CN211234964U - Engine thrust measurement movable frame and thrust measurement rack thereof - Google Patents

Engine thrust measurement movable frame and thrust measurement rack thereof Download PDF

Info

Publication number
CN211234964U
CN211234964U CN201922038184.1U CN201922038184U CN211234964U CN 211234964 U CN211234964 U CN 211234964U CN 201922038184 U CN201922038184 U CN 201922038184U CN 211234964 U CN211234964 U CN 211234964U
Authority
CN
China
Prior art keywords
mounting seat
movable frame
force sensor
spring piece
engine
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Active
Application number
CN201922038184.1U
Other languages
Chinese (zh)
Inventor
王文彬
周皓
邱添
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Beijing Aerospace Sanfa High Tech Co Ltd
Original Assignee
Beijing Aerospace Sanfa High Tech Co Ltd
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Beijing Aerospace Sanfa High Tech Co Ltd filed Critical Beijing Aerospace Sanfa High Tech Co Ltd
Priority to CN201922038184.1U priority Critical patent/CN211234964U/en
Application granted granted Critical
Publication of CN211234964U publication Critical patent/CN211234964U/en
Active legal-status Critical Current
Anticipated expiration legal-status Critical

Links

Images

Landscapes

  • Testing Of Engines (AREA)

Abstract

An engine thrust measurement movable frame and a thrust measurement rack thereof comprise a movable frame body, a first movable frame spring leaf mounting seat, a movable frame working force sensor mounting seat, a second movable frame spring leaf mounting seat and a movable frame standard force sensor mounting seat; along the length direction of the movable frame, a movable frame standard force sensor mounting seat is fixedly mounted on the bottom surface of the front end of the movable frame body; the first movable frame spring piece mounting seat comprises 2 fixed mounting seats which are fixedly mounted on the bottom surface of the front end of the movable frame body and are respectively positioned on two sides of the movable frame standard force sensor mounting seat; the movable frame working force sensor mounting seat is fixedly mounted at the bottom of the movable frame body and is positioned on a central line along the length direction of the movable frame body; the second movable frame spring piece mounting seat comprises 2 spring pieces which are respectively fixedly mounted on the bottom surface of the rear end of the movable frame body. The utility model discloses an engine thrust measurement moves frame, the global rigidity is great, and in order to guarantee test frame dynamic behavior, the rational distribution atress component in the design adopts the strength principle such as structure, removes the optimization design such as the not atress part of material, alleviates and moves the frame quality.

Description

Engine thrust measurement movable frame and thrust measurement rack thereof
Technical Field
The utility model belongs to the technical field of the thrust measurement technique and specifically relates to an engine thrust measurement moves frame and measurement rack thereof.
Background
The engine test and test technology is an important component of the solid propulsion technology, and the thrust measurement is an important parameter to be measured in the engine test and test. To study engine thrust, numerous trial and error tests are required, which are not possible if all are put into flight tests. The main reasons are high flight test cost, long period, small information yield, risk and large manpower consumption. The engine ground test is to perform static test on the system according to specific conditions and environmental requirements on the ground to obtain various performance index information describing the system so as to solve the key problem in the engine thrust test process.
Disclosure of Invention
The technical solution problem of the utility model is that: the defects of the prior art are overcome, and the engine thrust measurement movable frame and the measurement rack thereof are provided.
The technical solution of the utility model is that: an engine thrust measurement movable frame comprises a movable frame body, a first movable frame spring piece mounting seat, a movable frame working force sensor mounting seat, a second movable frame spring piece mounting seat and a movable frame standard force sensor mounting seat; the movable frame standard force sensor mounting seat is fixedly mounted on the bottom surface of the front end of the movable frame body along the length direction of the movable frame body; the first movable frame spring piece mounting seat comprises 2 fixed mounting seats which are fixedly mounted on the bottom surface of the front end of the movable frame body and are respectively positioned on two sides of the movable frame standard force sensor mounting seat; the movable frame working force sensor mounting seat is fixedly mounted at the bottom of the movable frame body and is positioned on a central line along the length direction of the movable frame body; the second movable frame spring piece mounting seat comprises 2 spring pieces which are respectively fixedly mounted on the bottom surface of the rear end of the movable frame body.
Further, engine thrust measurement moves frame including being used for supporting the measurement section bracket of measurement section, the measurement section bracket includes the first measurement section bracket and the second measurement section bracket of coaxial setting, and equal fixed mounting is at the top surface of moving the frame support body.
Further, the engine thrust measuring movable frame comprises an engine mounting frame fixed on the top surface of the movable frame body, and the engine mounting frame comprises an engine mounting top frame, a left upright post and a right upright post which are identical in structure, a front joint and a rear joint; the bottom surfaces of the left upright post and the right upright post are detachably connected with the movable frame; the engine mounting top frame is fixedly connected with the top surfaces of the left upright post and the right upright post to form a gantry type, and the front joint and the rear joint are detachably mounted on the engine mounting top frame; and the engine mounting top frame is provided with mounting holes for mounting the front joint and the rear joint.
An engine thrust measuring rack comprising the engine thrust measuring movable rack comprises a fixed rack and a loading measuring device; the loading measuring device comprises a spring piece, a loading mechanism and a working force sensor; the movable frame is hung on the fixed frame through the spring piece, the loading mechanism is fixedly installed on the fixed frame, and two ends of the working force sensor are respectively connected with the fixed frame and the movable frame.
Further, the fixed frame comprises a base, a front mounting seat, a loading mechanism mounting seat, a first fixed frame spring piece mounting seat, a fixed frame working force sensor mounting seat, a rear mounting seat and a second fixed frame spring piece mounting seat; the base is of a cuboid structure, the front mounting seat and the rear mounting seat are fixedly mounted at the front end and the rear end of the base respectively along the length direction of the base, the rear mounting seat comprises a transverse plate and a vertical plate, and the transverse plate and the vertical plate form an L shape; the loading mechanism mounting seats are fixedly mounted on the front mounting seat, the number of the first fixing frame spring piece mounting seats is 2, and the first fixing frame spring piece mounting seats are fixedly mounted at the front end of the base and are respectively positioned on two sides of the front mounting seat; the fixed frame working force sensor mounting seat is fixedly arranged on the base and is positioned on a central line along the length direction of the base; the second fixed frame spring piece mounting seat comprises 2 spring pieces which are fixedly mounted at the rear end of the base and are respectively positioned on two sides of the rear mounting seat.
Furthermore, the loading measuring device comprises a first spring piece, a second spring piece, a loading mechanism, a standard force sensor and a working force sensor; the number of the first spring pieces is 2, each first spring piece is fixedly connected with a first fixed frame spring piece mounting seat and a first movable frame spring piece mounting seat, the number of the second spring pieces is 2, and two ends of each second spring piece are fixedly connected with a second fixed frame spring piece mounting seat and a second movable frame spring piece mounting seat respectively; the loading mechanism is fixedly arranged on a transverse plate of the front mounting seat, the standard force sensor is fixedly arranged on a baffle plate at the front end of the movable frame body, and the loading mechanism and the standard force sensor are coaxially arranged and are parallel to the central line of the base along the length direction; the two ends of the working force sensor are respectively and fixedly connected with the fixed frame working force sensor mounting seat and the movable frame working force sensor mounting seat, and the working force sensor, the loading mechanism and the standard force sensor are coaxially arranged.
Furthermore, the loading mechanism comprises a servo motor, a motor power supply, a hydraulic loading device and a calibration oil cylinder, wherein the motor power supply is electrically connected with the servo motor, the servo motor is sequentially connected with the hydraulic loading device and the calibration oil cylinder, and a piston of the calibration oil cylinder is connected with the standard force sensor.
Further, engine thrust measures rack includes locking device, and locking device includes tight set screw, tight set baffle and tight set nut, and tight set screw passes movable frame support body rear end baffle in proper order, tight set baffle, the riser and the tight set nut of back mount pad, tight set nut and the cooperation of tight set screw, tight set baffle and tight set nut all with the riser butt of back mount pad.
Furthermore, the engine thrust measurement rack comprises a force sensor calibration device, and the force sensor calibration device comprises an industrial personal computer, a display, a standard force sensor data acquisition device and a working force sensor data acquisition device; the industrial personal computer is respectively electrically connected with the display and the servo motor, the standard force sensor data acquisition device is respectively electrically connected with the standard force sensor and the industrial personal computer, and the working force sensor data acquisition device is respectively electrically connected with the working force sensor and the industrial personal computer.
Compared with the prior art, the utility model the advantage lie in:
1. the utility model discloses an engine thrust measurement moves frame, the global rigidity is great, and in order to guarantee test frame dynamic behavior, the rational distribution atress component in the design adopts the strength principle such as structure, removes the optimization design such as the not atress part of material, alleviates and moves the frame quality.
2. The utility model discloses an engine thrust measurement moves frame and measurement rack thereof has realized the measurement of engine thrust, simple structure.
3. The utility model discloses an engine thrust measurement moves frame and measurement rack thereof, ingenious will move the frame and hang on the fixed frame through the spring leaf to be aided with the thrust of force transducer measurement engine, simple and easy.
4. The utility model discloses an engine thrust measurement moves frame and measurement rack thereof sets up the measurement section bracket to it is coaxial with the engine to guarantee to be used for measuring the measurement section that is tried the engine air inlet parameter, has both guaranteed the engine precision of the simulation of admitting air, has improved the engine precision of parameter measurement of admitting air again.
5. The utility model discloses an engine thrust is measured and is moved frame and measurement rack thereof, its decide the frame and set up horizontal base, improve the load capacity of whole deciding the frame.
6. The utility model discloses an engine thrust measurement moves frame and measurement rack thereof sets up the lock state, when making the engine install the engine before not test condition or experiment, moves the frame and keeps the fixed state with the fixed frame, has prolonged the life of engine thrust measurement rack, avoids exerting irreversible external force and causing the damage even to the spring leaf when moving the frame and installing engine under the self-contained state (not using lock state) and relevant test piece simultaneously, has guaranteed the precision of engine thrust measurement rack.
7. The utility model discloses an engine thrust measures movable support and measures the rack thereof adopts planer-type engine mounting bracket, hangs the engine and sets up, has improved the measurement accuracy of engine thrust to it is adjustable to set up front connector and back joint position, has improved engine mounting bracket's application scope by a wide margin, has solved the problem that an engine set up an engine mounting bracket in the past.
8. The utility model discloses an engine thrust measurement moves frame and measurement rack thereof adopts standard force transducer to carry out the error determination of working force transducer to the working force transducer, and static calibration produces the known "simulation thrust" of a set of high accuracy and carries out the degree of definite to force measuring system from this, because it has reappeared the deformation and the atress condition of test condition, eliminated because the most system error that deformation, installation, temperature, restraint etc. that produce when experimental arouse to the thrust measurement uncertainty has been reduced.
9. The utility model discloses an engine thrust measurement moves frame and measurement rack thereof draws the characteristic curve graph of standard force sensor and working force sensor through demarcating, passes through the true value of the accurate definite force of characteristic curve graph with the power value of working force sensor output, has avoided the calibration of every test to the working force sensor, and is with low costs, efficient.
Drawings
Fig. 1 is a front view of an engine thrust measuring rack including the engine thrust measuring movable rack of the present invention.
Fig. 2 is an enlarged view of a portion a in fig. 1.
Fig. 3 is an enlarged view of a portion B in fig. 1.
Fig. 4 is the engine thrust that contains the utility model discloses an engine thrust measures rack structure top view of movable frame.
Fig. 5 is an enlarged view of the portion C of fig. 4.
Fig. 6 is the utility model discloses an in engine thrust measurement movable frame and the measurement rack thereof, the structural schematic of measurement section bracket.
Fig. 7 is an enlarged view of a portion D in fig. 6.
Fig. 8 is an enlarged view of a portion E of fig. 6.
Fig. 9 is a front view of the engine mounting rack in the engine thrust measuring movable rack and the measuring rack thereof of the present invention.
Fig. 10 is a side view of the engine mounting rack in the engine thrust measuring movable rack and the measuring rack thereof of the present invention.
Fig. 11 is the structure diagram of the engine thrust measuring moving frame and the measuring rack thereof, which are provided with the engine mounting top frame.
Fig. 12 is the schematic diagram of the calibration of the force sensor in the engine thrust measurement movable frame and the measurement rack thereof of the present invention.
Detailed Description
In the description of the present invention, it is to be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", "axial", "radial", "circumferential", and the like, indicate the orientation or positional relationship indicated based on the drawings, and are only for convenience of description and simplicity of description, and do not indicate or imply that the device or element referred to must have a particular orientation, be constructed and operated in a particular orientation, and therefore, should not be construed as limiting the present invention. Furthermore, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of the present invention, "a plurality" means two or more unless otherwise specified.
In the description of the present invention, it is to be noted that, unless otherwise explicitly specified or limited, the terms "mounted", "connected" and "abutted" are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in the present invention can be understood in specific cases to those skilled in the art.
An engine thrust measurement movable frame 200 comprises a movable frame body 210, a first movable frame spring leaf mounting seat 220, a movable frame working force sensor mounting seat 230, a second movable frame spring leaf mounting seat 240 and a movable frame standard force sensor mounting seat 250, wherein the movable frame body 210 comprises a right movable frame body 211, a left movable frame body 212 and a movable frame connecting plate 260, the right movable frame body 211 and the left movable frame body 212 have the same structure, are both cuboid structures and are both parallel to the base 110, the center lines of the right moving frame body 211 and the left moving frame body 212 in the length direction are parallel to the center line of the base 110 in the length direction, the right moving frame body 211 and the left moving frame body 212 are symmetrically disposed with respect to a center line of the base 110 in a length direction, the number of the movable frame connecting plates 260 is multiple, and the right movable frame body 211 and the left movable frame body 212 are fixedly connected by the plurality of movable frame connecting plates 260; along the length direction of the movable frame body 210, a movable frame standard force sensor mounting seat 250 is fixedly mounted on the bottom surface of the front end of the movable frame body 210; the first moving frame spring piece mounting seat 220 comprises a first right moving frame spring piece mounting seat and a first left moving frame spring piece mounting seat, and the first right moving frame spring piece mounting seat and the first left moving frame spring piece mounting seat are respectively fixedly mounted on the bottom surfaces of the front ends of the right moving frame body 211 and the left moving frame body 212 and are respectively positioned on two sides of the moving frame standard force sensor mounting seat 250; the movable frame working force sensor mounting base 230 is fixedly mounted at the bottom of one movable frame connecting plate 260 of the movable frame body 210 and is located on a central line along the length direction of the movable frame body 210; the second moving frame spring piece mounting seat 240 comprises a second right moving frame spring piece mounting seat and a second left moving frame spring piece mounting seat, and the second right moving frame spring piece mounting seat and the second left moving frame spring piece mounting seat are fixedly mounted on the bottom surfaces of the rear ends of the right moving frame body 211 and the left moving frame body 212 respectively.
The engine thrust measurement movable frame 200 comprises a measurement section bracket for supporting a measurement section, the measurement section bracket comprises a first measurement section bracket 410 and a second measurement section bracket 420 which are coaxially arranged, and the first measurement section bracket 410 and the second measurement section bracket 420 have the same structure and are both fixedly arranged on the top surface of the movable frame body 210; the measuring section bracket comprises a measuring section bracket 411, a measuring section bracket lower ring 412, a measuring section bracket upper ring 413, a measuring section bracket positioning mechanism 414 and a locking device 415; the bottom surface of the measurement section bracket 411 is fixedly connected with the top surface of the movable frame body 210, the measurement section bracket lower ring 412 and the measurement section bracket upper ring 413 are both of a semicircular structure, and the measurement section bracket lower ring 412 and the measurement section bracket upper ring 413 are connected to form a circle; the measuring section bracket lower ring 412 and the measuring section bracket 411 are integrally formed; the number of the measuring section bracket positioning mechanisms 414 is 3, the structures of the measuring section bracket positioning mechanisms are the same, and the measuring section bracket positioning mechanisms 414 are used for positioning and measuring the measuring sections of the intake parameters of the tested engine, the 3 measuring section bracket positioning mechanisms 414 are uniformly distributed along the radial direction of a circle formed by connecting the measuring section bracket lower ring 412 and the measuring section bracket upper ring 413, wherein one measuring section bracket positioning mechanism 414 is arranged at the top of the measuring section bracket upper ring 413, and the rest 2 measuring section bracket positioning mechanisms 414 are arranged on the measuring section bracket lower ring 412; the measuring section bracket positioning mechanism 414 comprises a positioning mechanism nut 4141, a positioning mechanism locking nut 4142 and a positioning mechanism screw 4143, the positioning mechanism screw 4143 passes through the measuring section bracket lower ring 412 or the measuring section bracket upper ring 413, the positioning mechanism locking nut 4142 is sleeved on the positioning mechanism screw 4143, is arranged on the outer side of the measuring section bracket lower ring 412 or the measuring section bracket upper ring 413 and is abutted against the measuring section bracket lower ring 412 or the measuring section bracket upper ring 413 and is used for locking the positioning mechanism screw 4143, and the positioning mechanism nut 4141 is sleeved on the positioning mechanism screw 4143 and is abutted against the positioning mechanism locking nut 4142; the number of the locking devices 415 is 2, and the structures of the locking devices are the same, and the locking devices 415 are used for fixedly connecting the lower ring 412 of the measurement section bracket and the upper ring 413 of the measurement section bracket, 2 locking devices 415 are arranged at the connecting ends of the lower ring 412 of the measurement section bracket and the upper ring 413 of the measurement section bracket, the locking device 415 includes an upper locking plate 4151, a lower locking plate 4152, a locking bolt 4153 and a locking nut 4154, the upper locking plate 4151 is fixedly attached to the front end surface of the upper ring 413 of the measurement section bracket, the lower surface of the upper locking plate 4151 coincides with the lower surface of the upper ring 413 of the measurement section bracket, the lower locking plate 4152 is fixedly attached to the front end surface of the measuring section bracket lower ring 412, the upper surface of the lower lock plate 4152 coincides with the upper surface of the measuring section bracket lower ring 412, the locking bolt 4153 passes through the lower and upper locking plates 4152 and 4151 in sequence, the lock nut 4154 is engaged with the lock bolt 4153 and abuts against the upper lock plate 4151.
The engine thrust measuring movable frame 200 comprises an engine mounting frame 600, wherein the engine mounting frame 600 comprises an engine mounting top frame 610, a left upright post 620 and a right upright post 630 which are identical in structure, a front joint 640, a rear joint 650 and a lifting lug 660; the bottom surfaces of the left upright post 620 and the right upright post 630 are detachably connected with the movable frame 200; the engine mounting top frame 610 is fixedly connected with the top surfaces of the left upright column 620 and the right upright column 630 to form a gantry type, the front joint 640 and the rear joint 650 are detachably mounted on the engine mounting top frame 610, and the lifting lug 660 is fixedly connected with the engine mounting top frame 610; the engine mounting top frame 610 comprises a front beam 611, a rear beam 612 and a longitudinal beam 613, wherein the front beam 611 and the rear beam 612 are arranged in parallel and are fixedly connected with the longitudinal beam 613, the rear beam 612 is fixedly connected with one end of the longitudinal beam 613, and the front beam 611, the rear beam 612 and the longitudinal beam 613 form a shape like the Chinese character 'tu'; the longitudinal beam 613 is provided with a mounting hole 614 for mounting a front joint 640 and a rear joint 650; the left upright post 620 comprises a front post 621, a rear post 622 and upright post connecting rods 623, wherein the front post 621 and the rear post 622 are arranged in parallel and are fixedly connected through the upright post connecting rods 623.
An engine thrust measuring rack comprising the engine thrust measuring movable rack comprises a fixed rack 100 and a loading measuring device; the loading measuring device comprises a spring piece, a loading mechanism 330 and a working force sensor 350; the movable frame 200 is suspended on the fixed frame 100 through the spring plate, the loading mechanism 330 is fixedly mounted on the fixed frame 100, and two ends of the working force sensor 350 are respectively connected with the fixed frame 100 and the movable frame 200.
The fixed frame comprises a base 110, a front mounting seat 120, a loading mechanism mounting seat 130, a first fixed frame spring piece mounting seat 140, a fixed frame working force sensor mounting seat 150, a rear mounting seat 160 and a second fixed frame spring piece mounting seat 170; the base 110 is of a cuboid structure, the front mounting seat 120 and the rear mounting seat 160 are respectively and fixedly mounted at the front end and the rear end of the base 110 along the length direction of the base 110, the rear mounting seat 160 comprises a transverse plate and a vertical plate, and the transverse plate and the vertical plate form an L shape; the loading mechanism mounting seat 130 is fixedly mounted on the front mounting seat 120, the first fixed frame spring leaf mounting seat 140 includes a first right fixed frame spring leaf mounting seat 141 and a first left fixed frame spring leaf mounting seat 142, and the first right fixed frame spring leaf mounting seat 141 and the first left fixed frame spring leaf mounting seat 142 are fixedly mounted at the front end of the base 110 and are respectively located on two sides of the front mounting seat 120; the fixed frame working force sensor mounting seat 150 is fixedly mounted on the base 110 and is positioned on a central line along the length direction of the base 110; the second fixed frame spring piece mounting seat 170 includes a second right fixed frame spring piece mounting seat 171 and a second left fixed frame spring piece mounting seat 172, and the second right fixed frame spring piece mounting seat 171 and the second left fixed frame spring piece mounting seat 172 are fixedly mounted at the rear end of the base 110 and respectively located at two sides of the rear mounting seat 160.
The loading measuring device comprises a first spring plate 310, a second spring plate 320, a loading mechanism 330, a standard force sensor 340 and a working force sensor 350; the first spring piece 310 comprises a first right spring piece 311 and a first left spring piece 312, two ends of the first right spring piece 311 are respectively and fixedly connected with a first right fixed frame spring piece mounting seat 141 and a first right movable frame spring piece mounting seat, and two ends of the first left spring piece 312 are respectively and fixedly connected with a first left fixed frame spring piece mounting seat 142 and a first left movable frame spring piece mounting seat; the second spring piece 320 comprises a second right spring piece 321 and a second left spring piece 322, two ends of the second right spring piece 321 are fixedly connected with the second right fixed frame spring piece mounting seat 171 and the second right movable frame spring piece mounting seat respectively, and two ends of the second left spring piece 322 are fixedly connected with the second left fixed frame spring piece mounting seat 172 and the second left movable frame spring piece mounting seat respectively; the loading mechanism 330 is fixedly mounted on a transverse plate of the front mounting seat 120, the standard force sensor 340 is fixedly mounted on a baffle plate at the front end of the movable frame body 210, and the loading mechanism 330 and the standard force sensor 340 are coaxially arranged and are parallel to the central line of the base 110 along the length direction; two ends of the working force sensor 350 are respectively and fixedly connected with the fixed frame working force sensor mounting seat 150 and the movable frame working force sensor mounting seat 230, and the working force sensor 350, the loading mechanism 330 and the standard force sensor 340 are coaxially arranged; the loading mechanism 330 comprises a servo motor, a motor power supply, a hydraulic loading device and a calibration oil cylinder, wherein the motor power supply is electrically connected with the servo motor, the servo motor is sequentially connected with the hydraulic loading device and the calibration oil cylinder, and a piston of the calibration oil cylinder is connected with a standard force sensor.
The engine thrust measuring rack comprises a locking device, the locking device comprises a fastening screw rod 510, a fastening baffle 520 and a fastening nut 530, the fastening screw rod 510 sequentially penetrates through a rear end baffle of the movable rack body 210, the fastening baffle 520, a vertical plate and a fastening nut 530 of the rear mounting seat 160, the fastening nut 530 is matched with the fastening screw rod 510, and the fastening baffle 520 and the fastening nut 530 are both abutted to the vertical plate of the rear mounting seat 160.
The engine thrust measurement rack comprises a force sensor calibration device, and the force sensor calibration device comprises an industrial personal computer, a display, a standard force sensor data acquisition device and a working force sensor data acquisition device; the industrial personal computer is respectively electrically connected with the display and the servo motor, the standard force sensor data acquisition device is respectively electrically connected with the standard force sensor and the industrial personal computer, and the working force sensor data acquisition device is respectively electrically connected with the working force sensor and the industrial personal computer.
A method of measuring thrust of a subject engine using the engine thrust measurement rig, comprising the steps of:
s100), installing the tested engine and measuring section
S110), sequentially enabling a measuring section for measuring engine air inlet parameters to pass through the first measuring section bracket 410 and the second measuring section bracket 420, and placing the measuring section in the first measuring section bracket 410 and the second measuring section bracket 420;
s120), mounting the front joint 640 and the rear joint 650 to the longitudinal beam 613 according to the suspension position of the engine under test;
s130), mounting the engine mounting frame 600 on the movable frame body 210, and then mounting the tested engine 1 on the front joint 640 and the rear joint 650;
s140) adjusting the measuring section, connecting one end of the measuring section with the air inlet of the tested engine, adjusting a positioning mechanism screw 4143 in the measuring section bracket positioning mechanism 414, enabling the measuring section and the air inlet of the engine to be coaxial, and then sequentially rotating a positioning mechanism locking nut 4142 and a positioning mechanism nut 4141 in the measuring section bracket positioning mechanism 414.
S200), disassembling and locking device
The fastening nut 530 is loosened, the fastening screw 510 is pulled out from the vertical plate of the rear mounting seat 160, the fastening baffle 520 and the baffle at the rear end of the movable frame body 210 in sequence, and then the fastening baffle 520 is taken out.
S300), determining the error of the working force sensor
S310), the industrial personal computer controls the servo motor to start to drive the hydraulic loading device to work, the hydraulic loading device drives the calibration oil cylinder to work, a piston of the calibration oil cylinder drives the standard force sensor 340 to displace so as to drive the movable frame body 210 to displace, and force is applied to the working force sensor 350 in the displacement process of the movable frame body 210;
s320), the hydraulic loading device drives the calibration oil cylinder to work, and the loading force is unloaded to a zero value after the loading force is continuously applied to the standard force sensor 340 to a preset value; the standard force sensor data acquisition device and the working force sensor data acquisition device respectively acquire force values output by the standard force sensor 340 and the working force sensor 350 in the loading force applying and unloading processes and feed back the force values to the industrial personal computer, and the display displays the force values output by the standard force sensor 340 and the working force sensor 350 in the loading force applying and unloading processes, which are acquired by the standard force sensor data acquisition device and the working force sensor data acquisition device;
s330), drawing characteristic curve graphs of the standard force sensor 340 and the working force sensor 350 according to force values output by the standard force sensor 340 and the working force sensor 350 in the process of applying loading force and unloading loading force, wherein the force values are displayed by a display and acquired by the standard force sensor data acquisition device and the working force sensor data acquisition device; under the same loading force, the difference between the force value output by the working force sensor 350 acquired by the working force sensor data acquisition device and the force value output by the standard force sensor 340 acquired by the standard force sensor data acquisition device is the working force sensor error.
S400), measuring thrust of tested engine
After the engine is ignited and the measurement section detects that the air inlet parameter of the tested engine reaches the working condition, the display displays the force value output by the working force sensor 350 and collected by the working force sensor data collection device.
In the description herein, references to the description of the term "one embodiment," "some embodiments," "an illustrative embodiment," "an example," "a specific example," or "some examples" or the like mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the present invention. In this specification, the schematic representations of the terms used above do not necessarily refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.
While embodiments of the present invention have been shown and described, it will be understood by those of ordinary skill in the art that: various changes, modifications, substitutions and alterations can be made to the embodiments without departing from the principles and spirit of the invention, the scope of which is defined by the claims and their equivalents.

Claims (9)

1. The engine thrust measurement movable frame is characterized by comprising a movable frame body, a first movable frame spring leaf mounting seat, a movable frame working force sensor mounting seat, a second movable frame spring leaf mounting seat and a movable frame standard force sensor mounting seat; the movable frame standard force sensor mounting seat is fixedly mounted on the bottom surface of the front end of the movable frame body along the length direction of the movable frame body; the first movable frame spring piece mounting seat comprises 2 fixed mounting seats which are fixedly mounted on the bottom surface of the front end of the movable frame body and are respectively positioned on two sides of the movable frame standard force sensor mounting seat; the movable frame working force sensor mounting seat is fixedly mounted at the bottom of the movable frame body and is positioned on a central line along the length direction of the movable frame body; the second movable frame spring piece mounting seat comprises 2 spring pieces which are respectively fixedly mounted on the bottom surface of the rear end of the movable frame body.
2. An engine thrust measurement turret for use according to claim 1, characterized in that: including being used for supporting the measurement section bracket of measurement section, the measurement section bracket includes the first measurement section bracket and the second measurement section bracket of coaxial setting, and equal fixed mounting is at the top surface of movable frame support body.
3. The engine thrust measuring moving frame according to claim 1, characterized in that: the engine mounting frame comprises an engine mounting top frame, a left upright post and a right upright post which are same in structure, a front joint and a rear joint; the bottom surfaces of the left upright post and the right upright post are detachably connected with the movable frame; the engine mounting top frame is fixedly connected with the top surfaces of the left upright post and the right upright post to form a gantry type, and the front joint and the rear joint are detachably mounted on the engine mounting top frame; and the engine mounting top frame is provided with mounting holes for mounting the front joint and the rear joint.
4. An engine thrust measuring rack comprising the engine thrust measuring movable rack of any one of claims 1 to 3, characterized by comprising a fixed rack and a load measuring device;
the loading measuring device comprises a spring piece, a loading mechanism and a working force sensor; the movable frame is hung on the fixed frame through the spring piece, the loading mechanism is fixedly installed on the fixed frame, and two ends of the working force sensor are respectively connected with the fixed frame and the movable frame.
5. The engine thrust measurement bench of claim 4, wherein: the fixed frame comprises a base, a front mounting seat, a loading mechanism mounting seat, a first fixed frame spring piece mounting seat, a fixed frame working force sensor mounting seat, a rear mounting seat and a second fixed frame spring piece mounting seat; the base is of a cuboid structure, the front mounting seat and the rear mounting seat are fixedly mounted at the front end and the rear end of the base respectively along the length direction of the base, the rear mounting seat comprises a transverse plate and a vertical plate, and the transverse plate and the vertical plate form an L shape; the loading mechanism mounting seats are fixedly mounted on the front mounting seat, the number of the first fixing frame spring piece mounting seats is 2, and the first fixing frame spring piece mounting seats are fixedly mounted at the front end of the base and are respectively positioned on two sides of the front mounting seat; the fixed frame working force sensor mounting seat is fixedly arranged on the base and is positioned on a central line along the length direction of the base; the second fixed frame spring piece mounting seat comprises 2 spring pieces which are fixedly mounted at the rear end of the base and are respectively positioned on two sides of the rear mounting seat.
6. The engine thrust measurement bench of claim 5, wherein: the loading measuring device comprises a first spring piece, a second spring piece, a loading mechanism, a standard force sensor and a working force sensor; the number of the first spring pieces is 2, each first spring piece is fixedly connected with a first fixed frame spring piece mounting seat and a first movable frame spring piece mounting seat, the number of the second spring pieces is 2, and two ends of each second spring piece are fixedly connected with a second fixed frame spring piece mounting seat and a second movable frame spring piece mounting seat respectively; the loading mechanism is fixedly arranged on a transverse plate of the front mounting seat, the standard force sensor is fixedly arranged on a baffle plate at the front end of the movable frame body, and the loading mechanism and the standard force sensor are coaxially arranged and are parallel to the central line of the base along the length direction; the two ends of the working force sensor are respectively and fixedly connected with the fixed frame working force sensor mounting seat and the movable frame working force sensor mounting seat, and the working force sensor, the loading mechanism and the standard force sensor are coaxially arranged.
7. The engine thrust measurement bench of claim 4, wherein: the loading mechanism comprises a servo motor, a motor power supply, a hydraulic loading device and a calibration oil cylinder, wherein the motor power supply is electrically connected with the servo motor, the servo motor is sequentially connected with the hydraulic loading device and the calibration oil cylinder, and a piston of the calibration oil cylinder is connected with a standard force sensor.
8. The engine thrust measurement bench of claim 4, wherein: including locking device, locking device includes tight set screw, tight set baffle and tight set nut, and tight set screw passes in proper order and moves a support body rear end baffle, tight set baffle, the riser and the tight set nut of back mount pad, tight set nut and the cooperation of tight set screw, tight set baffle and tight set nut all with the riser butt of back mount pad.
9. The engine thrust measurement bench of claim 4, wherein: the device comprises a force sensor calibration device, wherein the force sensor calibration device comprises an industrial personal computer, a display, a standard force sensor data acquisition device and a working force sensor data acquisition device; the industrial personal computer is respectively electrically connected with the display and the servo motor, the standard force sensor data acquisition device is respectively electrically connected with the standard force sensor and the industrial personal computer, and the working force sensor data acquisition device is respectively electrically connected with the working force sensor and the industrial personal computer.
CN201922038184.1U 2019-11-22 2019-11-22 Engine thrust measurement movable frame and thrust measurement rack thereof Active CN211234964U (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
CN201922038184.1U CN211234964U (en) 2019-11-22 2019-11-22 Engine thrust measurement movable frame and thrust measurement rack thereof

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
CN201922038184.1U CN211234964U (en) 2019-11-22 2019-11-22 Engine thrust measurement movable frame and thrust measurement rack thereof

Publications (1)

Publication Number Publication Date
CN211234964U true CN211234964U (en) 2020-08-11

Family

ID=71932805

Family Applications (1)

Application Number Title Priority Date Filing Date
CN201922038184.1U Active CN211234964U (en) 2019-11-22 2019-11-22 Engine thrust measurement movable frame and thrust measurement rack thereof

Country Status (1)

Country Link
CN (1) CN211234964U (en)

Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN110763467A (en) * 2019-11-22 2020-02-07 北京航天三发高科技有限公司 Engine thrust measurement movable frame and thrust measurement rack thereof

Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN110763467A (en) * 2019-11-22 2020-02-07 北京航天三发高科技有限公司 Engine thrust measurement movable frame and thrust measurement rack thereof

Similar Documents

Publication Publication Date Title
CN210802905U (en) Engine test bed thrust measuring device
CN110763397A (en) Calibration method and device for engine test bed thrust measurement sensor
CN109141905B (en) Six-component force test bed and method for measuring vector thrust thereof
US20190033157A1 (en) Device for measuring and adjusting inertia of test model of offshore structure and method for using the same
CN110763469A (en) Engine test bed thrust measurement decides frame and thrust measurement rack thereof
CN210802906U (en) Engine test bed thrust measurement decides frame and thrust measurement rack thereof
CN210802907U (en) Engine test thrust measuring device
CN210802751U (en) Air inlet thrust measuring device of engine test bed
CN109115510B (en) Six-component force test bed and error determination method thereof
CN205002959U (en) Measuring instrument of axial clearance of bearing
CN110595685A (en) Contrast type six-dimensional force sensor calibration device and calibration method
CN110702293A (en) Supersonic engine test bed air inlet thrust measuring device and using method
CN104390772A (en) Device and method for testing static and dynamic variable friction of telescopic mechanism
CN110702292B (en) Engine test bed air inlet thrust measuring device and using method
CN211234964U (en) Engine thrust measurement movable frame and thrust measurement rack thereof
CN210603720U (en) Contrast type calibration device for six-dimensional force sensor
CN211234963U (en) Engine test bed thrust measurement mounting bracket and thrust measurement rack thereof
CN110726504A (en) Engine test bed air inlet thrust measuring device and using method thereof
CN111366988A (en) Component type drilling strain gauge complete machine detection platform controlled by six degrees of freedom
CN210802752U (en) Supersonic engine test bench air inlet thrust measuring device
CN109115513B (en) Method for determining natural frequency of moving frame of six-component test bed
CN210802909U (en) Engine thrust measuring rack
CN210802908U (en) Engine test bed thrust measurement hanging bracket and mounting rack thereof
CN211669390U (en) Component type drilling strain gauge complete machine detection platform controlled by six degrees of freedom
CN110749446A (en) Engine test bed thrust measurement mounting bracket and thrust measurement rack thereof

Legal Events

Date Code Title Description
GR01 Patent grant
GR01 Patent grant