CN116399213A - Multifunctional batch test equipment for testing linear displacement sensor - Google Patents

Abstract

The invention discloses multifunctional batch testing equipment for testing a linear displacement sensor, which comprises a sensor clamping driving mechanism and a high-low temperature box, wherein the sensor clamping driving mechanism comprises a base, a clamping mounting bracket, a clamping pressure rod, an inclined transmission rod, a vertical transmission rod, a transverse transmission rod, an adjusting bolt, a driving motor, a driving plate, a driving screw and a guide rod, one or more sensor clamping driving mechanisms are arranged in a testing inner cavity of the high-low temperature box, a controller is arranged on the outer wall of the high-low temperature box, and the control input end of the driving motor of one or more sensor clamping driving mechanisms is correspondingly connected with the control output end of the controller through a wire. The invention realizes the multifunctional purpose of being compatible with various conventional linear displacement sensors at present, has strong universality, can finish batch test work of a plurality of linear displacement sensors at one time, and can meet the application requirements of high-low temperature environment test through the high-low temperature adjusting function in the high-low temperature box.

Description

Multifunctional batch test equipment for testing linear displacement sensor

Technical Field

The invention belongs to the technical field of sensor testing, in particular to linear displacement sensor testing equipment, and more particularly relates to multifunctional batch testing equipment for testing linear displacement sensors.

Background

The linear displacement sensor is a sensor for converting linear mechanical displacement into an electric signal so as to realize a linear displacement detection function, and is widely applied to complete machine systems of ships, aviation, aerospace, weapons, ships and the like. The common linear displacement sensor comprises a push rod type linear displacement sensor, a pull rod type linear displacement sensor, a rope drawing type linear displacement sensor and a sliding handle type linear displacement sensor.

The linear displacement sensor generally needs to carry out testing processes such as detection precision testing or sliding life sampling testing before delivery, the linear displacement sensor needs to be clamped before testing, a driving component of the linear displacement sensor needs to be driven in the testing process, an output signal of the linear displacement sensor is detected, and the testing purpose is achieved by combining parameters such as a detection result, reciprocation times and the like.

The traditional clamping driving equipment for testing the linear displacement sensor aims at a type of linear displacement sensor, is single in structure and function and poor in universality, can only complete testing operation of one sensor at a time generally, is low in efficiency, and meanwhile, the traditional testing environment is a normal-temperature environment and cannot meet application requirements of high-low-temperature environment testing.

Disclosure of Invention

The invention aims to solve the problems and provide a multifunctional batch test device for testing linear displacement sensors, which has strong universality and can realize batch test in a high-low temperature environment.

The invention realizes the above purpose through the following technical scheme:

the utility model provides a linear displacement sensor test is with multi-functional batch test equipment, includes sensor clamping driving mechanism, still includes high low temperature box, sensor clamping driving mechanism includes base, clamping mounting bracket, clamping depression bar, slant transfer line, vertical transfer line, horizontal transfer line, adjusting bolt, driving motor, drive plate, drive screw and guide bar, the first end in the base both ends is equipped with one or more vertical overlapping arranged's horizontal mounting panel, and a plurality of clamping mounting bracket installs respectively on the base and be located the top of mounting panel, a plurality of clamping depression bar's middle section respectively with a plurality of clamping mounting bracket swivelling joint, a plurality of clamping depression bar's one end respectively with a plurality of slant transfer line's one end swivelling joint, a plurality of slant transfer line's the other end respectively with a plurality of vertical transfer line's upper end swivelling joint, a plurality of vertical transfer line's lower extreme respectively pass corresponding through-hole on the mounting panel, a plurality of horizontal transfer line's one end respectively with a plurality of vertical transfer line's mounting panel are installed respectively on the base and are located the top the mounting panel and are located the top of mounting panel the mounting panel, a plurality of vertical transfer line's the middle section respectively with a plurality of vertical transfer line's the vertical transfer line is installed the second end respectively the screw is located the second end is connected with the corresponding screw of the base under the other end of the screw bolt, the end is located the side of the base is connected with the other end of the screw bolt is located down the side of the base is corresponding bolt is connected down to the side of the screw bolt, two ends of the two guide rods which are transverse and parallel to each other are respectively connected with two ends of the base and are respectively positioned at two sides of the driving screw rod, a transverse screw hole is formed in the vertical driving plate and sleeved on the driving screw rod through the transverse screw hole, and transverse guide holes are respectively formed in positions, positioned at two sides of the transverse screw hole, of the driving plate and sleeved on the two guide rods through the two transverse guide holes; one or more sensor clamping driving mechanisms are arranged in the testing inner cavity of the high-low temperature box, a controller is arranged on the outer wall of the high-low temperature box, the control input ends of the driving motors of the one or more sensor clamping driving mechanisms are correspondingly connected with the control output ends of the controller through wires, and the wires penetrate through corresponding wire through holes on the wall of the high-low temperature box.

Preferably, in order to facilitate reliable clamping operation, the clamping pressure rod is an L-shaped rod, the middle section corner position of the clamping pressure rod is in rotary connection with the corresponding clamping mounting bracket, one end of the clamping pressure rod is in rotary connection with one end of the corresponding oblique transmission rod, and the other end of the clamping pressure rod is provided with a pressure rod handle.

Preferably, in order to realize batch test and be convenient for centre gripping and drive operation, the mounting panel is two, the driving plate includes the fixed driving plate of lower part, the regulation driving plate in middle part and the driving plate clamp plate on upper portion, horizontal screw with horizontal guiding hole all locates on the fixed driving plate, the upper end of fixed driving plate with the lower extreme of regulation driving plate contacts each other and is located the lower part the oblique top of mounting panel, the upper end of regulation driving plate with the lower extreme of driving plate clamp plate contacts each other and is located the upper portion the oblique top of mounting panel, the upper end terminal surface of fixed driving plate the upper end terminal surface of regulation driving plate the lower extreme terminal surface of driving plate clamp plate is equipped with a plurality of semi-circular centre gripping grooves that correspond each other respectively, and relative two semi-circular centre gripping grooves are enclosed into a circular centre gripping through-hole, a plurality of circular centre gripping through-hole and a plurality of adjusting bolt one-to-one, one or more lower extreme that connect from top to bottom passes in proper order on the driving plate clamp plate's the lower extreme contact each other and be located the upper end of driving plate clamp plate through-hole, the corresponding screw on the driving plate clamp plate and the upper end face of the upper end of driving plate clamp plate.

Preferably, in order to meet the installation requirement of more sensor structures, a plurality of strip-shaped installation grooves are formed in the installation plate.

Preferably, in order to facilitate rapid operation of the adjusting bolt, a butterfly handle is arranged at the upper end of the adjusting bolt.

Preferably, for easy assembly, the second end of the base is connected to a base end plate by a screw, and one end of the two guide rods is connected to the base end plate.

Preferably, in order to facilitate reliable connection with the sliding handle of the sliding handle type linear displacement sensor, the multifunctional batch testing device for testing the linear displacement sensor further comprises a plurality of connecting rods, one ends of the connecting rods are provided with connecting rod convex rings protruding towards the peripheral direction and used for being connected with the driving plate, and the other ends of the connecting rods are provided with connecting columns used for being connected with the sliding handle of the sliding handle type linear displacement sensor.

The invention has the beneficial effects that:

according to the invention, the clamping and driving structures of the linear displacement sensors are integrated on the same base, the rubber pads at the lower ends of the adjusting bolts can be used for realizing the clamping function on the shells of the linear displacement sensors of different types, the vertical transmission rod, the horizontal transmission rod and the adjusting bolts can be driven to synchronously move downwards by the rotation operation of the clamping pressure rods, so that the synchronous clamping function on the linear displacement sensors is realized, the driving plate is driven to transversely move by the driving motor, the synchronous driving control function on the linear displacement sensors is realized, the multifunctional purpose of being compatible with the conventional linear displacement sensors of various types at present is finally realized, the universality is strong, the batch test work of the linear displacement sensors can be finished at one time, and the application requirements of high-low temperature environment test can be met by the high-low temperature adjusting function in the high-low temperature box.

Drawings

FIG. 1 is a schematic perspective view of a multifunctional batch test device for testing linear displacement sensors according to the present invention;

FIG. 2 is a schematic diagram of a three-dimensional structure of a clamping mounting bracket, a clamping compression bar, an oblique transmission rod, a vertical transmission rod, a transverse transmission rod and an adjusting bolt of the multifunctional batch testing device for testing the linear displacement sensor;

FIG. 3 is a schematic perspective view of a sensor clamping driving mechanism of the multifunctional batch test equipment for testing linear displacement sensors;

fig. 4 is a schematic perspective view of a connecting rod of the multifunctional batch test device for testing linear displacement sensors.

In the figure, the box comprises a box door 1, a high-low temperature box 2, a testing cavity 3, a sensor clamping driving mechanism 4, a controller 5, a display screen 6, a wire through hole 7, a wire 8, a press lever handle 9, a clamping press lever 10, a clamping mounting bracket 11, a diagonal transmission rod 12, a vertical transmission rod 13, a transverse transmission rod 14, an adjusting bolt 15, a rubber pad 16, a base 17, a mounting groove 18, a mounting plate 19, a connecting screw 20, a driving plate pressing plate 21, a semicircular clamping groove 22, a regulating driving plate 23, a fixed driving plate 24, a guide rod 25, a driving screw 26, a driving motor 27, a base end plate 28, a connecting rod convex ring 29, a connecting rod 30 and a connecting column 31.

Detailed Description

The invention is further described below with reference to the accompanying drawings:

as shown in fig. 1-4, the multifunctional batch test equipment for testing linear displacement sensors of the invention comprises a sensor clamping driving mechanism 4 and a high-low temperature box 2, wherein the sensor clamping driving mechanism 4 comprises a base 17, a clamping mounting bracket 11, a clamping pressure rod 10, an inclined transmission rod 12, a vertical transmission rod 13, a transverse transmission rod 14, an adjusting bolt 15, a driving motor 27, a driving plate, a driving screw 26 and a guide rod 25, one or more (two in the figure) transverse mounting plates 19 which are vertically overlapped are arranged at the first ends of the two ends of the base 17, a plurality of clamping mounting brackets 11 are respectively arranged on the base 17 and are positioned above the mounting plates 19, the middle sections of the clamping pressure rods 10 are respectively and rotatably connected with the clamping mounting brackets 11, one ends of the clamping pressure rods 10 are respectively and rotatably connected with one ends of the inclined transmission rods 12, the other ends of the plurality of oblique transmission rods 12 are respectively and rotatably connected with the upper ends of the plurality of vertical transmission rods 13, the lower ends of the plurality of vertical transmission rods 13 respectively pass through corresponding through holes on the mounting plates 19, one ends of the plurality of transverse transmission rods 14 above each mounting plate 19 are respectively connected with the plurality of vertical transmission rods 13, the lower ends of the plurality of vertical adjusting bolts 15 respectively pass through vertical screw holes at the other ends of the plurality of transverse transmission rods 14 and are in threaded connection, the lower ends of each adjusting bolt 15 are respectively provided with a rubber pad 16 and are positioned above the corresponding mounting plate 19, a driving motor 27 is arranged in the middle part of the second end of the two ends of the base 17, one end of a transverse driving screw 26 is connected with a rotating shaft of the driving motor 27, the other end of the driving screw 26 is connected with the first end of the base 17 through a bearing and is positioned below the lowermost mounting plate 19, two ends of two transverse and parallel guide rods 25 are respectively connected with two ends of the base 17 and are respectively positioned at two sides of the driving screw 26, a transverse screw hole (not marked in the figure) is arranged on the vertical driving plate and sleeved on the driving screw 26 through the transverse screw hole, and transverse guide holes (not marked in the figure) are respectively arranged at positions on two sides of the transverse screw hole on the driving plate and sleeved on the two guide rods 25 through the two transverse guide holes; one or more sensor clamping driving mechanisms 4 are arranged in the test inner cavity 3 of the high-low temperature box 2, a controller 5 is arranged on the outer wall of the high-low temperature box 2, and the control input ends of one or more (one or more in the figure) driving motors 27 of the sensor clamping driving mechanisms 4 are correspondingly connected with the control output ends of the controller 5 through wires 8, and the wires 8 penetrate through corresponding wire through holes 7 on the wall of the high-low temperature box 2.

As shown in fig. 1-4, the present invention also discloses a number of more optimal specific structures:

in order to facilitate reliable clamping operation, the clamping pressure lever 10 is an L-shaped lever, the middle corner position of the clamping pressure lever 10 is rotationally connected with the corresponding clamping mounting bracket 11, one end of the clamping pressure lever 10 is rotationally connected with one end of the corresponding oblique transmission lever 12, and the other end of the clamping pressure lever 10 is provided with a pressure lever handle 9.

In order to realize batch test and facilitate clamping and driving operation, the two mounting plates 19 are provided, the driving plates comprise a fixed driving plate 24 at the lower part, an adjusting driving plate 23 at the middle part and a driving plate pressing plate 21 at the upper part, the transverse screw holes and the transverse guide holes are all arranged on the fixed driving plate 24, the upper ends of the fixed driving plate 24 and the lower ends of the adjusting driving plate 23 are mutually contacted and positioned obliquely above the mounting plate 19 at the lower part, the upper ends of the adjusting driving plate 23 and the lower ends of the driving plate pressing plate 21 are mutually contacted and positioned obliquely above the mounting plate 19 at the upper part, a plurality of semicircular clamping grooves 22 which are mutually corresponding are respectively arranged at the upper end face of the fixed driving plate 24, the upper end face and the lower end face of the adjusting driving plate 23 and the lower end face of the driving plate pressing plate 21 are encircled into a circular clamping through hole, the circular clamping through holes are in one-to-one correspondence with the plurality of adjusting bolts 15, and the lower ends of one or more connecting screws 20 sequentially penetrate through corresponding through holes in the driving plate 21 from top to bottom and are correspondingly connected with the corresponding driving plate 24 on the opposite pressing plate 21.

To accommodate the mounting requirements of more types of sensor structures, a plurality of strip-shaped mounting slots 18 are provided in the mounting plate 19.

In order to facilitate the quick operation of the adjusting bolt 15, the upper end of the adjusting bolt 15 is provided with a butterfly handle (not marked in the figure).

For ease of assembly, the second end of the base 17 is connected to a base end plate 28 by screws, and one end of the two guide rods 25 is connected to the base end plate 28.

In order to facilitate reliable connection with the sliding handle of the sliding handle type linear displacement sensor, the multifunctional batch test device for testing the linear displacement sensor further comprises a plurality of connecting rods 30, one ends of the connecting rods 30 are provided with connecting rod convex rings 29 protruding towards the peripheral direction and used for being connected with the driving plate, and the other ends of the connecting rods 30 are provided with connecting columns 31 used for being connected with the sliding handle of the sliding handle type linear displacement sensor.

Also shown in fig. 1 are a door 1 of the high-low temperature chamber 2 and a display screen 6 provided on the outer wall of the high-low temperature chamber 2, which are both of conventional construction. A wire groove (not shown) is provided on the bottom surface of the base 17, and leads of a plurality of linear displacement sensors (not shown) mounted on the mounting plate 19 are led out and connected to the controller 5 together with the wires 8.

As shown in fig. 1 to 4, when in use, a plurality of linear displacement sensors are firstly installed on the sensor clamping driving mechanism 4, and the specific method is as follows: the pressing rod handle 9 is lifted upwards firstly, the pressing rod handle 9 drives the corresponding inclined transmission rod 12 to move upwards and rotate along with the inclined transmission rod, the corresponding vertical transmission rod 13 and the corresponding transverse transmission rod 14 are driven to move upwards, the corresponding adjusting bolt 15 moves upwards, the distance between the rubber pad 16 at the lower end of the adjusting bolt and the corresponding mounting plate 19 is increased, the linear displacement sensor is conveniently placed on the mounting plate 19 and located right below the rubber pad 16 at the lower end of the corresponding adjusting bolt 15, then the pressing rod handle 9 is pressed downwards until the pressing rod handle is driven to move downwards and rotate along with the corresponding inclined transmission rod 12 to a vertical position, the inclined transmission rod 12 drives the corresponding vertical transmission rod 13, the transverse transmission rod 14 and the adjusting bolt 15 to move downwards to a limit position, the rubber pad 16 at the lower end of the adjusting bolt 15 just presses the corresponding linear displacement sensor shell, and the friction force between the rubber pad 16 and the linear displacement sensor shell can be utilized to enable the linear displacement sensor to be kept motionless and not damage the linear displacement sensor shell when being driven, namely the linear displacement sensor is clamped and fixed.

After a plurality of linear displacement sensors are installed according to the method, driving pieces of the linear displacement sensors are correspondingly connected with the driving plates, and the specific method is as follows: if the sensor is a push rod type linear displacement sensor, the push rod is not required to be connected, or the end part of the push rod passes through the corresponding circular clamping through hole; if the sensor is a pull rod type linear displacement sensor, the end part of the pull rod passes through the corresponding circular clamping through hole; if the sensor is a rope-drawing type linear displacement sensor, the end part of the rope-drawing type linear displacement sensor passes through the corresponding circular clamping through hole; if the sensor is a sliding handle type linear displacement sensor, connecting the sliding handle with a connecting column of the connecting rod 30, and enabling the connecting rod 30 to pass through a corresponding circular clamping through hole; after the driving parts of all the linear displacement sensors pass through the corresponding circular clamping through holes, the connecting screw 20 is locked, and the connection work of the driving parts of all the linear displacement sensors is completed.

Then, the sensor clamping driving mechanism 4 with the installed linear displacement sensors is placed in the testing inner cavity 3 of the high-low temperature box 2, the leads of the linear displacement sensors (not shown in the figure) and the leads 8 of the driving motor 27 are correspondingly connected with the controller 5 after passing through the lead through holes 7, the box door 1 is closed, the temperature in the high-low temperature box 2 is regulated according to testing requirements, the power supply of the linear displacement sensors can be communicated, the driving motor 27 is started to drive the driving screw 26 to rotate, the fixed driving plate 24 moves linearly under the action of the screw thread matching of the driving screw 26, the driving pieces of the linear displacement sensors are driven to synchronously move linearly, the linear displacement sensors output corresponding electric signals, and the controller 5 completes related testing work according to the detected electric signals or according to control signals to the driving motor 27.

The above embodiments are only preferred embodiments of the present invention, and are not limiting to the technical solutions of the present invention, and any technical solution that can be implemented on the basis of the above embodiments without inventive effort should be considered as falling within the scope of protection of the patent claims of the present invention.

Claims (7)

1. The utility model provides a linear displacement sensor test is with multi-functional batch test equipment, includes sensor clamping driving mechanism, its characterized in that: the sensor clamping driving mechanism comprises a base, a clamping mounting bracket, a clamping pressure rod, an inclined driving rod, a vertical driving rod, a transverse driving rod, an adjusting bolt, a driving motor, a driving plate, a driving screw and a guide rod, wherein one or more transverse mounting plates which are vertically overlapped are arranged at the first ends of the two ends of the base, the clamping mounting bracket is respectively arranged on the base and positioned above the mounting plate, the middle sections of the clamping pressure rods are respectively and rotatably connected with the clamping mounting bracket, one ends of the clamping pressure rods are respectively and rotatably connected with one ends of the inclined driving rods, the other ends of the inclined driving rods are respectively and rotatably connected with the upper ends of the vertical driving rods, the lower ends of the vertical driving rods respectively pass through corresponding through holes on the mounting plate, one ends of the transverse driving rods above each mounting plate are respectively connected with the vertical driving rods, the lower ends of the adjusting bolts respectively pass through corresponding screw bolts of the two ends of the two screws of the two shafts which are respectively arranged at the two ends of the two sides of the base, the two ends of the driving screw are respectively connected with the two screw bolts which are arranged at the two sides of the base in parallel, the vertical driving plate is provided with a transverse screw hole and sleeved on the driving screw rod through the transverse screw hole, and the positions of the driving plate, which are positioned at two sides of the transverse screw hole, are respectively provided with a transverse guide hole and sleeved on the two guide rods through the two transverse guide holes; one or more sensor clamping driving mechanisms are arranged in the testing inner cavity of the high-low temperature box, a controller is arranged on the outer wall of the high-low temperature box, the control input ends of the driving motors of the one or more sensor clamping driving mechanisms are correspondingly connected with the control output ends of the controller through wires, and the wires penetrate through corresponding wire through holes on the wall of the high-low temperature box.

2. The multi-functional batch test apparatus for linear displacement sensor testing of claim 1, wherein: the clamping pressure rod is an L-shaped rod, the corner position of the middle section of the clamping pressure rod is in rotary connection with the corresponding clamping mounting bracket, one end of the clamping pressure rod is in rotary connection with one end of the corresponding oblique transmission rod, and the other end of the clamping pressure rod is provided with a pressure rod handle.

3. The multi-functional batch test apparatus for linear displacement sensor testing of claim 1, wherein: the mounting plate is two, the driving plate includes the fixed driving plate of lower part, the regulation driving plate in middle part and the driving plate clamp plate on upper portion, horizontal screw with horizontal guiding hole all locates on the fixed driving plate, the upper end of fixed driving plate with the lower extreme of regulation driving plate contacts each other and is located the lower part the oblique top of mounting plate, the upper end of regulation driving plate with the lower extreme of driving plate clamp plate contacts each other and is located the upper portion the oblique top of mounting plate, the upper end terminal surface of fixed driving plate the upper and lower end terminal surface of regulation driving plate the lower extreme terminal surface of driving plate clamp plate is equipped with a plurality of semicircular clamping grooves that correspond each other respectively, and two relative semicircular clamping grooves surround into a circular centre gripping through-hole, a plurality of circular centre gripping through-hole and a plurality of adjusting bolt one-to-one, the lower extreme of one or more connecting screw passes in proper order on the driving plate the corresponding through-hole on the adjusting plate clamp plate the corresponding through-hole with on the fixed driving plate behind the last pair of through-hole.

4. A multi-functional batch test apparatus for testing linear displacement sensors according to claim 1, 2 or 3, characterized in that: a plurality of strip-shaped mounting grooves are formed in the mounting plate.

5. A multi-functional batch test apparatus for testing linear displacement sensors according to claim 1, 2 or 3, characterized in that: the upper end of the adjusting bolt is provided with a butterfly handle.

6. A multi-functional batch test apparatus for testing linear displacement sensors according to claim 1, 2 or 3, characterized in that: the second end of the base is connected with a base end plate through a screw, and one end of each guide rod is connected with the base end plate.

7. A multi-functional batch test apparatus for testing linear displacement sensors according to claim 1, 2 or 3, characterized in that: the multifunctional batch test equipment for testing the linear displacement sensor further comprises a plurality of connecting rods, wherein one ends of the connecting rods are provided with connecting rod convex rings protruding towards the peripheral direction and used for being connected with the driving plate, and the other ends of the connecting rods are provided with connecting columns used for being connected with sliding handles of the sliding handle type linear displacement sensor.

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