CN110957655B

CN110957655B - Electric energy management and coordination integrated control device

Info

Publication number: CN110957655B
Application number: CN201911024497.XA
Authority: CN
Inventors: 雷洋; 周丽丽; 柳云华; 王慧阳
Original assignee: Shanxi Zhongbo Xinchuang Technology Co ltd; Yuncheng Power Supply Co of State Grid Shanxi Electric Power Co Ltd
Current assignee: Shanxi Zhongbo Xinchuang Technology Co ltd; Yuncheng Power Supply Co of State Grid Shanxi Electric Power Co Ltd
Priority date: 2019-10-25
Filing date: 2019-10-25
Publication date: 2021-12-28
Anticipated expiration: 2039-10-25
Also published as: CN110957655A

Abstract

The invention is suitable for the technical field of electric energy management, and provides an electric energy management and coordination integrated control device, which comprises a body assembly and a sliding assembly used for moving the body assembly, wherein the sliding assembly comprises a first lifting device, a second lifting device, a coupler and a servo motor, the servo motor is positioned on one side of the first lifting device, which is far away from the second lifting device, an output shaft of the servo motor penetrates through the first lifting device and is rotationally connected with the first lifting device, the coupler is positioned between the first lifting device and the second lifting device, and the first lifting device and the second lifting device are connected through the coupler; through setting up the sliding assembly, when servo motor starts, through the effect of shaft coupling, make first worm with the second worm rises to promote support piece slides on the second spout, thereby adjust the position of LED screen.

Description

Electric energy management and coordination integrated control device

Technical Field

The invention belongs to the technical field of electric energy management, and particularly relates to an electric energy management and coordination integrated control device.

Background

The power energy management system software provides a basic platform for real-time data acquisition, on-off state detection and remote control of the system by means of a computer, communication equipment, a metering protection device and the like. The power monitoring system can provide an integral solution of 'monitoring integration' for enterprises, mainly comprises a real-time historical database, industrial automation configuration software, power automation software, 'soft' control strategy software, a communication gateway server, OPC products, Web portal tools and the like, and can be widely applied to enterprise informatization, DCS systems, PLC systems and SCADA systems.

When the existing control device is used, a computer can emit a large amount of heat, the problem of crash can be caused frequently when the computer is not timely processed, and on the other hand, when the existing computer is matched with a screen to display data, the computer cannot be moved frequently, so that inconvenient viewing experience is brought to users.

Disclosure of Invention

The invention provides an integrated control device for electric energy management and coordination, and aims to solve the problems that a computer can generate a large amount of heat when the existing control device is used, and the computer often crashes due to untimely processing, and on the other hand, the existing computer often cannot move when matched with screen display data, so that inconvenient viewing experience is brought to users.

The invention is realized in this way, the electric energy management and coordination integrated control device, including the body assembly and the sliding assembly used for making the body assembly move, the body assembly includes the organism, support piece, computer, LED screen and heat-dissipating assembly, the said support piece locates at one side of the said organism, and the said support piece and the said organism are connected slidably, the said computer locates at the upper surface of the said support piece, and the said computer and the said support piece are connected fixedly, the said LED screen locates at one side of the said computer, and the said LED screen and the said support piece are connected fixedly, the said LED screen and the said organism are connected electrically with the said computer through the electric wire;

the heat dissipation assembly is positioned in the computer, and heat dissipation holes are formed in two sides of the computer;

the sliding assembly comprises a first lifting device, a second lifting device, a coupler and a servo motor, the first lifting device and the second lifting device are arranged on the lower surface of the supporting piece in parallel and are fixedly connected with the supporting piece, the servo motor is positioned on one side, far away from the second lifting device, of the first lifting device, an output shaft of the servo motor penetrates through the first lifting device and is rotatably connected with the first lifting device, the coupler is positioned between the first lifting device and the second lifting device, and the first lifting device and the second lifting device are connected through the coupler;

the first lifting device comprises a first shell, a driving shaft, a third gear, a first tapered roller bearing and a first worm, the third gear is located inside the first shell, the first tapered roller bearing is provided with two first tapered roller bearings which are located on two sides of the third gear respectively, the inner side wall of each first tapered roller bearing is fixedly connected with the third gear, the driving shaft penetrates through the first tapered roller bearing and the third gear and is fixedly connected with an output shaft of the servo motor, and the first worm is located in front of the third gear and meshed with the third gear.

Preferably, the heat dissipation assembly comprises two bearings, a screw and a first gear, the two bearings are respectively embedded on two sides of the computer, the screw is located between the two bearings and is rotatably connected with the bearings, and the first gear is located on the outer side wall of the screw and is fixedly connected with the screw;

a second gear is arranged below the first gear, the first gear and the second gear are meshed with each other, a driving motor is arranged on one side of the second gear, an output shaft of the driving motor is fixedly connected with the second gear, a nut is connected to a rod wall of the screw in a threaded fit manner, a motor is arranged on the upper surface of the nut, the motor is fixedly connected with the nut, and fan blades are fixed on the output shaft of the motor;

the lower surface of the nut is provided with a sliding block, and a first sliding groove matched with the sliding block is formed in the lower surface of the inner portion of the computer.

Preferably, a second sliding groove is formed in one side, connected with the supporting piece, of the machine body, and the supporting piece is connected with the machine body in a sliding mode through the second sliding groove.

Preferably, the second lifting device comprises a housing, a driven shaft, a fourth gear, a second tapered roller bearing, a second worm and an angular contact bearing, the angular contact bearing is embedded in one side of the housing and is fixedly connected with the housing, and the fourth gear is located inside the housing;

the second tapered roller bearings are arranged in two numbers, the two second tapered roller bearings are respectively located on two sides of the fourth gear, the inner side wall of the second tapered roller bearing is fixedly connected with the fourth gear, the driven shaft penetrates through the second tapered roller bearing and the fourth gear and is in rotating connection with the angular contact bearing, the second worm is located in front of the fourth gear, and the second worm is in meshing connection with the fourth gear.

Preferably, the shaft coupling comprises pivot and second casing, the one end of pivot is run through one side of first elevating gear, and with driving shaft fixed connection, the other end of pivot runs through the second casing and second elevating gear, and with driven shaft fixed connection.

Preferably, the lower surface of the machine body is provided with a fixed seat.

Compared with the prior art, the invention has the beneficial effects that: by arranging the heat dissipation assembly, when the temperature in the computer is too high, the motor is started, the motor drives the fan blades to rotate, and meanwhile, the driving motor is turned on, the driving motor drives the second gear to rotate, so that the first gear and the second gear are meshed with each other, the screw rod is driven to rotate, the nut is driven to move leftwards or rightwards, the fan blades rotating at high speed are driven to move, air is exchanged with the outside through the heat dissipation holes, the heat dissipation effect is increased, and the heat dissipation of the computer is faster; through setting up the sliding assembly, when servo motor starts, through the effect of shaft coupling, make first worm with the second worm rises to promote support piece slides on the second spout, thereby adjust the position of LED screen.

Drawings

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a schematic diagram of the internal structure of a computer part according to the present invention;

FIG. 3 is a schematic view of the internal structure of the first lifting device according to the present invention;

FIG. 4 is a schematic view of the internal structure of the second lifting device according to the present invention;

FIG. 5 is a front view of a third gear of the present invention;

FIG. 6 is a cross-sectional view of the coupling of the present invention;

in the figure: 1-body component, 11-body, 12-supporting piece, 13-computer, 131-first sliding groove, 14-LED screen, 15-heat dissipation component, 151-bearing, 152-screw rod, 153-first gear, 154-second gear, 155-driving motor, 156-nut, 157-motor, 158-fan blade, 159-sliding block, 16-second sliding groove, 17-fixed seat, 2-sliding component, 21-first lifting device, 211-first shell, 212-driving shaft, 213-third gear, 214-first conical roller bearing, 215-first worm, 22-second lifting device, 221-shell, 222-driven shaft, 223-fourth gear, 224-second conical roller bearing, 225-second worm, 226-angular contact bearing, 23-coupling, 231-rotating shaft, 232-second shell and 24-servo motor.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention is described in further detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

Referring to fig. 1-6, the power management and coordination integrated control device includes a body assembly 1 and a sliding assembly 2 for moving the body assembly 1, the body assembly 1 includes a body 11, a support member 12, a computer 13, an LED screen 14 and a heat dissipation assembly 15, the support member 12 is located at one side of the body 11, the support member 12 is slidably connected with the body 11, the computer 13 is located on the upper surface of the support member 12, the computer 13 is fixedly connected with the support member 12, the LED screen 14 is located at one side of the computer 13, the LED screen 14 is fixedly connected with the support member 12, and both the LED screen 14 and the body 11 are electrically connected with the computer 13 through wires;

the heat dissipation assembly 15 is located inside the computer 13, and heat dissipation holes are formed in both sides of the computer 13;

the sliding assembly 2 comprises a first lifting device 21, a second lifting device 22, a coupler 23 and a servo motor 24, wherein the first lifting device 21 and the second lifting device 22 are arranged on the lower surface of the support 12 in parallel and are fixedly connected with the support 12, the servo motor 24 is positioned on one side of the first lifting device 21 far away from the second lifting device 22, an output shaft of the servo motor 24 penetrates through the first lifting device 21 and is rotatably connected with the first lifting device 21, the coupler 23 is positioned between the first lifting device 21 and the second lifting device 22, and the first lifting device 21 and the second lifting device 22 are connected through the coupler 23.

In the present embodiment, the type of the driving motor 155 is Y2-160M1-8, the type of the motor 157 is RF-300C, and the type of the servo motor 24 is EDSMT-2T 110; the third gear 213 and the fourth gear 223 have the same internal structure;

by arranging the machine body 11, the computer 13 and the LED screen 14, data stored in the machine body 11 are transmitted to the computer 13, the computer 13 transmits the data to the LED screen 14, and the numerical value is displayed through the LED screen 14, so that the user can watch the data conveniently;

by arranging the bearing 151, under the action of the bearing 151, on one hand, the screw 152 can rotate in the computer 13, on the other hand, the rotation friction of the screw 152 is reduced under the action of the bearing 151, and by arranging the first gear 153 and the second gear 154, the load of the screw 152 is reduced under the action of the two gears, and meanwhile, the problem that the output shaft of the driving motor 155 is damaged due to the fact that the driving motor 155 is directly connected with the screw 152 is avoided;

by arranging the first lifting device 21, when the servo motor 24 is started, the driving shaft 212 is driven to rotate, the driving shaft 212 drives the third gear 213 to rotate on the first tapered roller bearing 214, so that the axial load capacity is greatly reduced, then, under the action of the coupler 23, torque is transmitted, and an overload protection effect is achieved, so that the driven shaft 222 in the second lifting device 22 rotates, and further, the first worm 215 and the second worm 225 are lifted through meshing with the gears, so that the LED screen 14 is driven to lift.

In this embodiment, when the heat inside the computer 13 is too much, the motor 157 is turned on, so that the output shaft of the motor 157 drives the fan blades 158 to rotate, and the driving motor 155 is turned on, so that the output shaft of the driving motor 155 rotates to drive the second gear 154 to rotate, at this time, the second gear 154 and the first gear 153 are engaged with each other to drive the screw 152 to rotate, so that the nut 156 moves leftwards or rightwards, when the fan blades 158 move while rotating, the air circulation inside the computer 13 is accelerated, and the air is exchanged with the outside air through the heat dissipation holes, so that the temperature inside the computer 13 is reduced; when an operator needs to adjust the height of the LED screen 14, the servo motor 24 is started, so that the servo motor 24 drives the driving shaft 212 to rotate, the first worm 215 and the third gear 213 are meshed with each other, and therefore ascend, and simultaneously, the driven shaft 222 is driven to rotate through the action of the coupler 23, so that the second worm 225 and the fourth gear 223 are meshed with each other, and therefore ascend, so that the support member 12 is pushed to move on the machine body 11 under the action of the first worm 215 and the second worm 225, and the operator can conveniently adjust the height of the LED screen 14. Further, the first lifting device 21 includes a first housing 211, a driving shaft 212, two third gears 213, two first tapered roller bearings 214 and a first worm 215, the third gear 213 is located inside the first housing 211, the two first tapered roller bearings 214 are located on two sides of the third gear 213, an inner side wall of each first tapered roller bearing 214 is fixedly connected with the third gear 213, the driving shaft 212 penetrates through the first tapered roller bearings 214 and the third gear 213 and is fixedly connected with an output shaft of the servo motor 24, the first worm 215 is located in front of the third gear 213, and the first worm 215 and the third gear 213 are connected in a meshing manner.

In the present embodiment, as shown in fig. 3, the driving shaft 212 is fixedly connected to the third gear 213, so that when the driving shaft 212 rotates, the third gear 213 is driven to rotate; by arranging the first tapered roller bearing 214, because the inner ring and the outer ring of the bearing are both provided with tapered raceways, the bearing can bear radial load and unidirectional axial load, so that the third gear 213 has higher rotation efficiency; when the servo motor 24 is activated, the output shaft of the servo motor 24 rotates, thereby rotating the driving shaft 212, and then the driving shaft 212 drives the third gear 213 to rotate on the first tapered roller bearing 214, thereby greatly reducing the axial load capacity and the rotation error, and then the first worm 215 and the third gear 213 are engaged with each other, thereby driving the support member 12 to ascend.

Further, the heat dissipation assembly 15 includes two bearings 151, a screw 152 and a first gear 153, the two bearings 151 are respectively embedded on two sides of the computer 13, the screw 152 is located between the two bearings 151 and is rotatably connected with the bearings 151, and the first gear 153 is located on an outer side wall of the screw 152 and is fixedly connected with the screw 152;

a second gear 154 is arranged below the first gear 153, the first gear 153 and the second gear 154 are meshed with each other, a driving motor 155 is arranged on one side of the second gear 154, an output shaft of the driving motor 155 is fixedly connected with the second gear 154, a nut 156 is connected to a rod wall of the screw 152 in a threaded fit manner, a motor 157 is arranged on the upper surface of the nut 156, the motor 157 is fixedly connected with the nut 156, and fan blades 158 are fixed on the output shaft of the motor 157;

the lower surface of the nut 156 is provided with a sliding block 159, and the inner lower surface of the computer 13 is provided with a first sliding slot 131 matched with the sliding block 159.

In the present embodiment, as shown in fig. 2, by providing the bearing 151, under the action of the bearing 151, on one hand, the screw 152 can rotate in the computer 13, on the other hand, the rotational friction of the screw 152 is reduced under the action of the bearing 151, and by providing the first gear 153 and the second gear 154, the load of the screw 152 is reduced under the action of the two gears, and meanwhile, the problem that the output shaft of the driving motor 155 is damaged due to the direct connection of the driving motor 155 and the screw 152 is avoided;

by arranging the sliding block 159 and the first sliding chute 131, the weight of the nut 156 is supported under the action of the sliding block 159, and on the other hand, under the action of the sliding block 159 and the first sliding chute 131, the movement of the nut 156 is smoother, the generation of shaking and shaking is avoided, and the rotation speed of the fan blade 158 is higher;

when the motor 157 is turned on, the output shaft of the motor 157 rotates to rotate the fan blades 158, when the driving motor 155 is turned on, the second gear 154 is driven to rotate, the second gear 154 and the first gear 153 are meshed with each other to drive the screw 152 to rotate, and further the nut 156 is driven to move leftwards or rightwards, so that when the motor 157 and the driving motor 155 are used in a matched manner, the air circulation inside the computer 13 is accelerated, and the heat is exchanged with the outside air through the heat dissipation holes, and the temperature inside the computer 13 is reduced.

Further, a second sliding groove 16 is formed at a side where the machine body 11 and the supporting member 12 are connected, and the supporting member 12 is slidably connected with the machine body 11 through the second sliding groove 16.

In the present embodiment, by providing the second slide groove 16, friction generated when the support member 12 ascends or descends is reduced by the second slide groove 16, thereby making the apparatus durable for a longer time.

Further, the second lifting device 22 includes a housing 221, a driven shaft 222, a fourth gear 223, a second tapered roller bearing 224, a second worm 225 and an angular contact bearing 226, the angular contact bearing 226 is embedded in one side of the housing 221 and is fixedly connected with the housing 221, and the fourth gear 223 is located inside the housing 221;

the number of the second tapered roller bearings 224 is two, the two second tapered roller bearings 224 are respectively located on two sides of the fourth gear 223, the inner side wall of the second tapered roller bearing 224 is fixedly connected with the fourth gear 223, the driven shaft 222 penetrates through the second tapered roller bearing 224 and the fourth gear 223 and is rotatably connected with the angular contact bearing 226, the second worm 225 is located in front of the fourth gear 223, and the second worm 225 is meshed with the fourth gear 223.

In the present embodiment, as shown in fig. 4, the driven shaft 222 and the fourth gear 223 are fixedly connected, and the second tapered roller bearing 224 and the first tapered roller bearing 214 have the same structure, which will not be described in detail; by arranging the angular contact bearing 226, under the action of the angular contact bearing 226, on one hand, the driven shaft 222 can rotate on the shell 221, and on the other hand, because a connecting line of contact points of the steel balls on the angular contact bearing 226 and the inner and outer rings forms a certain angle with the radial direction, when the angular contact bearing 226 bears a larger axial load, the contact angle is increased, so that the bearing load is stronger; when the driving shaft 212 rotates, the driven shaft 222 is also rotated by the action of the coupling 23, so that the driven shaft 222 drives the fourth gear 223 to rotate on the second tapered roller bearing 224, and then the second worm 225 and the fourth gear 223 are engaged with each other to drive the support 12 to ascend.

Further, the coupling 23 is composed of a rotating shaft 231 and a second housing 232, one end of the rotating shaft 231 penetrates one side of the first lifting device 21 and is fixedly connected with the driving shaft 212, and the other end of the rotating shaft 231 penetrates the second housing 232 and the second lifting device 22 and is fixedly connected with the driven shaft 222.

In this embodiment, as shown in fig. 6, the second housing 232 is composed of two half-couplings and two rotating shafts 231, and the two half-couplings are connected by bolts, when the driving shaft 212 drives one of the rotating shafts 231 to rotate, the rotating shaft 231 drives one of the half-couplings to rotate, and simultaneously drives the other half-coupling to rotate, thereby driving the other rotating shaft 231 to rotate, so that the driven shaft 222 rotates, so that under the action of the coupling 23, the dynamic performance of the shaft system is improved, the rotation error is reduced, and the effect of the first worm 215 and the second worm 225 driving the supporting member 12 to ascend is better.

Further, the lower surface of the machine body 11 is provided with a fixed seat 17.

In the present embodiment, by providing the fixing seat 17, the height of the machine body 11 is increased under the action of the fixing seat 17, and moisture and water are prevented from entering the inside of the machine body 11.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the invention, and any modifications, equivalents and improvements made within the spirit and principle of the present invention are intended to be included within the scope of the present invention.

Claims

1. Electric energy management and coordination integrated control device, including body subassembly (1) and sliding assembly (2) that are used for making body subassembly (1) remove, its characterized in that: the body assembly (1) comprises an engine body (11), a supporting piece (12), a computer (13), an LED screen (14) and a heat dissipation assembly (15), wherein the supporting piece (12) is located on one side of the engine body (11), the supporting piece (12) is connected with the engine body (11) in a sliding mode, the computer (13) is located on the upper surface of the supporting piece (12), the computer (13) is fixedly connected with the supporting piece (12), the LED screen (14) is located on one side of the computer (13), the LED screen (14) is fixedly connected with the supporting piece (12), and the LED screen (14) and the engine body (11) are both electrically connected with the computer (13) through electric wires;

the heat dissipation assembly (15) is positioned inside the computer (13), and heat dissipation holes are formed in two sides of the computer (13);

the sliding assembly (2) comprises a first lifting device (21), a second lifting device (22), a coupler (23) and a servo motor (24), the first lifting device (21) and the second lifting device (22) are arranged on the lower surface of the supporting piece (12) in parallel, and is fixedly connected with the supporting piece (12), the servo motor (24) is positioned on one side of the first lifting device (21) far away from the second lifting device (22), the output shaft of the servo motor (24) penetrates through the first lifting device (21), and is rotationally connected with the first lifting device (21), the coupling (23) is positioned between the first lifting device (21) and the second lifting device (22), the first lifting device (21) and the second lifting device (22) are connected through the coupler (23);

the first lifting device (21) comprises a first shell (211), a driving shaft (212), a third gear (213), a first tapered roller bearing (214) and a first worm (215), the third gear (213) is positioned inside the first housing (211), two first tapered roller bearings (214) are arranged, the two first tapered roller bearings (214) are respectively positioned at two sides of the third gear (213), and the inner side wall of the first conical roller bearing (214) is fixedly connected with the third gear (213), the drive shaft (212) penetrates the first tapered roller bearing (214) and the third gear (213), and is fixedly connected with the output shaft of the servo motor (24), the first worm (215) is positioned in front of the third gear (213), and the first worm (215) and the third gear (213) are in meshed connection.

2. The integrated power management and coordination control device of claim 1, wherein: the heat dissipation assembly (15) comprises two bearings (151), a screw rod (152) and a first gear (153), the two bearings (151) are respectively embedded on two sides of the computer (13), the screw rod (152) is positioned between the two bearings (151) and is in rotating connection with the bearings (151), and the first gear (153) is positioned on the outer side wall of the screw rod (152) and is fixedly connected with the screw rod (152);

a second gear (154) is arranged below the first gear (153), the first gear (153) and the second gear (154) are meshed with each other, a driving motor (155) is arranged on one side of the second gear (154), an output shaft of the driving motor (155) is fixedly connected with the second gear (154), a nut (156) is connected to a rod wall of the screw (152) in a threaded fit manner, a motor (157) is arranged on the upper surface of the nut (156), the motor (157) is fixedly connected with the nut (156), and fan blades (158) are fixed on the output shaft of the motor (157);

the lower surface of nut (156) is provided with sliding block (159), offer on the inside lower surface of computer (13) with first spout (131) of sliding block (159) looks adaptation.

3. The integrated power management and coordination control device of claim 1, wherein: a second sliding groove (16) is formed in one side, connected with the supporting piece (12), of the machine body (11), and the supporting piece (12) is connected with the machine body (11) in a sliding mode through the second sliding groove (16).

4. The integrated power management and coordination control device of claim 1, wherein: the second lifting device (22) comprises a shell (221), a driven shaft (222), a fourth gear (223), a second tapered roller bearing (224), a second worm (225) and an angular contact bearing (226), the angular contact bearing (226) is embedded in one side of the shell (221) and fixedly connected with the shell (221), and the fourth gear (223) is located inside the shell (221);

the number of the second tapered roller bearings (224) is two, the two second tapered roller bearings (224) are respectively located on two sides of the fourth gear (223), the inner side wall of the second tapered roller bearing (224) is fixedly connected with the fourth gear (223), the driven shaft (222) penetrates through the second tapered roller bearing (224) and the fourth gear (223) and is rotatably connected with the angular contact bearing (226), the second worm (225) is located in front of the fourth gear (223), and the second worm (225) is meshed with the fourth gear (223).

5. The integrated power management and coordination control device of claim 4, wherein: the shaft coupling (23) comprises pivot (231) and second casing (232), the one end of pivot (231) is run through one side of first elevating gear (21), and with driving shaft (212) fixed connection, the other end of pivot (231) runs through second casing (232) and second elevating gear (22), and with driven shaft (222) fixed connection.

6. The integrated power management and coordination control device of claim 1, wherein: the lower surface of the machine body (11) is provided with a fixed seat (17).