WO2019037140A1 - 一种风机叶片调节装置、对旋风机和风机叶片调节方法 - Google Patents

一种风机叶片调节装置、对旋风机和风机叶片调节方法 Download PDF

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Publication number
WO2019037140A1
WO2019037140A1 PCT/CN2017/099568 CN2017099568W WO2019037140A1 WO 2019037140 A1 WO2019037140 A1 WO 2019037140A1 CN 2017099568 W CN2017099568 W CN 2017099568W WO 2019037140 A1 WO2019037140 A1 WO 2019037140A1
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WIPO (PCT)
Prior art keywords
fan
fan blade
shaft
installation angle
blade
Prior art date
Application number
PCT/CN2017/099568
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English (en)
French (fr)
Inventor
寇子明
吴娟
高贵军
张鹏
王海清
李志刚
梁宏达
Original Assignee
太原理工大学
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Application filed by 太原理工大学 filed Critical 太原理工大学
Priority to ZA2018/01581A priority Critical patent/ZA201801581B/en
Publication of WO2019037140A1 publication Critical patent/WO2019037140A1/zh

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    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F04POSITIVE - DISPLACEMENT MACHINES FOR LIQUIDS; PUMPS FOR LIQUIDS OR ELASTIC FLUIDS
    • F04DNON-POSITIVE-DISPLACEMENT PUMPS
    • F04D27/00Control, e.g. regulation, of pumps, pumping installations or pumping systems specially adapted for elastic fluids
    • F04D27/002Control, e.g. regulation, of pumps, pumping installations or pumping systems specially adapted for elastic fluids by varying geometry within the pumps, e.g. by adjusting vanes
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F04POSITIVE - DISPLACEMENT MACHINES FOR LIQUIDS; PUMPS FOR LIQUIDS OR ELASTIC FLUIDS
    • F04DNON-POSITIVE-DISPLACEMENT PUMPS
    • F04D29/00Details, component parts, or accessories
    • F04D29/26Rotors specially for elastic fluids
    • F04D29/32Rotors specially for elastic fluids for axial flow pumps
    • F04D29/34Blade mountings
    • F04D29/36Blade mountings adjustable
    • F04D29/362Blade mountings adjustable during rotation

Definitions

  • the invention relates to the technical field of axial flow fans, in particular to a fan blade adjusting device, a pair of rotating fan and a fan blade adjusting method.
  • a fan or ventilator is a mechanical device configured to deliver gas.
  • a fan or ventilator is a mechanical device that converts the mechanical energy of a prime mover into gas energy. Starting from the principle of increasing gas pressure, it can be mainly divided into volumetric type, vane type and jet type. Among them, vane type fan can be further divided into centrifugal type, mixed flow type, axial flow type and cross flow type.
  • a counter-rotating fan is generally used in mines such as coal mines.
  • the cyclone fan also called the counter-rotating axial fan, refers to an axial flow fan in which two impellers are connected in series. The diameters, hub ratios and rotational speeds of the two impellers are the same, and the rotation direction is opposite. Usually two impellers are driven by two motors respectively.
  • the advantages of this design include: 1) in the case of the same flow rate, the pressure gain can be significantly increased, and the inherent weakness of the axial fan total pressure gain is relatively low; 2) no Any baffle is needed to shorten the axial dimension and make the structure simple; and after removing the baffle, the wind resistance is reduced, resulting in higher efficiency and lower noise; 3) due to the use of dual motors, double-end drag The capacity of each motor has dropped drastically, which has greatly reduced the investment in power supply and electronic control equipment of wind turbines and operational control technology requirements.
  • an axial flow fan rotor blade adjustment device is mainly composed of moving blades. , the transmission group, the hub, the hydraulic transmission system, the control panel, etc.; the power of the blade adjustment device comes from the hydraulic power system, and the structure is high in cost, because the hydraulic power system includes a pump station, a pipeline, a servo valve, A series of components such as servo cylinders, as well as a considerable number of parts need to be specially made, complicated in process and high in maintenance cost, which limits the application of the device in small and medium-sized wind turbines.
  • the hydraulic power system used in it has a large space and is placed. Inside the air duct, the air flow is affected in the narrow air duct, which limits the size of the wind wheel hub, resulting in low efficiency of the fan; the third is that the adjustment precision of the blade mounting angle by hydraulic power is not high enough to make the pair The cyclone operates at the optimum efficiency point.
  • the invention patent application with the publication number CN105673560A and the invention titled "two-stage blade adjustment mechanism for a counter-rotating axial fan" converts the adjusted rotary motion into a two-stage impeller through a combination of a series of gear pairs and thread pairs.
  • the linear motion of the thrust disk is used to adjust the blade mounting angle of the two-stage impeller.
  • the application realizes the synchronous adjustment of the two-stage blade mounting angle, and the cost is low; however, the device needs to manually rotate the hand wheel when adjusting the blade, and the remote adjustment needs to be equipped with an external power source, and the blade mounting angle is not realized. Remote automation adjustment.
  • the embodiments of the present invention are expected to provide a fan blade adjusting device, a pair of rotating fan and a fan blade adjusting method, which can accurately adjust the mounting angle of the fan blade, and is convenient for remote automatic adjustment.
  • An embodiment of the present invention provides a fan blade adjusting device, which is connected to one or more fan blades on a fan, wherein the fan blade adjusting device includes a control host and an adjusting actuator; wherein
  • the control host is configured to instruct the adjustment actuator to adjust a mounting angle of the fan blade according to an actual air volume of the fan;
  • the adjustment actuator is configured to adjust a mounting angle of the fan blade according to an instruction of the control host.
  • the adjustment actuator comprises a drive motor and a transmission mechanism including at least a first reduction drive; an output shaft of the drive motor is coupled to an input end of the transmission; and the fan blade is provided with a blade at one end of the fan shaft A shaft, a mounting angle of the fan blade changes with rotation of the blade shaft, and an output end of the transmission mechanism is coupled to the blade shaft.
  • the transmission mechanism includes a first bevel gear and a second bevel gear that mesh with each other, the first bevel gear rotating with rotation of the drive motor; the first bevel gear is at an axis of the fan shaft Rotating the axis relative to the fan shaft and driving the second bevel gear; the second bevel gear is mounted on the vane shaft, the vane shaft rotating with the rotation of the second bevel gear.
  • the transmission mechanism further includes a sun gear, a planetary gear and a planet carrier, the sun gear is fixed to the fan shaft, the planetary gear is fixed on the planet carrier by a planetary gear shaft, and surrounds the sun Gear revolution;
  • One end of the planetary gear shaft is fixed to the planetary gear, and the other end is perpendicularly fixed to an end surface of the first bevel gear from an axial direction of the first bevel gear, and the first bevel gear revolves with the planetary gear Rotate;
  • An output shaft of the driving motor is provided with an interconnected nut and a screw, the screw is fixed to an output shaft of the driving motor, and the wire moves linearly with the rotation of the driving motor; Hinged to the planet carrier, the planet carrier swings with the linear movement of the nut to drive the revolution of the planetary gear.
  • the fan blade adjusting device further comprises a feedback mechanism connected to the control host, the feedback mechanism comprising an angular displacement detecting component;
  • the angular displacement detecting component is configured to measure a mounting angle variation value of the fan blade, and send the installation angle variation value to the control host;
  • a measuring rod of the angular displacement detecting member is coupled to the vane shaft, and a measuring rod of the angular displacement detecting member rotates in accordance with rotation of the vane shaft.
  • the feedback mechanism further includes a measured value amplifying mechanism, the measured value amplifying mechanism includes a driving gear and a driven gear that mesh with each other, the number of teeth of the driving gear is greater than the number of teeth of the driven gear; Connected to the vane shaft, the driving gear rotates with the rotation of the vane shaft; the driven gear is coupled to a measuring rod of the angular displacement detecting member, and the measuring rod of the angular displacement detecting member is The driven gear rotates while rotating.
  • the measured value amplifying mechanism includes a driving gear and a driven gear that mesh with each other, the number of teeth of the driving gear is greater than the number of teeth of the driven gear; Connected to the vane shaft, the driving gear rotates with the rotation of the vane shaft; the driven gear is coupled to a measuring rod of the angular displacement detecting member, and the measuring rod of the angular displacement detecting member is The driven gear rotates while rotating.
  • the fan blade adjusting device further comprises an instruction processing mechanism
  • the instruction processing mechanism is configured to issue a second instruction indicating that the adjustment actuator is executed according to the first instruction of the control host to adjust the installation angle of the fan blade;
  • the instruction processing mechanism is further configured to reply to the control host according to the detection data of the feedback mechanism;
  • the instruction processing mechanism is respectively connected to the control host, the adjustment actuator, and the feedback mechanism.
  • the instruction processing mechanism includes a host instruction receiving component, an instruction processing component, and a host command reply component; the host command receiving component and the host command reply component are both fixed on an outer wall of the air duct of the fan, and are wired. Communicating with the control host; the host command receiving component and the host command reply component are wirelessly connected to the command processing component.
  • the fan blade adjusting device further includes a power generating mechanism that supplies power to the adjusting actuator, the feedback mechanism, and the command processing mechanism, the power generating mechanism includes a stator and a rotor; and the stator and the rotor are respectively fixed to the fan motor and the fan The end faces of the impellers.
  • the stator faces the end face of the fan impeller with a circumferentially uniformly distributed permanent magnet block
  • the rotor is provided with a coil corresponding to the permanent magnet block, and the coil and the permanent magnet block are axially spaced There is a preset gap.
  • the embodiment of the invention further provides a pair of rotary blowers, comprising two fan blades of the same diameter and hub ratio, the same rotational speed and opposite rotation directions, each of the fan impellers being provided with any one of the above. Fan blade adjustment device.
  • the embodiment of the invention further provides a method for adjusting a fan blade, the method comprising:
  • an adjustment actuator that is commanded to be connected to more than one fan blade on the fan adjusts the installation angle of the fan blade.
  • the adjusting actuator that is configured to be connected to more than one fan blade on the fan according to the actual air volume of the fan, adjusts the installation angle of the fan blade, including:
  • the method further includes:
  • the fan blade adjusting device, the pairing fan and the fan blade adjusting method provided by the embodiments of the present invention obtain the actual air volume of the fan; according to the actual air volume of the fan, the command and the fan are used.
  • the adjusting actuator of the above fan blade connection adjusts the installation angle of the fan blade; it can be seen that the fan blade adjusting device adjusts the installation angle of the fan blade in time according to the actual air volume of the fan.
  • the adjustment is carried out by the drive motor and the transmission mechanism including at least the first-stage reduction transmission, without using the complicated and large-sized hydraulic system, the installation angle of the fan blade can be adjusted accurately and timely, the remote automatic adjustment can be realized, and the wind is occupied.
  • the barrel space is small.
  • FIG. 1 is a schematic structural view of a fan blade adjusting device according to an embodiment of the present invention
  • FIG. 2 is a schematic structural diagram of a detailed configuration of a fan blade adjusting device according to an embodiment of the present invention
  • FIG. 3 is a schematic view of a fan impeller in a fan blade adjusting device according to an embodiment of the present invention
  • FIG. 4 is a schematic view of an adjustment actuator in a fan blade adjusting device according to an embodiment of the present invention.
  • FIG. 5 is a schematic structural view of an adjustment actuator and a feedback mechanism in a fan blade adjusting device according to an embodiment of the present invention
  • Figure 6 is a schematic structural view of the encoder and the measurement value amplifying mechanism of Figure 5;
  • FIG. 7 is a schematic view of a command processing mechanism in a fan blade adjusting device according to an embodiment of the present invention.
  • FIG. 8 is a schematic diagram of a power generating mechanism in a fan blade adjusting device according to an embodiment of the present invention.
  • FIG. 9 is a schematic flow chart of a method for adjusting a fan blade according to an embodiment of the present invention.
  • An embodiment of the present invention provides a fan blade adjusting device, the fan blade adjusting device includes a control host and an adjusting actuator, and the control host is configured to instruct the adjusting actuator to wind the blade according to an actual air volume of the fan.
  • the installation angle is adjusted; the adjustment actuator is configured to adjust the installation angle of the fan blade according to an instruction of the control host.
  • the fan includes a air cylinder, a fan motor, a fan shaft, and a fan impeller, and the fan The impeller is provided with more than one fan blade, which is evenly distributed along the circumferential direction of the fan impeller.
  • the principle of the embodiment of the present invention is: adjusting the installation angle of the fan blade according to the actual air volume of the fan, and adjusting by using a driving motor and a transmission mechanism including at least a first-stage reduction transmission, without using a complicated structure and a large volume
  • the hydraulic system can not only precisely adjust the installation angle of the fan blades, but also realize remote automatic adjustment and occupy small air duct space.
  • FIG. 1 is a schematic structural diagram of a fan blade adjusting device according to an embodiment of the present invention. As shown in FIG. 1 , the fan blade adjusting device includes a control host 11 and an adjusting actuator.
  • the control host 11 is configured to instruct the adjustment actuator to adjust the installation angle of the fan blade 101 according to the actual air volume of the fan 10;
  • the adjustment actuator is configured to adjust an installation angle of the fan blade 101 according to an instruction of the control host 11;
  • the adjustment actuator includes a drive motor 12 and a transmission mechanism 13 including at least one primary reduction drive; an output shaft of the drive motor 12 is coupled to an input end of the transmission mechanism 13;
  • the transmission mechanism 13 includes at least a first-stage reduction transmission, so that the rotation speed of the drive motor 12 can be reduced and then transmitted to the fan blade 101, which makes it easier to ensure the adjustment accuracy;
  • the transmission mechanism 13 can be provided with two or more stages of reduction transmission.
  • the fan blade adjusting device includes a control host 11, a driving motor 12, a transmission mechanism 13, an encoder 141, An air volume sensor 111, an instruction processing mechanism 15, and a power generation mechanism 16; wherein
  • the control host 11 may be a computer, and the control host 11 acquires the actuality of the fan 10.
  • the airflow amount may be acquired by the air volume sensor 111; the memory of the control host 11 stores a preset correspondence relationship between the fan blade mounting angle and the air volume of the fan 10;
  • the control host 11 sends an instruction to adjust the installation angle of the fan blade to the drive motor 12 in the adjustment actuator, and the memory of the control host 11 stores a preset change value of the installation angle of the fan blade.
  • the correspondence relationship of the rotational angles of the drive motor 12 is described.
  • the drive motor 12 may be a servo motor, and more preferably, the drive motor 12 may be a DC servo motor;
  • the command processing mechanism 15 is configured to issue a second instruction indicating that the adjustment actuator is executed according to the first instruction of the control host 11 to adjust the installation angle of the fan blade;
  • the first command includes the fan blade mounting angle adjustment value, the first command is sent to the command processing mechanism 15 by a pulse signal;
  • the fan blade mounting angle adjustment value is first expressed as a binary number, and the binary number is converted into a pulse signal and sent to the command processing mechanism 15.
  • the second command is a control command for controlling the driving motor 12, that is, the driving motor 12 is instructed to rotate or reverse a preset angle, and the preset angle is adjusted according to the installation angle of the fan blade.
  • the transmission ratio of the transmission mechanism 13 is determined;
  • the second instruction may be a pulse signal including an instruction of forward rotation, reverse rotation, or the like;
  • the rotational speed of the drive motor 12 can be set to be constant, such that the content of the command to control the drive motor 12 includes only steering and time, for example, when it is necessary to adjust the installation angle of the fan blade, The command to rotate forward or reverse and the time of rotation;
  • the rotational speed of the drive motor 12 is generally set to a constant low speed.
  • the drive motor 12 can be other control motors, for example, The drive motor 12 can be a stepper motor.
  • FIG. 3 is a schematic view of a fan impeller in a fan blade adjusting device according to an embodiment of the present invention.
  • a fan shaft 102 is disposed at one end of the fan blade 101 toward the fan shaft, and a mounting angle of the fan blade 101 is provided.
  • the output of the transmission mechanism 13 is coupled to the vane shaft 102 as the vane shaft 102 rotates.
  • the transmission mechanism 13 includes a first bevel gear 131 and a second bevel gear 132 that mesh with each other, and the first bevel gear 131 can rotate with the rotation of the drive motor 12; the first bevel gear 131 Rotating relative to the fan shaft with the axis of the fan shaft as an axis, and driving the second bevel gear 132 to rotate; the second bevel gear 132 is mounted on the vane shaft 102, and the vane shaft 102 can follow the second The bevel gear 132 rotates while rotating;
  • the first bevel gear 131 is a driving bevel gear
  • the second bevel gear 132 is a driven bevel gear
  • the cooperation of the first bevel gear 131 and the second bevel gear 132 realizes a vertical intersecting fan shaft and Power transmission of the blade shaft 102.
  • the transmission mechanism 13 further includes a sun gear 133, a planetary gear 134, and a carrier 135, the sun gear 133 is fixed to the fan shaft, and the planetary gear 134 is fixed by a planetary gear shaft.
  • One end of the planetary gear shaft is fixed to the planetary gear 134, and the other end is perpendicularly fixed to an end surface of the first bevel gear 131 from an axial direction of the first bevel gear 131.
  • the first bevel gear 131 can follow Rotating the planetary gear 134 for revolution;
  • the output shaft of the driving motor 12 is provided with an interconnecting nut 121 and a screw 122.
  • the screw 122 is fixed to an output shaft of the driving motor 12, and the nut 121 can rotate with the driving motor 12. And moving linearly; the nut 121 is hinged to the planet carrier 135, and the planet carrier 135 can swing with the linear movement of the nut 121 to drive the revolution of the planetary gear 134.
  • the transmission process of the transmission mechanism 13 is: the driving motor 12 rotates to drive The screw 122 rotates, the rotation of the screw 122 drives the linear movement of the nut 121, and the linear movement of the nut 121 drives the swing of the carrier 135, and the swing of the carrier 135 drives The revolution of the planetary gear 134, the revolution of the planetary gear 134 drives the first bevel gear 131 to rotate relative to the fan shaft with the axis of the fan shaft as an axis, and the rotation of the first bevel gear 131 drives the second cone
  • the rotation of the gear 132 causes the rotation of the second bevel gear 132 to drive the rotation of the blade shaft 102, and the rotation of the blade shaft 102 drives the fan blade 101 to change the installation angle.
  • both the planetary gear 134 and the sun gear 133 can be machined in a part of the circumference, so that the processing is convenient;
  • the lead screw 122 and the output shaft of the drive motor 12 may be integrated;
  • the driving motor 12 and the vane shaft 102 pass through a four-stage transmission, and the rotational speed of the vane shaft 102 is substantially lower than the rotational speed of the driving motor 12, thereby greatly improving the adjustment of the mounting angle of the fan blade. Precision.
  • the transmission mechanism 13 can be other types of transmission structures, and can be used in the implementation of the present invention as long as the rotation of the drive motor 12 can be converted into the change of the installation angle of the fan blade and meets certain precision requirements. example.
  • the fan blade adjusting device further includes a feedback mechanism connected to the control host 11, and the feedback mechanism includes an encoder 141, that is, an angular displacement detecting component;
  • the encoder 141 is configured to measure a mounting angle variation value of the fan blade 101, and send the installation angle variation value to the control host 11; the measuring rod of the encoder 141 and the The vane shaft 102 is coupled, and the measuring rod of the encoder 141 rotates in accordance with the rotation of the vane shaft 102.
  • the feedback mechanism further includes amplifying a variation value of the installation angle of the fan blade Then inputting the measured value amplifying mechanism of the encoder 141;
  • FIG. 6 is a schematic structural view of the encoder 141 and the measurement value amplifying mechanism of FIG. 5.
  • the figure includes an encoder 141 and a measured value amplifying mechanism, and the measured value amplifying mechanism includes a driving gear 142 that meshes with each other.
  • the driven gear 143, the number of teeth of the driving gear 142 is larger than the number of teeth of the driven gear 143;
  • the driving gear 142 is coupled to the blade shaft 102, and the driving gear 142 rotates with the rotation of the blade shaft 102
  • the driven gear 143 is coupled to the measuring rod of the encoder 141, and the measuring rod of the encoder 141 rotates with the rotation of the driven gear 143;
  • the number of teeth of the driving gear 142 is much larger than the number of teeth of the driven gear 143, so the angular velocity of the driven gear 143 is much larger than the angular velocity of the driving gear 142, that is, the blade is mounted.
  • the value of the angle is magnified;
  • the accuracy of the feedback mechanism for measuring the mounting angle variation value of the fan blade 101 is greatly improved.
  • the measuring rod of the encoder 141 may be coupled to the shaft of the driven gear 143 via a coupling 144; the outer circumference of the driving gear 142 may be formed in the form of an outer spline groove, the vane shaft 102
  • the drive gear 142 can be coupled by providing a key on the shaft that matches the outer spline slot.
  • the angular displacement detecting component may be other detecting components capable of detecting a change in the mounting angle of the fan blade.
  • the angular displacement detecting component may also be an angle sensor.
  • the command processing mechanism 15 is respectively connected to the control host 11, the drive motor 12, and the encoder 141.
  • the command processing mechanism 15 is further configured to:
  • the detection data of the encoder 141 is a binary number indicating a value of the installation angle of the fan blade
  • the command processing unit 15 converts a binary number indicating the fan blade mounting angle variation value into a pulse signal to return to the control host 11.
  • the instruction processing unit 15 includes an instruction processing unit 151, a host instruction reply unit 152, and a host command receiving unit 153; the host command reply unit 152 and the host command receiving unit 153 are both fixed to the outer wall of the air cylinder, and are wired.
  • the method is in communication with the control host 11; the host command reply component 152 and the host command receiving component 153 are communicably connected to the command processing component 151 by means of infrared ray;
  • the instruction processing component 151 may be a single chip microcomputer, and the host command reply component 152 and the host command receiving component 153 may be an infrared emitter and an infrared receiver, respectively;
  • the command processing component 151 follows the rotation of the fan impeller, that is, the fan impeller is rotated by the fan motor 105, and the command processing component 151 is fixed to the fan impeller, thus adopting wireless
  • the communication with the control host 11 is convenient and reliable;
  • the command processing unit 151 is provided with a fiber transceiver 154.
  • the fiber optic transceiver 154 protrudes from the fan impeller end face, and the host command recovery component 152 and the host command receiving component 153 are mounted at positions corresponding to the fiber optic transceiver 154;
  • the end face of the blade impeller is provided with a transparent fiber transceiver cover 155; the portion of the fiber transceiver 154 protruding from the end face of the fan impeller is tapered, so that The optical fiber receiving the signal exposes the protective sheath of the optical fiber;
  • the fiber transceiver cover 155 can be made of a material of plexiglass
  • command processing mechanism 15 can also communicate with the control host 11 by using other wireless signals, such as Bluetooth, 2.4G wireless signals.
  • the fan blade adjusting device further includes a power generating mechanism 16 that supplies power to the adjusting actuator, the feedback mechanism, and the command processing mechanism, the power generating mechanism 16 including a stator 161 and a rotor 162;
  • the stator 161 and the rotor 162 are respectively fixed to opposite end faces of the fan motor 105 and the fan impeller;
  • stator 161 is provided with a circumferentially uniform permanent magnet block 163 facing the end surface of the fan impeller, and the rotor 162 is provided with a coil 164 corresponding to the permanent magnet block 163, the coil 164 and the permanent
  • the magnetic block 163 is axially spaced with a predetermined gap;
  • the stator 161 does not rotate with the rotation of the motor shaft 106, and the rotor 162 rotates with the rotation of the motor shaft 106, so that the stator 161 and the rotor 162 are relatively rotated; that is, the coil 164 cuts the magnetic lines of the permanent magnet block 163, resulting in Inducing an electromotive force to supply power to the adjustment actuator and the feedback mechanism;
  • the coil 164 and the permanent magnet block 163 are axially spaced apart by a predetermined gap, and the main function is to avoid the friction loss of the stator 161 and the rotor 162 during the rotation, that is, the air gap of the motor, but in order to ensure a sufficient magnetic flux,
  • the gap between the coil 164 and the permanent magnet block 163 is as small as possible.
  • the permanent magnet block 163 may be made of samarium cobalt (SmCo) material;
  • the permanent magnet block 163 can also be made of other materials such as neodymium iron boron (Nd2Fe14B), ferrite (Ferrite) and the like.
  • the power supply mechanism 16 supplies power to the adjustment actuator, the feedback mechanism, and the command processing mechanism 15, which can save energy consumption, is safer and more reliable, because the adjustment actuator, the feedback mechanism and the instruction
  • the processing mechanism 15 is fixed on the fan impeller.
  • the fan impeller continuously rotates when the fan 10 is in operation. Therefore, it is difficult to connect the electric energy from the outside of the fan impeller through the wire, and the wire is relatively easy to damage. of.
  • the fan blade adjusting device is further provided with a rectifying unit 17 configured to convert the alternating current output by the power generating mechanism 16 into direct current and input the command Agency 15;
  • the command processing mechanism also uses the obtained electric energy for the adjustment actuator and the feedback mechanism.
  • the embodiment of the present invention further provides a pair of rotary blowers, comprising two fan blades of the same diameter and hub ratio, the same rotational speed and opposite rotation directions, each of which is provided with a fan blade adjusting device;
  • the components of the fan blade adjusting device, the connection relationship between the components, and the functional principle of each component are the same as those of the fan blade adjusting device in the first embodiment, and will not be described again.
  • FIG. 9 is a schematic flow chart of a method for adjusting a fan blade according to an embodiment of the present invention. As shown in FIG. 9, the method includes:
  • Step 801 Acquire an actual air volume of the fan
  • control host acquires the actual air volume of the fan, and specifically, the control host acquires the air volume sensor.
  • Step 802 Adjust an installation angle of the fan blade by an adjustment actuator that is connected to one or more fan blades on the fan according to an actual air volume of the fan.
  • the adjusting actuator that is connected to one or more fan blades on the fan to adjust the installation angle of the fan blade according to the actual air volume of the fan includes:
  • the control host instructs the adjustment actuator to adjust the installation angle of the fan blade according to the installation angle adjustment value of the fan blade.
  • the preset correspondence relationship between the installation angle of the fan blade and the air volume of the fan may be A relationship of changing trend, for example, when the fan blade mounting angle is between X1° and X2°, the wind blade installation angle increases or decreases by 0.5°, and the air volume increases or decreases by Y1 cubic meters per second; When the installation angle of the fan blade is between X3° and X4°, the wind turbine blade installation angle increases or decreases by 0.5°, the air volume increases or decreases by Y2 cubic meters per second, etc., wherein the installation angle of the fan blade is positive The direction is preset.
  • the corresponding relationship between the installation angle of the fan blade and the air volume of the fan is non-linear, and the corresponding relationship between the installation angle of the fan blade and the air volume of the fan is an approximation.
  • the corresponding relationship between the installation angle of the fan blade and the air volume of the fan may be preset to the control host by establishing a mathematical formula including a plurality of variation factors; wherein, the specific mathematical formula and the variation factor The value is not the content of the present invention and will not be described.
  • the corresponding relationship between the installation angle of the fan blade and the air volume of the fan may be a result of a theoretical calculation, or may be a result of an actual test, or may be a result of combining the two;
  • the control host instructs the adjustment actuator to adjust the installation angle of the fan blade according to the installation angle adjustment value of the fan blade, including: the adjustment actuator passes the drive motor and the transmission mechanism including at least one stage reduction drive Realizing adjustment of the installation angle of the fan blade;
  • the transmission mechanism includes at least one stage reduction drive for improving the accuracy of adjusting the installation angle of the fan blade.
  • the method further includes:
  • the control host acquires a mounting angle variation value of the fan blade measured by a feedback mechanism, and determines an installation angle adjustment error value of the fan blade;
  • the control host re-determines the error according to the installation angle adjustment error value of the fan blade
  • the installation angle of the fan blade is adjusted, and the adjustment actuator is instructed to adjust the installation angle of the fan blade until the installation angle adjustment error value of the fan blade meets a preset threshold.
  • control host can further control the accuracy of adjusting the installation angle of the fan blade
  • the instruction processing mechanism is further required to convert a binary digit representing the fan blade installation angle variation value into a pulse signal to return to the control host;
  • the command processing mechanism communicates with the control host by means of infrared rays.
  • the control host needs to determine a new fan blade according to the corresponding relationship between the fan blade installation angle and the fan air outlet amount. Install the angle until the fan airflow meets the requirements.
  • control host After the adjustment is completed, the control host records the data of the fan blade installation angle and the fan air outlet amount, so that the preset correspondence relationship between the fan blade installation angle and the fan air outlet amount can be corrected later.
  • the fan blade adjusting device adjusts the installation angle of the fan blade in time according to the actual air volume of the fan, and the adjustment is performed by the driving motor and the transmission mechanism including at least the first-stage reduction transmission, without using a complicated structure.
  • the large hydraulic system can adjust the installation angle of the fan blade accurately and timely, and can also realize remote automatic adjustment and occupy small air duct space.

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  • Structures Of Non-Positive Displacement Pumps (AREA)

Abstract

一种风机叶片调节装置,风机叶片调节装置包括控制主机(11)和调节执行机构;其中,控制主机(11),配置为根据风机(10)的实际出风量,指令调节执行机构对风机叶片(101)的安装角进行调整;调节执行机构,配置为根据控制主机(11)的指令,对风机叶片(101)的安装角进行调整。该风机叶片调节装置不必使用结构复杂及体积大的液压系统,既能精确调节风机叶片的安装角,也能实现远程自动化调节,且占用风筒空间小。还涉及一种对旋风机和风机叶片调节方法。

Description

一种风机叶片调节装置、对旋风机和风机叶片调节方法
相关申请的交叉引用
本申请基于申请号为201710730730.0、申请日为2017年8月23日的中国专利申请提出,并要求该中国专利申请的优先权,该中国专利申请的全部内容在此引入本申请作为参考。
技术领域
本发明涉及轴流风机技术领域,具体涉及一种风机叶片调节装置、对旋风机和风机叶片调节方法。
背景技术
风机或通风机是配置为输送气体的机械设备,从能量观点来看,风机或通风机是将原动机的机械能转变为气体能量的一种机械设备。从气体压力升高的原理出发,主要可分为容积式、叶片式和喷射式,其中,叶片式风机可进一步分为离心式、混流式、轴流式和横流式。
由于对风量和风压要求较高,在煤矿等矿井内一般采用对旋风机。对旋风机,也称对旋轴流式风机,是指前后串连两个叶轮的轴流式风机,两个叶轮的直径、轮毂比、转速都相同,而旋转方向相反。通常两个叶轮由两个电机分别驱动,这样设计的优点包括:1)在流量相同的情况下,能显著地增加压强增益,克服轴流风机总压增益相对较低的固有弱点;2)不需要任何导流片,缩短轴向尺寸,使结构变得简单;而且去掉导流片后,风阻降低,使效率更高、噪声更低;3)由于采用了双电机、双端拖动,使每部电机容量大幅度下降,使风机的供电及电控设备的投资额和操作控制技术要求大幅度降低。
但是,目前市场上的对旋风机多采用整体式叶轮,其叶片安装角不可调节。这样,无论是设计或制造中存在错误或误差,还是在使用过程中出现需要调节叶片安装角的情况,都无法方便及快速调节,使得对旋风机工作效率偏低,并容易出现喘振等现象,加剧振动,影响使用寿命。
因此,在对旋风机的制造中,开始研发叶片安装角能调节的技术;如:公开号为CN103727062A、发明名称为“一种轴流风机动叶片调节装置”的发明专利申请,主要由动叶片、传动组、轮毂、液压传动系统、控制盘等组成;所述叶片调节装置的动力来自液压动力系统,这种结构一是成本较高,因为液压动力系统包括泵站、管路、伺服阀、伺服油缸等一系列零部件,还有相当一部分零件需要特制,工艺复杂,维护成本高,限制了该装置在中小型风机中的应用;二是其采用的液压动力系统占用空间较大且置于风筒内部,在空间狭小的风筒内影响了空气的流动,限制了风轮轮毂的大小,导致风机的效率偏低;三是通过液压动力调节叶片安装角的调节精度不够高,无法使对旋风机在最佳效率点工作。
再如,公开号为CN105673560A、发明名称为“对旋轴流式风机双级叶片调节机构”的发明专利申请,通过一系列齿轮副与螺纹副的组合,将调节的回转运动转化为两级叶轮推力盘的直线运动,以此来调整两级叶轮的叶片安装角。该申请实现了两级叶片安装角的同步调节,且成本较低;但是,该装置在调节叶片时需要人工手动转动手轮,实现远程调节需要加装外接动力源,并未实现叶片安装角的远程自动化调节。
发明内容
有鉴于此,本发明实施例期望提供一种风机叶片调节装置、对旋风机和风机叶片调节方法,能精确调节风机叶片的安装角,便于远程自动化调节。
为达到上述目的,本发明的技术方案是这样实现的:
本发明实施例提供了一种风机叶片调节装置,与风机上的一个以上风机叶片连接,所述风机叶片调节装置包括控制主机和调节执行机构;其中,
所述控制主机,配置为根据风机的实际出风量,指令所述调节执行机构对风机叶片的安装角进行调整;
所述调节执行机构,配置为根据所述控制主机的指令,对所述风机叶片的安装角进行调整。
优选地,所述调节执行机构包括驱动电机和至少包括一级减速传动的传动机构;所述驱动电机的输出轴连接所述传动机构的输入端;所述风机叶片朝向风机轴的一端设有叶片轴,所述风机叶片的安装角随所述叶片轴的转动而改变,所述传动机构的输出端连接所述叶片轴。
优选地,所述传动机构包括相互啮合的第一圆锥齿轮和第二圆锥齿轮,所述第一圆锥齿轮随所述驱动电机的转动而转动;所述第一圆锥齿轮以所述风机轴的轴线为轴线相对于风机轴转动,并驱动所述第二圆锥齿轮转动;所述第二圆锥齿轮安装于所述叶片轴上,所述叶片轴随第二圆锥齿轮的转动而转动。
优选地,所述传动机构还包括太阳齿轮、行星齿轮和行星架,所述太阳齿轮固定于所述风机轴,所述行星齿轮通过行星齿轮轴固定于所述行星架上,并围绕所述太阳齿轮公转;
所述行星齿轮轴一端固定于所述行星齿轮,另一端从所述第一圆锥齿轮的轴向垂直固定于所述第一圆锥齿轮的端面,所述第一圆锥齿轮随所述行星齿轮的公转而转动;
所述驱动电机的输出轴上设有相互连接的丝母和丝杆,所述丝杆固定于所述驱动电机的输出轴,所述丝母随驱动电机的转动而直线移动;所述丝母铰接于所述行星架,所述行星架随所述丝母的直线移动而摆动,带动所述行星齿轮的公转。
优选地,所述风机叶片调节装置还包括反馈机构,与所述控制主机连接,所述反馈机构包括角位移检测部件;
所述角位移检测部件,配置为测量所述风机叶片的安装角变动值,并将所述安装角变动值发送给所述控制主机;
所述角位移检测部件的测量杆与所述叶片轴连接,所述角位移检测部件的测量杆随所述叶片轴的转动而转动。
优选地,所述反馈机构还包括测量值放大机构,所述测量值放大机构包括相互啮合的主动齿轮和从动齿轮,所述主动齿轮的齿数大于所述从动齿轮的齿数;所述主动齿轮与所述叶片轴连接,所述主动齿轮随所述叶片轴的转动而转动;所述从动齿轮与所述角位移检测部件的测量杆连接,所述角位移检测部件的测量杆随所述从动齿轮的转动而转动。
优选地,所述风机叶片调节装置还包括指令处理机构;
所述指令处理机构,配置为根据所述控制主机调整所述风机叶片安装角的第一指令,发出指示所述调节执行机构执行的第二指令;
所述指令处理机构,还配置为根据所述反馈机构的检测数据回复所述控制主机;
所述指令处理机构分别连接所述控制主机、调节执行机构和反馈机构。
优选地,所述指令处理机构包括主机指令接收部件、指令处理部件和主机指令回复部件;所述主机指令接收部件和主机指令回复部件均固定在所述风机的风筒外壁,且通过有线的方式与所述控制主机通讯连接;所述主机指令接收部件和主机指令回复部件通过无线方式与所述指令处理部件通讯连接。
优选地,所述风机叶片调节装置还包括向所述调节执行机构、反馈机构和指令处理机构供电的发电机构,所述发电机构包括定子和转子;所述定子和转子分别固定在风机电机和风机叶轮相向的端面。
优选地,所述定子朝向所述风机叶轮的端面设置有圆周方向均布的永磁块,所述转子设有与所述永磁块对应的线圈,所述线圈和永磁块在轴向间隔有预设的间隙。
本发明实施例还提供了一种对旋风机,包括前后串联的两个直径、轮毂比、转速都相同且旋转方向相反的风机叶轮,每个所述风机叶轮均设有如上面所述的任意一种风机叶片调节装置。
本发明实施例还提供了一种风机叶片调节方法,所述方法包括:
获取风机的实际出风量;
根据所述风机的实际出风量,指令与风机上一个以上风机叶片连接的调节执行机构对所述风机叶片的安装角进行调整。
优选地,所述根据所述风机的实际出风量,指令与风机上一个以上风机叶片连接的调节执行机构对所述风机叶片的安装角进行调整,包括:
根据所述风机的实际出风量和风机叶片安装角与风机出风量的预设对应关系,确定所述风机叶片的安装角调整值;
根据所述风机叶片的安装角调整值,指令所述调节执行机构对所述风机叶片的安装角进行调整。
优选地,在指令与风机上一个以上风机叶片连接的调节执行机构对所述风机叶片的安装角进行调整之后,所述方法还包括:
获取反馈机构测量的所述风机叶片的安装角变动值,确定所述风机叶片的安装角调整误差值;
根据所述风机叶片的安装角调整误差值,重新确定所述风机叶片的安装角调整值,并指令所述调节执行机构对所述风机叶片的安装角进行调整,直至所述风机叶片的安装角调整误差值符合预设阈值。
本发明实施例提供的风机叶片调节装置、对旋风机和风机叶片调节方法,获取风机的实际出风量;根据风机的实际出风量,指令与风机上一个 以上风机叶片连接的调节执行机构对所述风机叶片的安装角进行调整;可见,本发明实施例由风机叶片调节装置,根据风机的实际出风量,及时对所述风机叶片的安装角进行调整,且调整通过驱动电机和至少包括一级减速传动的传动机构进行,不必使用结构复杂及体积大的液压系统,既能精确及时地调节风机叶片的安装角,也能实现远程自动化调节,且占用风筒空间小。
附图说明
图1为本发明实施例一风机叶片调节装置的组成结构示意图;
图2为本发明实施例一风机叶片调节装置的详细组成结构示意图;
图3为本发明实施例一风机叶片调节装置中风机叶轮的示意图;
图4为本发明实施例一风机叶片调节装置中调节执行机构的示意图;
图5为本发明实施例一风机叶片调节装置中调节执行机构和反馈机构的结构示意图;
图6为图5中编码器和测量值放大机构的结构示意图;
图7为本发明实施例一风机叶片调节装置中指令处理机构的示意图;
图8为本发明实施例一风机叶片调节装置中发电机构的示意图;以及
图9为本发明实施例三风机叶片调节方法的流程示意图。
具体实施方式
本发明实施例提供了一种风机叶片调节装置,所述风机叶片调节装置包括控制主机和调节执行机构,所述控制主机,配置为根据风机的实际出风量,指令所述调节执行机构对风机叶片的安装角进行调整;所述调节执行机构,配置为根据所述控制主机的指令,对所述风机叶片的安装角进行调整。
这里,所述风机包括风筒、风机电机、风机轴和风机叶轮,所述风机 叶轮设有一个以上的风机叶片,沿所述风机叶轮圆周方向均布。
本发明实施例的原理是:根据风机的实际出风量,对所述风机叶片的安装角进行调整,且调整通过驱动电机和至少包括一级减速传动的传动机构进行,不必使用结构复杂及体积大的液压系统,既能精确调节风机叶片的安装角,也能实现远程自动化调节,且占用风筒空间小。
为了能够更加详尽地了解本发明实施例的特点与技术内容,下面结合附图以及具体的应用实施例对本发明做进一步的阐述,所附附图仅供参考说明之用,并非用来限定本发明实施例。
实施例一
图1为本发明实施例一风机叶片调节装置的组成结构示意图,如图1所示,所述风机叶片调节装置包括控制主机11和调节执行机构,其中,
所述控制主机11,配置为根据风机10的实际出风量,指令所述调节执行机构对风机叶片101的安装角进行调整;
所述调节执行机构,配置为根据所述控制主机11的指令,对所述风机叶片101的安装角进行调整;
具体地,所述调节执行机构包括驱动电机12和至少包括一级减速传动的传动机构13;所述驱动电机12的输出轴连接所述传动机构13的输入端;
所述传动机构13至少包括一级减速传动,这样,可以将驱动电机12的转动速度降低后传动到所述风机叶片101,更容易保证调节精度;
能够理解的是,所述传动机构13可以设有两级或两级以上的减速传动。
图2为本发明实施例一风机叶片调节装置的详细组成结构示意图;如图2所示,所述风机叶片调节装置包括控制主机11、驱动电机12、传动机构13、编码器(encoder)141、风量传感器111、指令处理机构15和发电机构16;其中,
所述控制主机11可以是计算机,所述控制主机11获取风机10的实际 出风量可以是通过风量传感器111获取;所述控制主机11的存储器保存有风机叶片安装角与所述风机10出风量的预设对应关系;
所述控制主机11将对风机叶片的安装角进行调整的指令发送给调节执行机构中的驱动电机12,所述控制主机11的存储器保存有预设的所述风机叶片安装角的改变值与所述驱动电机12的转动角度的对应关系。
所述驱动电机12可以是伺服电机,更优选地,所述驱动电机12可以是直流伺服电机;
所述指令处理机构15,配置为根据所述控制主机11调整所述风机叶片安装角的第一指令,发出指示所述调节执行机构执行的第二指令;
这里,所述第一指令包括所述风机叶片安装角调整值,所述第一指令通过脉冲信号发送到所述指令处理机构15;
具体地,先将所述风机叶片安装角调整值表示为二进制数字,再将所述二进制数转换为脉冲信号发送到所述指令处理机构15。
所述第二指令为控制所述驱动电机12的控制指令,即指令所述驱动电机12正转或反转预设的角度,所述预设的角度根据所述风机叶片安装角调整值和所述传动机构13的传动比确定;
具体地,如果所述驱动电机12为伺服电机,则所述第二指令可以是包括正转、反转等指令的脉冲信号;
更具体地,为了控制简便,可以将所述驱动电机12的转速设置为恒定,这样,控制所述驱动电机12的指令内容就只包括转向和时间,例如需要调整风机叶片安装角时,只需发出正转或反转的指令和转动的时间;
另外,因为风机叶片安装角的调整是在风机转动不停止的情况下,为保证调整过程中的平稳,调整的速度不能太高,由此所述驱动电机12的转速一般设置为恒定的低速。
能够理解的是,所述驱动电机12可以是其它的控制电机,例如,所述 驱动电机12可以是步进电机。
图3为本发明实施例一风机叶片调节装置中风机叶轮的示意图,如图3所示,所述风机叶片101朝向所述风机轴的一端设有叶片轴102,所述风机叶片101的安装角随所述叶片轴102的转动而改变,所述传动机构13的输出端连接所述叶片轴102。
具体地,所述传动机构13包括相互啮合的第一圆锥齿轮131和第二圆锥齿轮132,所述第一圆锥齿轮131能随所述驱动电机12的转动而转动;所述第一圆锥齿轮131能以风机轴的轴线为轴线相对于风机轴转动,并驱动所述第二圆锥齿轮132转动;所述第二圆锥齿轮132安装于所述叶片轴102上,所述叶片轴102能随第二圆锥齿轮132的转动而转动;
这里,所述第一圆锥齿轮131是主动锥齿轮,所述第二圆锥齿轮132是从动锥齿轮,所述第一圆锥齿轮131和第二圆锥齿轮132的配合实现了垂直相交的风机轴和叶片轴102的动力传递。
进一步地,如图4所示,所述传动机构13还包括太阳齿轮133、行星齿轮134和行星架135,所述太阳齿轮133固定于所述风机轴,所述行星齿轮134通过行星齿轮轴固定于所述行星架135上,并能围绕所述太阳齿轮133公转;
所述行星齿轮轴一端固定于所述行星齿轮134,另一端从所述第一圆锥齿轮131的轴向垂直固定于所述第一圆锥齿轮131的端面,所述第一圆锥齿轮131能随所述行星齿轮134的公转而转动;
所述驱动电机12的输出轴上设有相互连接的丝母121和丝杆122,所述丝杆122固定于所述驱动电机12的输出轴,所述丝母121能随驱动电机12的转动而直线移动;所述丝母121铰接于所述行星架135,所述行星架135能随所述丝母121的直线移动而摆动,带动所述行星齿轮134的公转。
具体地,所述传动机构13的传动过程为:所述驱动电机12转动带动 所述丝杆122转动,所述丝杆122的转动带动所述丝母121的直线移动,所述丝母121的直线移动带动所述行星架135的摆动,所述行星架135的摆动带动所述行星齿轮134的公转,所述行星齿轮134的公转带动所述第一圆锥齿轮131以风机轴的轴线为轴线相对于风机轴转动,所述第一圆锥齿轮131的转动带动所述第二圆锥齿轮132的转动,所述第二圆锥齿轮132的转动带动所述叶片轴102的转动,所述叶片轴102的转动带动所述风机叶片101改变安装角。
更具体地,由于风机叶片安装角的变动范围比较小,所述行星齿轮134和太阳齿轮133均可以是在圆周的一部分加工出齿形,这样加工也方便;
同理,为了加工方便,所述丝杆122和所述驱动电机12的输出轴可以是一体的;
本实施例中,所述驱动电机12和叶片轴102之间经过了四级传动,所述叶片轴102的转速大大低于所述驱动电机12的转速,因此大大提高了风机叶片安装角的调节精度。
能够理解的是,所述传动机构13可以是其它类型的传动结构,只要能将驱动电机12的转动转化为所述风机叶片安装角的改变,且符合一定的精度要求,均可用于本发明实施例。
进一步地,如图2和图5所示,所述风机叶片调节装置还包括反馈机构,与所述控制主机11连接,所述反馈机构包括编码器141,也就是角位移检测部件;
具体地,所述编码器141,配置为测量所述风机叶片101的安装角变动值,并将所述安装角变动值发送给所述控制主机11;所述编码器141的测量杆与所述叶片轴102连接,所述编码器141的测量杆随所述叶片轴102的转动而转动。
进一步地,所述反馈机构还包括将所述风机叶片安装角的变动值放大 后输入所述编码器141的测量值放大机构;
图6为图5中编码器141和测量值放大机构的结构示意图,如图6所示,图中包括编码器141和测量值放大机构,所述测量值放大机构包括相互啮合的主动齿轮142和从动齿轮143,所述主动齿轮142的齿数大于所述从动齿轮143的齿数;所述主动齿轮142与所述叶片轴102连接,所述主动齿轮142随所述叶片轴102的转动而转动;所述从动齿轮143与所述编码器141的测量杆连接,所述编码器141的测量杆随所述从动齿轮143的转动而转动;
从图6中可以看出,所述主动齿轮142的齿数远大于所述从动齿轮143的齿数,因此从动齿轮143的角速度是远大于所述主动齿轮142的角速度,也就是对风叶安装角的变动值进行了放大;
通过所述测量值放大机构,大大提高了所述反馈机构测量所述风机叶片101的安装角变动值的精度。
具体地,所述编码器141的测量杆可以通过联轴器144与所述从动齿轮143的轴连接;所述主动齿轮142的外圆周可以制作为外花键槽的形式,所述叶片轴102可以通过在轴上设置与所述外花键槽匹配的键与所述主动齿轮142连接。
能够理解的是,所述角位移检测部件,也可以是其它能检测所述风机叶片安装角角度变化的检测元器件,例如,所述角位移检测部件也可以是角度传感器。
如图2和图7所示,所述指令处理机构15分别连接所述控制主机11、驱动电机12和编码器141;所述指令处理机构15,还配置为:
根据所述编码器141的检测数据回复所述控制主机11;
这里,所述编码器141的检测数据为表示所述风机叶片安装角变动值的二进制数字;
所述指令处理机构15将表示所述风机叶片安装角变动值的二进制数字转换为脉冲信号回复所述控制主机11。
具体地,所述指令处理机构15包括指令处理部件151、主机指令回复部件152和主机指令接收部件153;所述主机指令回复部件152和主机指令接收部件153均固定在风筒外壁,且通过有线的方式与所述控制主机11通讯连接;所述主机指令回复部件152和主机指令接收部件153通过红外线(infrared ray)的方式与所述指令处理部件151通讯连接;
更具体地,所述指令处理部件151可以是单片机,所述主机指令回复部件152和主机指令接收部件153可以分别是红外线发射器和红外线接收器;
风机10工作时,所述指令处理部件151跟随所述风机叶轮转动,即所述风机叶轮在风机电机105的带动下转动,而所述指令处理部件151固定于所述风机叶轮,因此采用无线的方式与所述控制主机11通讯比较方便和可靠;
相比蓝牙(Bluetooth),使用红外线通讯具有成本低、速度快的特点,但是因为红外线只能直线传播,也就是只能点对点通讯,所以所述指令处理部件151设有光纤收发器154,所述光纤收发器154凸出所述风机叶轮端面,所述主机指令回复部件152和主机指令接收部件153安装在所述光纤收发器154对应的位置;
为了保护所述光纤收发器154,不影响红外线通讯,风叶叶轮端面设有透明的光纤收发器罩155;所述光纤收发器154凸出所述风机叶轮端面的部分为锥形,这样将能接收信号的光纤露出所述光纤保护皮;
具体地,所述光纤收发器罩155可以采用有机玻璃的材质制作;
能够理解的是,所述指令处理机构15也可以采用其它无线信号与所述控制主机11进行通讯,例如蓝牙、2.4G无线信号。
如图2和图8所示,所述风机叶片调节装置还包括向所述调节执行机构、反馈机构和指令处理机构供电的发电机构16,所述发电机构16包括定子161和转子162;所述定子161和转子162分别固定在风机电机105和风机叶轮相向的端面;
具体地,所述定子161朝向所述风机叶轮的端面设置有圆周方向均布的永磁块163,所述转子162设有与所述永磁块163对应的线圈164,所述线圈164和永磁块163在轴向间隔有预设的间隙;
所述定子161不随电机轴106的转动而转动,所述转子162随电机轴106的转动而转动,这样定子161和转子162产生相对转动;也就是线圈164会切割永磁块163的磁力线,产生感应电动势,对所述调节执行机构和反馈机构进行供电;
这里,所述线圈164和永磁块163在轴向间隔有预设的间隙,主要作用是避免定子161和转子162在转动中摩擦损耗,也就是电机的气隙,但是为了保证足够的磁通量,所述线圈164和永磁块163之间的间隙尽可能小。
具体地,所述永磁块163可以由钐钴(SmCo)材质制成;
能够理解的是,所述永磁块163也可以由其它材质制成,如钕铁硼(Nd2Fe14B)、铁氧体(Ferrite)等。
本发明实施例中,通过发电机构16对所述调节执行机构、反馈机构和指令处理机构15进行供电,既能节省能耗,也更安全和可靠,因为所述调节执行机构、反馈机构和指令处理机构15都固定在所述风机叶轮上,所述风机叶轮在风机10工作时是持续转动的,这样,通过导线从风机叶轮外部接入电能在结构上是比较困难的,也是比较容易损坏导线的。
进一步地,所述风机叶片调节装置还设有整流单元17,所述整流单元17配置为将所述发电机构16输出的交流电转换为直流电,输入所述指令处 理机构15;
具体地,所述指令处理机构还将获得的电能供调节执行机构和反馈机构使用。
实施例二
本发明实施例还提供了一种对旋风机,包括前后串联的两个直径、轮毂比、转速都相同且旋转方向相反的风机叶轮,每个所述风机叶轮均设有风机叶片调节装置;
所述风机叶片调节装置的组成结构、各组成部分之间的连接关系、以及各组成部分的功能原理均与实施例一中风机叶片调节装置的描述相同,不再赘述。
实施例三
图9为本发明实施例三风机叶片调节方法的流程示意图,如图9所示,所述方法包括:
步骤801:获取风机的实际出风量;
具体地,所述控制主机获取所述风机的实际出风量,具体可以是所述控制主机通过风量传感器获取。
步骤802:根据所述风机的实际出风量,指令与风机上一个以上风机叶片连接的调节执行机构对所述风机叶片的安装角进行调整。
具体地,所述根据所述风机的实际出风量,指令与风机上一个以上风机叶片连接的调节执行机构对所述风机叶片的安装角进行调整,包括:
根据所述风机的实际出风量和所述风机叶片安装角与所述风机出风量的预设对应关系,确定所述风机叶片的安装角调整值;
所述控制主机根据所述风机叶片的安装角调整值,指令所述调节执行机构对所述风机叶片的安装角进行调整。
这里,所述风机叶片安装角与所述风机出风量的预设对应关系可以是 一种变动趋势的关系,例如,当风机叶片安装角在X1°至X2°之间时,所述风机叶片安装角每增加或减少0.5°,风量就会增加或减少Y1每秒立方米;当风机叶片安装角在X3°至X4°之间时,所述风机叶片安装角每增加或减少0.5°,风量就会增加或减少Y2每秒立方米等;其中,所述风机叶片安装角的正方向为预设。
一般地,所述风机叶片安装角与所述风机出风量的对应关系是非线性的,上述将风机叶片安装角的变动范围细分后建立风机叶片安装角与风机出风量的对应关系是一种近似计算方法;
进一步地,为提高调节准确度,所述风机叶片安装角与所述风机出风量的对应关系可以通过建立包含多个变动因子的数学公式预置于控制主机;其中,具体的数学公式及变动因子的取值不是本发明的内容,不作介绍。
所述风机叶片安装角与所述风机出风量的对应关系可以是理论计算的结果,也可以是实际试验的结果,还可以是两者结合的结果;
所述控制主机根据所述风机叶片的安装角调整值,指令所述调节执行机构对风机叶片的安装角进行调整,包括:所述调节执行机构通过驱动电机和至少包括一级减速传动的传动机构实现对所述风机叶片的安装角的调整;
所述传动机构包括至少一级减速传动,是为了提高调节风机叶片安装角的精度。
在根据所述风机的实际出风量,指令所述调节执行机构对风机叶片的安装角进行调整之后,所述方法还包括:
所述控制主机获取反馈机构测量的所述风机叶片的安装角变动值,确定所述风机叶片的安装角调整误差值;
所述控制主机根据所述风机叶片的安装角调整误差值,重新确定所述 风机叶片的安装角调整值,并指令所述调节执行机构对所述风机叶片的安装角进行调整,直至所述风机叶片的安装角调整误差值符合预设阈值。
这样,通过反馈的方式,所述控制主机可以进一步控制调节风机叶片安装角的精确度;
具体地,反馈的过程中还需要指令处理机构将表示所述风机叶片安装角变动值的二进制数字转换为脉冲信号回复所述控制主机;
更具体地,所述指令处理机构通过红外线的方式与所述控制主机通讯。
进一步地,通过反馈的方式,将风机叶片安装角调整到预设的要求后,如果风量还是不满足要求,所述控制主机需要根据风机叶片安装角与风机出风量的对应关系确定新的风机叶片安装角,直至风机出风量满足要求。
调整完成后,所述控制主机记录风机叶片安装角和风机出风量的数据,以便以后可以对风机叶片安装角与风机出风量的预设对应关系进行修正。
以上所述,仅为本发明的较佳实施例而已,并非用于限定本发明的保护范围,凡在本发明的精神和原则之内所作的任何修改、等同替换和改进等,均应包含在本发明的保护范围之内。
工业实用性
本发明实施例由风机叶片调节装置,根据风机的实际出风量,及时对所述风机叶片的安装角进行调整,且调整通过驱动电机和至少包括一级减速传动的传动机构进行,不必使用结构复杂及体积大的液压系统,既能精确及时地调节风机叶片的安装角,也能实现远程自动化调节,且占用风筒空间小。

Claims (14)

  1. 一种风机叶片调节装置,与风机上的一个以上风机叶片连接,所述风机叶片调节装置包括控制主机和调节执行机构;其中,
    所述控制主机,配置为根据风机的实际出风量,指令所述调节执行机构对风机叶片的安装角进行调整;
    所述调节执行机构,配置为根据所述控制主机的指令,对所述风机叶片的安装角进行调整。
  2. 根据权利要求1所述的风机叶片调节装置,其中,所述调节执行机构包括驱动电机和至少包括一级减速传动的传动机构;所述驱动电机的输出轴连接所述传动机构的输入端;所述风机叶片朝向风机轴的一端设有叶片轴,所述风机叶片的安装角随所述叶片轴的转动而改变,所述传动机构的输出端连接所述叶片轴。
  3. 根据权利要求2所述的风机叶片调节装置,其中,所述传动机构包括相互啮合的第一圆锥齿轮和第二圆锥齿轮,所述第一圆锥齿轮随所述驱动电机的转动而转动;所述第一圆锥齿轮以所述风机轴的轴线为轴线相对于风机轴转动,并驱动所述第二圆锥齿轮转动;所述第二圆锥齿轮安装于所述叶片轴上,所述叶片轴随第二圆锥齿轮的转动而转动。
  4. 根据权利要求3所述的风机叶片调节装置,其中,所述传动机构还包括太阳齿轮、行星齿轮和行星架,所述太阳齿轮固定于所述风机轴,所述行星齿轮通过行星齿轮轴固定于所述行星架上,并围绕所述太阳齿轮公转;
    所述行星齿轮轴一端固定于所述行星齿轮,另一端从所述第一圆锥齿轮的轴向垂直固定于所述第一圆锥齿轮的端面,所述第一圆锥齿轮随所述行星齿轮的公转而转动;
    所述驱动电机的输出轴上设有相互连接的丝母和丝杆,所述丝杆固 定于所述驱动电机的输出轴,所述丝母随驱动电机的转动而直线移动;所述丝母铰接于所述行星架,所述行星架随所述丝母的直线移动而摆动,带动所述行星齿轮的公转。
  5. 根据权利要求2至4任一项所述的风机叶片调节装置,其中,所述风机叶片调节装置还包括反馈机构,与所述控制主机连接,所述反馈机构包括角位移检测部件;
    所述角位移检测部件,配置为测量所述风机叶片的安装角变动值,并将所述安装角变动值发送给所述控制主机;
    所述角位移检测部件的测量杆与所述叶片轴连接,所述角位移检测部件的测量杆随所述叶片轴的转动而转动。
  6. 根据权利要求5所述的风机叶片调节装置,其中,所述反馈机构还包括测量值放大机构,所述测量值放大机构包括相互啮合的主动齿轮和从动齿轮,所述主动齿轮的齿数大于所述从动齿轮的齿数;所述主动齿轮与所述叶片轴连接,所述主动齿轮随所述叶片轴的转动而转动;所述从动齿轮与所述角位移检测部件的测量杆连接,所述角位移检测部件的测量杆随所述从动齿轮的转动而转动。
  7. 根据权利要求5所述的风机叶片调节装置,其中,所述风机叶片调节装置还包括指令处理机构;
    所述指令处理机构,配置为根据所述控制主机调整所述风机叶片安装角的第一指令,发出指示所述调节执行机构执行的第二指令;
    所述指令处理机构,还配置为根据所述反馈机构的检测数据回复所述控制主机;
    所述指令处理机构分别连接所述控制主机、调节执行机构和反馈机构。
  8. 根据权利要求7所述的风机叶片调节装置,其中,所述指令处理 机构包括主机指令接收部件、指令处理部件和主机指令回复部件;所述主机指令接收部件和主机指令回复部件均固定在所述风机的风筒外壁,且通过有线的方式与所述控制主机通讯连接;所述主机指令接收部件和主机指令回复部件通过无线方式与所述指令处理部件通讯连接。
  9. 根据权利要求7所述的风机叶片调节装置,其中,所述风机叶片调节装置还包括向所述调节执行机构、反馈机构和指令处理机构供电的发电机构,所述发电机构包括定子和转子;所述定子和转子分别固定在风机电机和风机叶轮相向的端面。
  10. 根据权利要求9所述的风机叶片调节装置,其中,所述定子朝向所述风机叶轮的端面设置有圆周方向均布的永磁块,所述转子设有与所述永磁块对应的线圈,所述线圈和永磁块在轴向间隔有预设的间隙。
  11. 一种对旋风机,包括前后串联的两个直径、轮毂比、转速都相同且旋转方向相反的风机叶轮,每个所述风机叶轮均设有如权利要求1至10任一项所述的风机叶片调节装置。
  12. 一种风机叶片调节方法,所述方法包括:
    获取风机的实际出风量;
    根据所述风机的实际出风量,指令与风机上一个以上风机叶片连接的调节执行机构对所述风机叶片的安装角进行调整。
  13. 根据权利要求12所述的方法,其中,所述根据所述风机的实际出风量,指令与风机上一个以上风机叶片连接的调节执行机构对所述风机叶片的安装角进行调整,包括:
    根据所述风机的实际出风量和风机叶片安装角与风机出风量的预设对应关系,确定所述风机叶片的安装角调整值;
    根据所述风机叶片的安装角调整值,指令所述调节执行机构对所述风机叶片的安装角进行调整。
  14. 根据权利要求13所述的方法,其中,在指令与风机上一个以上风机叶片连接的调节执行机构对所述风机叶片的安装角进行调整之后,所述方法还包括:
    获取反馈机构测量的所述风机叶片的安装角变动值,确定所述风机叶片的安装角调整误差值;
    根据所述风机叶片的安装角调整误差值,重新确定所述风机叶片的安装角调整值,并指令所述调节执行机构对所述风机叶片的安装角进行调整,直至所述风机叶片的安装角调整误差值符合预设阈值。
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Publication number Priority date Publication date Assignee Title
CN110735813A (zh) * 2018-07-18 2020-01-31 北汽福田汽车股份有限公司 扇叶总成、风扇及其扇叶转角控制系统、方法和车辆
CN109237714B (zh) * 2018-09-21 2020-12-11 美的集团武汉制冷设备有限公司 空调器及其控制方法和存储介质
CN109209998A (zh) * 2018-10-23 2019-01-15 常州工学院 基于面齿轮传动的风机叶片角度调节系统、装置及风机
CN113049088A (zh) * 2019-12-26 2021-06-29 宁波奥克斯电气股份有限公司 一种空调喘振状态检测装置
CN113670620B (zh) * 2021-07-26 2022-06-17 南京航空航天大学 一种产生旋流畸变的新型装置

Citations (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US20120263593A1 (en) * 2009-12-18 2012-10-18 Flexxaire Inc. Variable pitch fan having a pitch sensor
CN103727062A (zh) * 2013-12-13 2014-04-16 湖北省风机厂有限公司 一种轴流风机动叶片调节装置
CN105041715A (zh) * 2015-08-05 2015-11-11 浙江理工大学 一种自动调节轴流风机叶片节距的机械装置
CN105673560A (zh) * 2016-03-04 2016-06-15 太原理工大学 对旋轴流式风机双级叶片调节机构

Family Cites Families (8)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
DE3910784A1 (de) * 1989-04-04 1990-10-18 Hans Schilder Umschlag-laufschaufel (180(grad))
CN1095525C (zh) * 2000-04-26 2002-12-04 三河市燕京新技术研究所 自动轴流通风机
CN2446315Y (zh) * 2000-09-27 2001-09-05 苏考文 矿用轴流式风机可调角度叶轮
KR100903050B1 (ko) * 2007-09-17 2009-06-18 (주)한서정공 방제기용 팬
CN201865932U (zh) * 2010-04-28 2011-06-15 洛阳沃能节电科技有限公司 矿井用可调角对旋轴流式节能风机
CN202560636U (zh) * 2012-02-29 2012-11-28 北京建筑工程学院 电控式动叶可调轴流风机
CN203453099U (zh) * 2013-05-28 2014-02-26 上海沃克通用设备有限公司 不停车调节叶片轴流风机
CN104847696B (zh) * 2015-05-04 2017-02-22 浙江理工大学 一种即时调节叶轮安装角的机械装置

Patent Citations (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US20120263593A1 (en) * 2009-12-18 2012-10-18 Flexxaire Inc. Variable pitch fan having a pitch sensor
CN103727062A (zh) * 2013-12-13 2014-04-16 湖北省风机厂有限公司 一种轴流风机动叶片调节装置
CN105041715A (zh) * 2015-08-05 2015-11-11 浙江理工大学 一种自动调节轴流风机叶片节距的机械装置
CN105673560A (zh) * 2016-03-04 2016-06-15 太原理工大学 对旋轴流式风机双级叶片调节机构

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