SUMMERY OF THE UTILITY MODEL
The utility model solves the technical problem that the whole size of the electric control actuator is larger because the internal structure of the electric control actuator is not finely distributed.
In order to solve the above problems, the present invention provides an electrically controlled actuator, including: the lower shell or the upper shell is provided with a plurality of first matching holes; the lower shell and the upper shell are matched to form an installation space; the isolation plate is clamped between the lower shell and the upper shell and provided with a plurality of second matching holes; the first matching hole and the second matching hole are connected in a matching mode through a positioning piece; a compact gear assembly and a drive motor both disposed in the installation space; the compact gear assembly is connected with the driving motor in a matched mode, and a motor shaft of the driving motor is arranged in the middle of the compact gear assembly.
Compared with the prior art, the technical scheme has the following technical effects: through the setting element is connected first mating holes with the second mating holes realizes right the division board is fixed a position to the effect of casing down or go up the casing. In combination with the actual installation process, on one hand, the first fitting hole is formed in either the upper shell or the lower shell, so that the positioning installation of the partition plate can be realized only by sequentially connecting the positioning piece with the first fitting hole and the second fitting hole at the corresponding position; compared with the prior art, if the first matching holes are formed in the upper shell and the lower shell, the positioning piece is difficult to be simultaneously and limitedly connected with the first matching holes in the upper shell and the lower shell in the process of assembling the lower shell and the upper shell, so that the whole assembling difficulty is increased, and the assembling efficiency is reduced; on the other hand, the compact gear assembly can realize the position compactness among all parts in the electric control actuator, namely, the utilization rate of the installation space is improved, so that the shell can be set to be in a small size, and the expenditure of the manufacturing cost is saved.
In one example of the present invention, the compact gear assembly comprises: the first reduction gear is in transmission connection with a motor shaft of the driving motor; the second reduction gear is coaxially and fixedly connected with the first reduction gear and is arranged on one side of the first reduction gear, which is close to the driving motor; and the sector gear is meshed with the second reduction gear, and is provided with a matching groove which is used for penetrating through the motor shaft.
Compared with the prior art, the technical scheme has the following technical effects: on the one hand, by enabling the motor shaft to penetrate through the matching groove, compared with the prior art, in the prior art, the motor shaft is arranged at the outer position of the sector gear, so that the installation space reserved for the motor shaft is increased, and therefore, each part inside the electric control actuator is not compactly installed; on the other hand, in combination with the installation environment of the electric control actuator, for example, when the electric control actuator is installed on a vehicle, the space reserved for installing the electric control actuator is also reduced, so that the whole structure is more compact.
In one example of the present invention, includes: the limiting structure is correspondingly arranged on one side of the positioning piece away from the first matching hole; the limiting structure is provided with a supporting surface, and when the lower shell is connected with the upper shell in a matching way, the supporting surface abuts against one side, far away from the first matching hole, of the isolating plate
Compared with the prior art, the technical scheme has the following technical effects: combine the actual installation environment of automatically controlled executor, through down the casing with go up the casing and press from both sides and establish limit structure, and then make limit structure supports on the division board, correspond to the setting element first mating holes and corresponding on the second mating holes, thereby avoided automatically controlled executor is in dynamic installation environment, makes the setting element is followed break away from on the first mating holes, lead to the division board is in installation space internalization, it is right compact gear assembly's transmission operation etc. causes the interference, even takes place serious damage.
In one example of the present invention, the number of the first fitting holes is two, and the first fitting holes are arranged along a diagonal line of the lower case or the upper case; the first matching holes are connected with the second matching holes in a one-to-one corresponding mode.
Compared with the prior art, the technical scheme has the following technical effects: through the mode that the diagonal set up for the means of location division board is high-efficient, avoids setting up too much first mating holes with the second mating holes has increased the part quantity in the installation space, in addition, also can lead to because trompil quantity is too much, and has reduced the overall structure intensity of automatically controlled executor.
In one embodiment of the present invention, the mating grooves are circular arc groove structures; and the distance between the motion track of the motor shaft in the arc groove structure and the tooth root circle of the sector gear is constant.
Compared with the prior art, the technical scheme has the following technical effects: in combination with the rotation process of the sector gear, the matching groove is set to be the arc groove structure, so that the motor shaft is prevented from interfering with the normal rotation of the sector gear.
In one example of the present invention, the method further comprises: the output shaft is arranged on the upper shell and coaxially and rotationally connected with the sector gear; the limiting piece is sleeved on the output shaft; the elastic piece is sleeved on the output shaft and clamps the limiting piece with the sector gear; the elastic piece is provided with a first end and a second end which are opposite to each other, the first end is connected with the limiting piece, and the second end is connected with the upper shell in a matched mode.
Compared with the prior art, the technical scheme has the following technical effects: the limiting piece is clamped between the sector gear and the elastic piece by sleeving the limiting piece on the output shaft, so that the elastic piece is convenient to mount on one hand; on the other hand, an avoiding space is formed between the elastic part and the sector gear, for example, the avoiding space is used for avoiding a motor shaft of the driving motor so as to avoid interference with the elastic part, so that the positions of all parts in the installation space are reasonably distributed, and the mutual structures are more compact.
In an example of the present invention, a first slot is disposed on a side of the limiting member close to the elastic member, and the first slot is configured to be in limit fit with the first end; the upper shell is provided with a second clamping groove which is used for being in limit fit with the second end; wherein the limiting member rotates along with the rotation of the output shaft.
Compared with the prior art, the technical scheme has the following technical effects: the matching mode for limiting the elastic part is simple, namely the difficulty of positioning and installing the elastic part in the installation space is reduced, so that the elastic part can be effectively deformed in the rotation process of the output shaft, and when the electronic control actuator is combined to control the valve opening adjusting process in an exhaust gas pipeline, after the driving motor stops operating, the elastic part can be deformed to release stored elastic potential energy and further convert the elastic potential energy into power for closing the valve, so that the driving motor is not required to be input with power, the closing action of the valve can be completed only by means of the elastic force, the operation work of the driving motor is reduced, the service life of the driving motor is prolonged, and the electric energy is saved.
In another aspect, the present invention further provides an exhaust gas treatment system, including: an electrically controlled actuator as in any preceding example.
Compared with the prior art, the technical scheme has the following technical effects: the technical effects corresponding to any one of the above technical solutions can be achieved, and are not described herein again.
In an example of the present invention, the exhaust gas treatment system includes a valve disposed on an exhaust gas circulation pipe of the exhaust gas treatment system, and the electrically controlled actuator is configured to control opening or closing of the valve.
Compared with the prior art, the technical scheme has the following technical effects: the driving shaft of the electric control actuator is connected with a valve shaft of the tail gas treatment system so as to control the valve to be opened or closed.
In yet another aspect, the present invention also provides a vehicle comprising: an electrically controlled actuator as in any of the examples above; or, an exhaust treatment system as in any of the above examples.
Compared with the prior art, the technical scheme has the following technical effects: the technical effects corresponding to any one of the above technical solutions can be achieved, and are not described herein again.
After the technical scheme of the utility model is adopted, the following technical effects can be achieved:
(1) through the setting element is connected first mating holes with the second mating holes realizes right the division board is fixed a position to the effect of casing down or go up the casing. In combination with the actual installation process, on one hand, the first fitting hole is formed in either the upper shell or the lower shell, so that the positioning installation of the partition plate can be realized only by sequentially connecting the positioning piece with the first fitting hole and the second fitting hole at the corresponding position; compared with the prior art, if the first matching holes are formed in the upper shell and the lower shell, the positioning piece is difficult to be simultaneously and limitedly connected with the first matching holes in the upper shell and the lower shell in the process of assembling the lower shell and the upper shell, so that the whole assembling difficulty is increased, and the assembling efficiency is reduced; on the other hand, the compact gear assembly can realize the position compactness among all parts in the electric control actuator, namely, the utilization rate of the installation space is improved, so that the shell can be set into a small body shape, and the expenditure of the manufacturing cost is saved;
(2) on the one hand, by enabling the motor shaft to penetrate through the matching groove, compared with the prior art, in the prior art, the motor shaft is arranged at the outer position of the sector gear, so that the installation space reserved for the motor shaft is increased, and therefore, each part inside the electric control actuator is not compactly installed; on the other hand, in combination with the installation environment of the electric control actuator, for example, when the electric control actuator is installed on a vehicle, the space reserved for installing the electric control actuator is also reduced, so that the whole structure is more compact;
(3) combine the actual installation environment of automatically controlled executor, through down the casing with go up the casing and press from both sides and establish limit structure, and then make limit structure supports on the division board, correspond to the setting element first mating holes and corresponding on the second mating holes, thereby avoided automatically controlled executor is in dynamic installation environment, makes the setting element is followed break away from on the first mating holes, lead to the division board is in installation space internalization, it is right compact gear assembly's transmission operation etc. causes the interference, even takes place serious damage.
Detailed Description
In order to make the aforementioned objects, features and advantages of the present invention comprehensible, embodiments accompanied with figures are described in detail below.
The first embodiment is as follows:
referring to fig. 1, a schematic structural diagram of an electrically controlled actuator 100 according to an embodiment of the present invention is shown. The electric actuator 100 includes, for example, a housing, a driving motor 30 and a compact gear assembly, wherein an installation space is provided in the housing, the driving motor 30 and the compact gear assembly are both provided in the installation space, and the compact gear assembly is connected with the driving motor 30 in a matching manner; the drive motor 30 is provided with a motor shaft 31, by means of which motor shaft 31 a driving connection to the compact gear assembly can be realized. And the motor shaft 31 of the driving motor 30 is provided at the middle of the compact gear assembly.
In particular, with reference to fig. 2-5, the compact gear assembly comprises, for example, a first reduction gear 41, a second reduction gear 42 and a sector gear 43. The first reduction gear 41 is in transmission connection with the motor shaft 31; the second reduction gear 42 is coaxially and fixedly connected with the first reduction gear 41, and the second reduction gear 42 is arranged on one side of the first reduction gear 41 close to the driving motor 30; the sector gear 43 meshes with the second reduction gear 42, and the sector gear 43 is provided with a fitting groove 44, wherein the fitting groove 44 is used for fitting connection of the motor shaft 31. Wherein the pitch circle of the first reduction gear 41 is larger than the pitch circle of the second reduction gear 42.
In one embodiment, the motor shaft 31 is a gear shaft, and thus, the motor shaft 31 and the first reduction gear 41 are in external meshing transmission. Specifically, the motor shaft 31 and the sector gear 43 are eccentrically arranged, a part of the motor shaft 31 extends out of the matching groove 44, and the structure of the part of the motor shaft 31 extending out of the matching groove 44 is denoted as a first gear shaft part 32, so that the first gear shaft part 32 is externally meshed with the first reduction gear 41; and the portion fitted into the fitting groove 44 is referred to as a second gear shaft portion 33, and the second gear shaft portion 33 rotates relative to the sector gear 43 in the fitting groove 44 in accordance with the rotation of the sector gear 43. In combination with the operation process of the driving motor 30, specifically, the gear shaft rotates to drive the first reduction gear 41 engaged therewith to rotate, and since the first reduction gear 41 and the second reduction gear 42 are coaxially and fixedly connected, the second reduction gear 42 is driven to rotate, and finally the sector gear 43 is driven to rotate.
Preferably, the engagement groove 44 is a circular arc groove structure in which a distance between a movement locus of the motor shaft 31 in the circular arc groove structure and a root circle of the sector gear 43 is kept constant.
For example, the arc groove structure is provided at an eccentric position of the sector gear 43; wherein the arc groove structure is concentric with the sector gear 43. Specifically, the circular arc groove structure is a partial annular structure, and as the sector gear 43 rotates, the position of the second gear shaft in the circular arc groove structure moves, which can be regarded as the second gear shaft rotating around the axis of the sector gear 43 in the circular arc groove structure. In order to avoid that the angle that the sector gear 43 rotates in the same direction is too large and the second gear shaft collides with the inner wall of the arc groove structure, the maximum number of turns that the driving motor 30 rotates in the same direction can be preset, so that the sector gear 43 is prevented from interfering with the inner wall of the arc groove structure in the forward rotation or reverse rotation process.
Referring to fig. 6 to 8, preferably, the housing includes, for example, a lower housing 10, an upper housing 20, and a partition plate 21. A first installation space 16 for installing the driving motor 30 is provided in the lower case 10; the upper shell 20 is matched and connected with the lower shell 10, and a second mounting space 27 for mounting the compact gear assembly is arranged in the upper shell 20; the lower casing 10 or the upper casing 20 is provided with a plurality of first fitting holes, correspondingly, the isolation plate 21 is provided with a plurality of second fitting holes, and the isolation plate 21 is clamped between the lower casing 10 and the upper casing 20. The first fitting holes 26 and the second fitting holes are arranged in a one-to-one correspondence manner, and are connected with the positioning pieces 23 in a fitting manner, so that the partition plate 21 is positioned and mounted on the lower casing 10 or the upper casing 20. For example, the first fitting hole 26 may be provided on an end surface of the upper case 20 for fitting with the lower case 10.
In a specific embodiment, the number of the first fitting holes 26 is two, and the first fitting holes are arranged on the end surface along the diagonal direction, and correspondingly, the number of the second fitting holes is also two, and similarly, the positioning member 23 is arranged along the diagonal of the partition board 21, for example, a pin shaft, and the first fitting holes 26 and the second fitting holes can be arranged as light holes, and the positioning and installation of the first fitting holes 26 and the second fitting holes can be completed only by inserting the pin shaft into the corresponding first fitting holes 26 and the second fitting holes. Certainly, the positioning element 23 may also be a bolt, and when the electronic control actuator 100 is applied to a vehicle in a manner of fastening the first fitting hole 26 and the second fitting hole by using a screw thread, the vehicle is in a running process, especially when an obstacle is crossed, so that an installation environment where the electronic control actuator 100 is located is a dynamic environment, and then, in a vibrating or swaying installation environment, the pin shaft is easily made to fall off from the first fitting hole 26 and the second fitting hole, so that the isolation plate 21 is separated from the upper housing 20. Also, the bolt is easily loosened.
Then, further, the position of the lower casing 10 corresponding to the positioning element 23 may be provided with a limiting structure 15, so that when the lower casing 10 is connected with the upper casing 20 in a matching manner, the limiting structure 15 is supported to the surface of the isolation plate 21, and meanwhile, the positioning element 23 is prevented from being disengaged from the second matching hole. For example, the limiting structure 15 may be a reinforcing rib, and the reinforcing rib can also reinforce the overall structural strength of the lower housing 10. Specifically, the limiting structure 15 is correspondingly disposed on one side of the positioning element 23 away from the first matching hole 26, wherein the limiting structure 15 is provided with a supporting surface, and when the lower housing 10 is connected with the upper housing 20 in a matching manner, the supporting surface abuts against one side of the partition board 21 away from the first matching hole 26.
Preferably, the lower case 10 includes, for example, a first mounting portion 14, a motor mounting portion 13, and an air-cooling unit 11. The first mounting portion 14 has a mounting side and a mating side opposite to each other, and the mating side is used for mating with the upper housing 20; the motor mounting part 13 is arranged on the mounting side, wherein the motor mounting part 13 is communicated with the first mounting part 14 to form a first mounting space 16; first installation department 14 is located to air-cooled subassembly 11, and be located the installation side, and is concrete, air-cooled subassembly 11 sets up around motor installation department 13, also motor installation department 13 can be the intermediate position who sets up in first installation department 14, so that can reserve the sufficient mounted position for air-cooled subassembly 11 at first installation department 14, so that air-cooled subassembly 11 can set up around motor installation department 13, and then can make air-cooled subassembly 11 can use motor installation department 13 as the center, carry out balanced reasonable heat dissipation.
For example, the air cooling assembly 11 may be, for example, a heat dissipating fin set, and the surface area of the corresponding position of the first mounting portion 14 is increased, so as to improve the timely discharge of heat dissipated into the first mounting space 16 by the operation of the driving motor 30, thereby achieving the effect of accelerating the temperature reduction, and preventing the driving motor 30 from overheating and thus from overheating and reducing the service life.
Further, the lower housing 10 further includes, for example, a water cooling module 12, where the water cooling module 12 is disposed on the first mounting portion 14 and corresponds to the air cooling module 11; wherein the water cooling unit 12 is disposed around the motor mounting portion 13.
Specifically, the water cooling component 12 is, for example, a water cooling channel, and the water cooling channel is isolated from the first installation space 16. The water cooling channel includes, for example, a water inlet channel and a water outlet channel. The water inlet of the water inlet channel and the water outlet of the water outlet channel are both arranged on the surface of the first mounting part 14, and the water inlet channel is communicated with the interior of the water outlet channel.
For example, in the process of processing the first installation part 14, in order to reduce the processing difficulty, the water inlet channel and the water outlet channel are straight channels arranged on the first installation part 14, and meanwhile, in order to ensure that the water cooling effect of the water cooling component 12 can be well realized, a third channel can be additionally arranged on the surface of the first installation part 14, and the third channel, the water inlet channel and the water outlet channel are mutually communicated, so that in the process of performing the water cooling effect on the water cooling component 12, the third channel can be blocked, so that the cooling liquid flows into the water inlet channel from the water inlet, flows through the water outlet channel, and finally flows out from the water outlet.
Preferably, the electric control actuator 100 includes, for example, an electric control board 22, and the electric control board 22 is disposed in the first installation space 16. Because the electric control board 22 and the driving motor 30 are both arranged in the first installation space 16, the environment temperature of the electric control board 22 is affected by the operation of the driving motor 30 and is at a higher temperature, and then, in combination with the above technical scheme, the electric control board 22 can normally function through the synergistic heat dissipation effect of the air cooling assembly 11 and the water cooling assembly 12.
Preferably, the upper housing 20 is provided with an output port 25, and the electric control actuator 100 further includes, for example, an output shaft 50, a limiting member 53 and an elastic member 51. The output shaft 50 is arranged on the upper shell 20 and partially extends out of the output port 25, wherein the output shaft 50 is coaxially and rotationally connected with the sector gear 43; the limiting member 53 is sleeved on the output shaft 50; the elastic element 51 is sleeved on the output shaft 50, and a limiting element 53 is interposed between the elastic element and the sector gear 43.
Further, the elastic member 51 has a first end and a second end 52 opposite to each other, and the first end is connected to the limiting member 53; second end 52 is in mating connection with upper housing 20; further, the motor shaft 31 is interposed between the output shaft 50 and the compact gear assembly.
With reference to fig. 9, in an embodiment, the elastic member 51 is a torsion spring, a first engaging groove 54 is disposed on a side of the limiting member 53 close to the elastic member 51, and the first engaging groove 54 is used for engaging with the first end in a limiting manner, so as to connect the torsion spring with the limiting member 53; and a second clamping groove 24 is formed at a position of the upper housing 20 corresponding to the second end 52, and the second end 52 is clamped with the second clamping groove 24, so that the connection between the torsion spring and the upper housing 20 is realized. Because the limiting member 53 is sleeved on the output shaft 50, the limiting member 53 can move synchronously with the rotation of the output shaft 50, so as to drive the first end of the torsion spring to rotate along the rotation of the output shaft 50, and the torsion spring is in a deformation state. In the case of operating the driving motor 30, for example, it can be defined that the output shaft 50 is driven to rotate forward during the forward rotation of the motor shaft 31, so that the opening of the valve rotatably connected to the output shaft 50 is increased continuously, and conversely, the opening of the valve is decreased continuously until the valve is completely closed during the reverse rotation of the motor shaft 31.
Therefore, when the motor shaft 31 is controlled to rotate forward, the first reduction gear 41 engaged with the motor shaft is rotated in a reverse direction, and at the same time, the second reduction gear 42 is also rotated in a reverse direction, and since the second reduction gear 42 is engaged with the sector gear 43, the sector gear 43 is rotated in a forward direction, so as to drive the output shaft 50 to rotate forward, and to control the opening of the valve in transmission connection with the output shaft to increase, wherein, in the process of rotating forward, the driving motor 30 needs to overcome the force generated by the deformation of the torsion spring. Specifically, when the driving motor 30 rotates by a larger angle in the forward rotation direction, the valve opening degree is correspondingly larger. On the contrary, after the driving motor 30 stops operating, the output shaft 50 is driven to rotate reversely under the restoring force of the torsion spring, that is, the opening of the valve is reduced, and the valve is finally closed.
In one embodiment, the sequential order of the motor shaft 31, the output shaft 50, and the compact gear assembly may be: an output shaft 50, a sector gear 43, a motor shaft 31, a first reduction gear 41 and a second reduction gear 42. It should be noted that the motor shaft 31 is fittingly connected to the fitting groove 44 of the sector gear 43, and it corresponds to the prior art, for example, in the following sequence: the output shaft 50, the sector gear 43, the first reduction gear 41, the second reduction gear 42 and the motor shaft 31, namely, the difference between the present technical solution and the prior art lies in that the sector gear 43 is provided with the matching groove 44, and the position of the motor shaft 31 is adjusted between the sector gear 43 and the first reduction gear 41, so that the internal space is reduced, the positions of the parts of the electric control actuator 100 are more compact, and the fine layout effect is achieved. In addition, it can be understood that, the position corresponding to the driving motor 30 is adjusted to the middle position located in the first installation part 14 from the original position close to the edge, which is arranged in the first installation part 14, so that the air cooling assembly 11 can be arranged around the motor installation part 13, heat generated in the operation process of the driving motor 30 can be sufficiently dissipated, the heat exchange efficiency between the inside of the electric control actuator 100 and the external installation environment is further improved, and the problem that the electric control actuator 100 is prone to failure due to untimely heat dissipation is avoided, and the service life is shortened.
Example two:
the second embodiment of the present invention further provides an exhaust gas treatment system, for example, the exhaust gas treatment system includes the electric control actuator 100 according to the first embodiment. Accordingly, the technical effects corresponding to any one of the technical solutions in the first embodiment can be achieved, and are not described herein again.
Preferably, the exhaust gas treatment system includes, for example, a valve, the valve is disposed on an exhaust gas circulation pipeline of the exhaust gas treatment system, and the electrically controlled actuator 100 is used for controlling the opening or closing of the valve.
For example, the exhaust treatment system may be: a turbocharging system, an exhaust braking system, and an exhaust gas recirculation system.
Example three:
a third embodiment of the present invention further provides a vehicle, where the vehicle includes, for example, the electronic control actuator 100 according to the first embodiment, and correspondingly, the third embodiment can achieve the technical effect corresponding to any one of the technical solutions according to the first embodiment; or, the exhaust gas treatment system provided by the second embodiment is included. Correspondingly, the third embodiment can achieve the technical effect corresponding to any one of the technical solutions in the second embodiment, and details are not repeated here. For example, the vehicle may be: automobiles, trucks, vans, and commercial vehicles, among others.
Although the present invention is disclosed above, the present invention is not limited thereto. Various changes and modifications may be effected therein by one skilled in the art without departing from the spirit and scope of the utility model as defined in the appended claims.