, the equal fixed connection in 1 inboard both ends of base is provided with intake pipe 5, the intake pipe 5 other end is in with the setting the 1 inboard radiator unit of base links to each other, both sides be provided with air pump 7 between the radiator unit, air pump 7 input with fixed connection is provided with air duct 6 between the radiator unit output, through setting up air guide radiator unit, under the effect of air pump 7, can utilize radiator unit to filter and cool off the air in the access device in, thereby make the air flow rate in the relay vanning 12 not only can accelerate to the outside air, but also can carry out direct cooling to the relay body 14 in the relay vanning 12, thereby reinforcing means's radiating effect.

In an embodiment of the present invention, referring to fig. 3, the heat dissipation assembly includes: the heat dissipation box 4 is arranged on the inner side of the base 1, and two ends of the heat dissipation box 4 are respectively connected with the air inlet pipe 5 and the air guide pipe 6; the heat absorption block 30 is fixedly connected to the inner side of the heat dissipation box 4, and a cavity is formed in the inner side of the heat absorption block 30; the partition plates 31 are arranged on the inner side of the cavity in a staggered mode, and are fixedly connected with the heat absorbing blocks 30; the filter screen 33 is detachably connected between two adjacent partition plates 31; and the heat radiating fins 32 are arranged between the heat absorbing block 32 and the wall of the heat radiating box 4, and are used for matching with the heat absorbing block 30 to realize heat radiation of air entering the heat radiating box 4.

In this embodiment, the heat dissipating fins 32 are fixedly connected to the outer sides of the two ends of the heat absorbing block 30, openings for the heat dissipating fins to pass through are formed in the walls of the two ends of the heat dissipating box 4, external air enters the inner side of the cavity located inside the heat absorbing block 30 after entering the heat dissipating box 4, the filter screen 33 located inside the cavity purifies the air, the heat absorbing block 30 can absorb heat contained in the air to cool the air, and the heat dissipating fins 32 can dissipate the heat of the heat absorbing block 30, so that the heat dissipating efficiency of the heat absorbing block 30 on the air is ensured, the effective heat dissipation of the air on the relay body 14 located in the relay casing 12 is ensured, and the service life of the device is effectively prolonged;

in addition, a plurality of heat dissipation holes 26 are arranged on the wall of the heat dissipation box 4.

In one embodiment of the present invention, the connection assembly includes: the connecting box 3 is fixedly connected with the base 1; the flow dividing piece is fixedly connected to the inner side of the connecting box 3, is connected with the gas conveying pipe 8 and is used for matching with the flow dividing piece to realize air dispersion; one end of the movable pipe 11 is slidably connected with the shunt piece, is fixedly connected with the relay packing box 12, and is used for being matched with the air guide heat dissipation assembly to discharge hot air in the relay packing box 12; and the elastic piece 13 is arranged between the relay packing box 12 and the connecting box 3 and used for realizing the shock absorption protection of the relay packing box 12.

In this embodiment, the shunt member includes a shunt plate 9 fixedly connected to the inner side of the connection box 3, the bottom end of the shunt plate 9 is fixedly connected to the gas pipe 8, the outer side of the other end of the shunt plate 9 is fixedly connected to a plurality of fixed tubes 10, the fixed tubes 10 are slidably connected to movable tubes 11 fixedly connected to the outer side of the relay casing 12, the fixed tubes 10 are connected to the cooling mechanism, the elastic member 13 is a spring, one end of the spring is fixedly connected to the relay casing 12, the other end of the spring is fixedly connected to the connection box 3, by providing the elastic member 13, the influence of vibration on the relay casing 12 can be reduced, the service life of the relay body 14 in the relay casing 12 can be prolonged, by providing the connection assembly, the air processed by the heat dissipation assembly can be guided into the relay casing 12, therefore, the discharge of hot air in the relay packing box 12 is accelerated, and the effective heat dissipation of the relay body 14 in the relay packing box 12 is realized.

In one embodiment of the present invention, referring to fig. 1, fig. 2 and fig. 4, the cooling mechanism includes: the water storage tank 27 is fixedly connected to the inner side of the base 1, and an infusion part is arranged on the inner side of the water storage tank 27; the cooling assembly is arranged on the outer side of the flow dividing piece and used for completing secondary cooling of air positioned on the inner side of the flow dividing piece; the backflow piece is arranged on the inner side of the base 1 and is connected with the output end of the cooling assembly; and the radiator 29 is arranged between the reflux piece and the water storage tank 27 and is used for realizing the circulating flow and heat dissipation of the cooling liquid.

In this embodiment, the infusion part includes a water pump fixedly connected to the inner side of the water storage tank 27, the output end of the water pump 27 is connected to the first water chute 21 arranged at the inner side of the supporting component through a water inlet pipe 20, in addition, the backflow part includes a second water chute 25 arranged at the inner side of the other end of the supporting component, the second water chute 25 is connected to the backflow tank 28 arranged at the inner side of the base 1 through a water outlet pipe 24, wherein a cooling component is arranged between the first water chute 21 and the second water chute 25, a radiator 29 is arranged between the backflow tank 28 and the water storage tank 27, and the cooling liquid in the circulating flow can be radiated by arranging the radiator 29, so that the cooling component can continuously and effectively cool the backflow part, the effectiveness of the device for secondary air cooling is ensured, and the heat radiation efficiency of the device is improved, and reduces the waste of resources.

In one embodiment of the invention, the cooling assembly comprises: the cooling plate 22 is fixedly connected to the outer side of the flow dividing piece and used for absorbing heat on the pipe wall of the flow dividing piece; cooling tube 23, cooling tube 23 encircles and locates the reposition of redundant personnel outside, with cooling plate 22 fixed connection, and with infusion piece and backward flow piece link to each other for the realization is to the cooling of cooling plate 22.

In this embodiment, cooling tube 23 encircles and locates the fixed pipe 10 outside, cooling tube 23 both ends respectively with first guiding gutter 21 and second guiding gutter 25 link to each other, cooling tube 23 outside fixed connection is provided with cooling plate 22, through setting up cooling module, can be to being located air in the coupling assembling carries out the secondary and cools down to the radiating efficiency of equipment has been promoted.

In one embodiment of the invention, the support assembly comprises: the supporting plates 2 are fixedly connected to the outer sides of the two ends of the base 1, and sliding grooves 19 are formed in the inner sides of the supporting plates 2; the sliding block 18 is fixedly connected with the sliding groove 19 through the sliding block 18; and the connecting plate 17 is fixedly connected between the sliding block 18 and the relay packing box 12.

In this embodiment, through setting up supporting component, can provide a stable support to relay vanning 12, and can cooperate elastic component 13 realizes the shock attenuation to relay vanning 12, has strengthened the stability and the security of device.

In one embodiment of the invention, a relay body 14 is fixedly connected to the inner side of the relay packing case 12, a temperature sensor 15 is fixedly connected to the inner side case wall of the relay packing case 12, a plurality of exhaust holes 16 are respectively formed in the case walls on the two sides of the relay packing case 12, a dust screen is detachably connected to the inner sides of the exhaust holes 16, and the detachable connection is an adhesive connection.

The energy-saving intelligent relay can rapidly discharge heat in the relay packing box 12 in the process of accelerating air flow by arranging the heat dissipation mechanism and the cooling mechanism, and simultaneously, the heat dissipation mechanism and the cooling mechanism are matched to carry out multiple cooling on air entering the relay packing box 12 so as to ensure the high efficiency and effectiveness of heat dissipation, and the air guide heat dissipation assembly is arranged to guide outside air into the device under the action of the air pump 7, so that the air entering the device can be filtered and cooled by the heat dissipation assembly, thus the air flow rate in the relay packing box 12 can be accelerated by the outside air, the relay body 14 in the relay packing box 12 can be directly cooled, the heat dissipation effect of the device is enhanced, the outside air can enter the cavity inside the heat absorption block 30 after entering the heat dissipation box 4, the filter screen 33 arranged on the inner side of the cavity can purify the air, the heat absorption block 30 can absorb the heat contained in the air to realize the cooling of the air, the heat dissipation fins 32 can dissipate the heat of the heat absorption block 30, so that the heat dissipation efficiency of the heat absorption block 30 to the air is ensured, and further the effective heat dissipation of the air to the relay body 14 positioned in the relay box 12 is ensured, so that the service life of the device is effectively prolonged, the air processed by the heat dissipation component can be guided into the relay box 12 by arranging the connecting component, so that the discharge of hot air in the relay box 12 is accelerated, the effective heat dissipation of the relay body 14 positioned in the relay box 12 is realized, the cooling liquid in the circulating flow can be dissipated by arranging the radiator 29, so that the cooling component can continuously and effectively cool a backflow component, and the effectiveness of the device for secondary cooling of the air is ensured, do benefit to lifting means's radiating efficiency to reduce the waste of resource, through setting up cooling module, can be to lieing in air in the coupling assembling carries out the secondary and cools down, thereby has promoted the radiating efficiency of equipment, through setting up supporting component, can provide a stable support to relay vanning 12, and can cooperate the elastic component 13 realizes the shock attenuation to relay vanning 12, has strengthened the stability and the security of device.

The above is only a preferred embodiment of the present invention, and it should be noted that, for those skilled in the art, it is possible to make several variations and modifications without departing from the concept of the present invention, and these should be considered as the protection scope of the present invention, which will not affect the effect of the implementation of the present invention and the utility of the patent.

Claims (7)

1. An energy-saving intelligent relay, characterized by comprising:

the relay boxing device comprises a base and a relay boxing body, wherein the relay boxing body is arranged on the outer side of the base and is connected with the base through a supporting assembly;

the heat dissipation mechanism is arranged between the relay encasement and the base and used for discharging hot air in the relay encasement;

the cooling mechanism is arranged on the outer side of the heat dissipation mechanism and is used for matching with the heat dissipation mechanism to realize the cooling of the relay boxing;

wherein, heat dissipation mechanism includes:

the air guide heat dissipation assembly is arranged on the inner side of the base and used for driving outside air to flow and performing heat dissipation and purification;

and the connecting assembly is arranged between the air guide heat dissipation assembly and the relay box packing and is connected with the cooling mechanism for matching the hot air discharged by the heat guide heat dissipation assembly and the cooling mechanism and located in the relay box packing.

2. The energy-saving intelligent relay according to claim 1, wherein the air guide heat dissipation assembly comprises:

the heat dissipation assemblies are arranged at two ends of the inner side of the base, are fixedly connected with the base through air inlet pipes and are used for purifying and cooling the outside air entering the device;

the air pump is arranged between the heat dissipation assemblies on the two sides, and the input end of the air pump is connected with the heat dissipation assemblies through air guide pipes;

the air pipe is arranged between the connecting component and the air pump and fixedly connected with the base.

3. The energy-saving smart relay according to claim 2, wherein the heat sink assembly comprises:

the heat dissipation box is arranged on the inner side of the base, and two ends of the heat dissipation box are respectively connected with the air inlet pipe and the air guide pipe;

the heat absorption block is fixedly connected to the inner side of the heat dissipation box, and a cavity is formed in the inner side of the heat absorption block;

the partition plates are arranged on the inner side of the cavity in a staggered mode and are fixedly connected with the heat absorbing blocks;

the filter screen is detachably connected between two adjacent partition plates;

and the heat dissipation fins are arranged between the heat absorption block and the wall of the heat dissipation box and are used for being matched with the heat absorption block to dissipate heat of air entering the heat dissipation box.

4. The energy-saving intelligent relay according to claim 3, wherein the connection assembly comprises:

the connecting box is fixedly connected with the base;

the flow dividing piece is fixedly connected to the inner side of the connecting box, is connected with the gas conveying pipe and is used for matching with the flow dividing piece to realize air dispersion;

one end of the movable pipe is connected with the shunt piece in a sliding mode, is fixedly connected with the relay packing box and is used for being matched with the air guide heat dissipation assembly to discharge hot air in the relay packing box;

the elastic piece is arranged between the relay boxing and the connecting box and used for achieving shock absorption protection of the relay boxing.

5. The energy-saving smart relay according to claim 4, wherein the cooling mechanism comprises:

the water storage tank is fixedly connected to the inner side of the base, and an infusion piece is arranged on the inner side of the water storage tank;

the cooling assembly is arranged on the outer side of the flow dividing piece and used for completing secondary cooling of air positioned on the inner side of the flow dividing piece;

the backflow piece is arranged on the inner side of the base and is connected with the output end of the cooling assembly;

the radiator is arranged between the reflux piece and the water storage tank and used for realizing the circulating flow and heat dissipation of the cooling liquid.

6. The energy-saving smart relay according to claim 5, wherein the cooling assembly comprises:

the cooling plate is fixedly connected to the outer side of the shunt piece and used for absorbing heat on the pipe wall of the shunt piece;

the cooling tube, the cooling tube is around locating the reposition of redundant personnel piece outside, with cooling plate fixed connection, and with infusion piece and backward flow piece link to each other for realize the cooling to the cooling plate.

7. The energy saving smart relay of claim 6, wherein the support assembly comprises:

the supporting plates are fixedly connected to the outer sides of the two ends of the base, and sliding grooves are formed in the inner sides of the supporting plates;

the sliding block is fixedly connected with the sliding chute;

and the connecting plate is fixedly connected between the sliding block and the relay box.

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