CN217904971U - Heat radiation structure of servo driver - Google Patents

Abstract

The utility model belongs to the technical field of the servo driver technique and specifically relates to a heat radiation structure of servo driver, including servo driver, standing groove, radiator fan and ventilating board, the standing groove is seted up on servo driver, ventilating board fixed mounting is in the standing groove, radiator fan movable mounting is in the standing groove and arrange between ventilating board and servo driver, still includes the moving mechanism, moving mechanism movable mounting is in the standing groove, the moving mechanism is used for controlling radiator fan's activity, the utility model discloses a rotate to drive the threaded rod and rotate for radiator fan goes up and down to remove, and then blows in with the adsorbed dust external on the ventilating board, reaches the clean and tidy effect of ventilating board when keeping long-term heat dissipation, through placing the box in pouring water, will place the box again and put into the slot for hot-air carries out the heat exchange with water, reaches the effect of cooling with higher speed.

Description

Heat radiation structure of servo driver

Technical Field

The utility model relates to a servo driver technical field especially relates to a servo driver's heat radiation structure.

Background

In prior art, when using servo driver, can produce high temperature among the servo driver and lead to servo driver's performance to descend, often install radiator fan in servo driver at this moment and continue work for inside hot-air is discharged from the vent of seting up, realizes the heat dissipation purpose to servo driver.

Based on the above explanation, in the process of using the servo driver for a long time, the heat dissipation fan discharges the internal hot air from one part of the vent, and the other part of the vent discharges the external air into the servo driver, so as to keep the internal and external pressure consistent, and at the moment, the dust carried in the external air is adsorbed in the vent and is difficult to clean, thereby providing the heat dissipation structure of the servo driver.

SUMMERY OF THE UTILITY MODEL

The utility model aims at solving the defects existing in the prior art and providing a heat radiation structure of a servo driver.

In order to achieve the above purpose, the utility model adopts the following technical scheme:

designing a heat dissipation structure of a servo driver, which comprises the servo driver, a placing groove, a heat dissipation fan and a ventilation plate, wherein the placing groove is formed in the servo driver, the ventilation plate is fixedly arranged in the placing groove, and the heat dissipation fan is movably arranged in the placing groove and arranged between the ventilation plate and the servo driver;

the movable mechanism, movable mechanism movable mounting is in the standing groove, movable mechanism is used for controlling radiator fan's activity, movable mechanism includes first movable block, threaded rod, second movable block, dead lever and two sets of movable grooves, and is two sets of the movable groove symmetry is seted up in the both sides of standing groove and is communicated with the standing groove, first movable block activity is arranged in one of them a set of movable groove and with radiator fan fixed connection, seted up on the first movable block and run through the screw hole, the threaded rod rotates to be installed in the movable groove that corresponds and through running through screw hole and first movable block threaded connection, second movable block activity is arranged in another set of movable groove and with radiator fan fixed connection, dead lever fixed mounting is in the movable groove that corresponds and runs through the second movable block.

Preferably, a heat absorbing mechanism is fixedly installed in the placing groove and is used for absorbing heat generated when the servo driver works.

Preferably, the heat absorption mechanism includes the slot, places box and filter screen, the slot is seted up in the bottom of standing groove and is communicated with the standing groove, just servo driver is run through to the one end of slot, filter screen fixed mounting is on the slot, place the box and insert in the slot, just place the top opening of box.

Preferably, the two groups of movable grooves are vertically arranged.

The utility model provides a pair of servo driver's heat radiation structure, beneficial effect lies in: this servo driver's heat radiation structure changes through rotating and drives the threaded rod rotation for radiator fan goes up and down to remove, and then blows in the external world with absorbent dust on the ventilating board, reaches the clean and tidy effect of ventilating board when keeping long-term heat dissipation, through placing pouring water in the box, will place the box again and put into the slot, makes hot-air and water carry out the heat exchange, reaches the effect of cooling with higher speed.

Drawings

Fig. 1 is an isometric view structural schematic diagram of a heat dissipation structure of a servo driver according to the present invention.

Fig. 2 is a schematic cross-sectional structure diagram of a heat dissipation structure of a servo driver according to the present invention.

Fig. 3 is an enlarged schematic structural diagram of a portion a of a heat dissipation structure of a servo driver according to the present invention.

Fig. 4 is a schematic diagram of a B-portion enlarged structure of a heat dissipation structure of a servo driver according to the present invention.

Fig. 5 is a schematic diagram of a C-portion enlarged structure of a heat dissipation structure of a servo driver according to the present invention.

In the figure: 1 servo driver, 2 standing grooves, 3 movable mechanisms, 31 first movable blocks, 32 threaded rods, 33 second movable blocks, 34 fixed rods, 35 movable grooves, 4 heat absorption mechanisms, 41 slots, 42 placing boxes, 43 filter screens, 5 heat dissipation fans, 6 ventilating plates, 7 rotating handles and 8 handles.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments.

Example 1:

referring to fig. 1-5, a heat dissipation structure of a servo driver comprises a servo driver 1, a placement groove 2, a heat dissipation fan 5 and a ventilation board 6, wherein the placement groove 2 is formed in the servo driver 1, the placement groove 2 is used for providing a placement space, the ventilation board 6 is fixedly installed in the placement groove 2, the ventilation board 6 is used for facilitating ventilation, the heat dissipation fan 5 is movably installed in the placement groove 2 and is arranged between the ventilation board 6 and the servo driver 1, and the heat dissipation fan 5 is used for providing heat dissipation airflow;

the movable mechanism 3, the movable mechanism 3 is movably mounted in the placing groove 2, the movable mechanism 3 is used for controlling the movement of the heat dissipation fan 5, the movable mechanism 3 comprises a first movable block 31, a threaded rod 32, a second movable block 33, a fixed rod 34 and two groups of movable grooves 35, the two groups of movable grooves 35 are symmetrically arranged on two sides of the placing groove 2 and communicated with the placing groove 2, the movable grooves 35 are used for providing a movable space, the first movable block 31 is movably arranged in one group of movable grooves 35 and fixedly connected with the heat dissipation fan 5, a through threaded hole is formed in the first movable block 31, the threaded rod 32 is rotatably mounted in the corresponding movable groove 35 and is in threaded connection with the first movable block 31 through the through threaded hole, the threaded rod 32 is used for rotating to drive the first movable block 31 to move, the servo driver 1 is rotatably mounted with a rotating handle 7, the rotating handle 7 and the threaded rod 32 coaxially rotate, the rotating handle 7 is used for convenient rotation, the second movable block 33 is movably arranged in the other group of movable grooves 35 and is fixedly connected with the heat dissipation fan 5, the fixed rod 34 is fixedly mounted in the corresponding movable groove 35 and penetrates through the second movable block 33, and is used for fixing the heat dissipation fan 5.

Both sets of active slots 35 are arranged vertically.

The working principle is as follows: when the air cooling device is used, the servo driver 1 is started to be used, so that the temperature is increased due to the internal generation of the servo driver 1, meanwhile, the heat dissipation fan 5 is started to generate air flow to discharge the internal hot air from the upper ventilating plate 6, the lower ventilating plate 6 sucks the external air into the placing groove 2, and the heat dissipation and the temperature reduction of the servo driver 1 are realized;

after long-term use, ventilating board 6 of radiator fan 5 below adsorbs a large amount of external dusts, rotates this moment and changes 7 and drive threaded rod 32 and rotate for threaded connection's first movable block 31 descends, and then drives radiator fan 5 and descend to the bottom and use, and hot-air discharges from ventilating board 6 of below in the radiating process this moment, makes the ventilating board 6 of below go up the dust and insufflate the external world.

Example 2:

in embodiment 1, since the heat dissipation fan 5 is used for heat dissipation, in order to provide the heat dissipation effect, referring to fig. 1 to 5, the heat absorption mechanism 4 is included in this embodiment;

the heat absorption mechanism 4 is fixedly installed in the placing groove 2, and the heat absorption mechanism 4 is used for absorbing heat generated when the servo driver 1 works.

Endothermic mechanism 4 includes slot 41, place box 42 and filter screen 43, slot 41 sets up in the bottom of standing groove 2, and communicate with standing groove 2, and slot 41's one end runs through servo driver 1, slot 41 is used for providing the insertion space, filter screen 43 fixed mounting is on slot 41, filter screen 43 is used for guaranteeing the steam circulation, filter out the dust simultaneously, place box 42 and insert in slot 41, and place box 42's top opening, it is used for putting into water and absorbs heat to place box 42, it has handle 8 to place last fixed mounting of box 42, handle 8 is used for convenient pulling.

The working principle is as follows: when the servo driver 1 is started to be used, the temperature is increased due to the fact that the servo driver 1 is internally generated, enough water is poured into the placing box 42 at the moment, the placing box 42 is placed into the inserting groove 41, the hot air and the water exchange heat, and the temperature in the placing groove 2 is lowered.

The general working principle is as follows: when the device is used, the servo driver 1 is started to be used, so that the temperature is increased due to the fact that the inside of the servo driver 1 is generated, enough water is poured into the placing box 42 at the moment, the placing box 42 is placed into the slot 41, hot air and the water exchange heat, and the temperature in the placing groove 2 is further reduced;

meanwhile, the heat dissipation fan 5 is started to generate air flow to discharge the hot air in the servo driver from the upper ventilating plate 6, and the lower ventilating plate 6 sucks the outside air into the placing groove 2, so that the heat dissipation and the temperature reduction of the servo driver 1 are realized;

after long-term use, ventilating board 6 below radiator fan 5 adsorbs a large amount of external dusts, rotates this moment and changes 7 and drive threaded rod 32 and rotate for threaded connection's first movable block 31 descends, and then drives radiator fan 5 and descend to the bottom and use, and hot-air discharges from ventilating board 6 below in the radiating process this moment, makes on the ventilating board 6 of below the dust blow in the external world.

The above, only be the concrete implementation of the preferred embodiment of the present invention, but the protection scope of the present invention is not limited thereto, and any person skilled in the art is in the technical scope of the present invention, according to the technical solution of the present invention and the utility model, the concept of which is equivalent to replace or change, should be covered within the protection scope of the present invention.

Claims (4)

1. A heat dissipation structure of a servo driver comprises the servo driver (1), a placing groove (2), a heat dissipation fan (5) and a ventilation plate (6), wherein the placing groove (2) is formed in the servo driver (1), the ventilation plate (6) is fixedly installed in the placing groove (2), the heat dissipation fan (5) is movably installed in the placing groove (2) and is arranged between the ventilation plate (6) and the servo driver (1), and the heat dissipation structure is characterized by further comprising;

the heat dissipation fan comprises a moving mechanism (3), the moving mechanism (3) is movably installed in a placing groove (2), the moving mechanism (3) is used for controlling the movement of the heat dissipation fan (5), the moving mechanism (3) comprises a first moving block (31), a threaded rod (32), a second moving block (33), a fixed rod (34) and two sets of moving grooves (35), the moving grooves (35) are symmetrically arranged on two sides of the placing groove (2) and communicated with the placing groove (2), the first moving block (31) is movably arranged in one set of moving groove (35) and fixedly connected with the heat dissipation fan (5), a through threaded hole is formed in the first moving block (31), the threaded rod (32) is rotatably installed in the corresponding moving groove (35) and is in threaded connection with the first moving block (31) through the through threaded hole, the second moving block (33) is movably arranged in the other set of moving groove (35) and is fixedly connected with the heat dissipation fan (5), and the fixed rod (34) is fixedly installed in the corresponding moving groove (35) and penetrates through the second moving groove (33).

2. The heat dissipation structure of the servo driver as recited in claim 1, wherein a heat absorption mechanism (4) is fixedly installed in the placement groove (2), and the heat absorption mechanism (4) is used for absorbing heat generated when the servo driver (1) works.

3. The servo driver heat dissipation structure according to claim 2, wherein the heat absorption mechanism (4) comprises a slot (41), a placement box (42) and a filter screen (43), the slot (41) is opened at the bottom of the placement tank (2) and is communicated with the placement tank (2), one end of the slot (41) penetrates through the servo driver (1), the filter screen (43) is fixedly installed on the slot (41), the placement box (42) is inserted into the slot (41), and the top of the placement box (42) is opened.

4. The heat dissipation structure of a servo driver according to claim 1, wherein both sets of the movable grooves (35) are arranged vertically.

Images