CN211205361U - In-situ test probe calibration detection device - Google Patents
In-situ test probe calibration detection device Download PDFInfo
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- CN211205361U CN211205361U CN202020060925.6U CN202020060925U CN211205361U CN 211205361 U CN211205361 U CN 211205361U CN 202020060925 U CN202020060925 U CN 202020060925U CN 211205361 U CN211205361 U CN 211205361U
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Abstract
The utility model belongs to normal position test probe field, especially a detection device is markd to normal position test probe is not convenient for carry the use to current detection device, and the user state is not convenient for adjust, occupies the problem of using the volume, now proposes following scheme, and it includes the base, the top fixed mounting of base has the fixing base, and the spread groove has been seted up at the top of fixing base, and the rotor plate is installed to the spread groove internal rotation, and the fixed slot has been seted up to one side of rotor plate, and slidable mounting has the movable plate in the fixed slot, and one side fixed mounting of movable plate has the mount pad, the mounting groove has been seted up to one side of mount pad, and movable mounting has the probe in the mounting groove, all sets up flutedly on. The utility model discloses rational in infrastructure, convenient operation, this detection device portable removes the use, and the user state is convenient for adjust, does not occupy the use volume, and is convenient for change not unidimensional probe.
Description
Technical Field
The utility model relates to an in situ test probe technical field especially relates to a detection device is markd to in situ test probe.
Background
The in-situ test is to test the rock property at the original position of the rock or basically under the in-situ state and stress condition, the common in-situ test method comprises a load test, a static sounding test, a side pressure test, a cross plate shearing test, a standard penetration test, a wave velocity test and other field tests, when the distance measured by a measuring scale is compared, the distance between a probe and an object is changed by moving the probe to obtain a plurality of groups of data, thereby obtaining an error coefficient, and when the actual detection is carried out, the error coefficient is subtracted to obtain an accurate measured value;
however, the existing detection device is inconvenient to carry and use, the use state is inconvenient to adjust, and the use volume is occupied.
SUMMERY OF THE UTILITY MODEL
The utility model aims at solving the problem that the detection device is not convenient to carry and use, the service condition is not convenient to adjust, the defect of the service volume is occupied, and the provided in-situ test probe calibrates the detection device.
In order to achieve the above purpose, the utility model adopts the following technical scheme:
an in-situ test probe calibration detection device comprises a base, wherein a fixed seat is fixedly arranged at the top of the base, a connecting groove is formed in the top of the fixed seat, a rotating plate is rotatably arranged in the connecting groove, a fixed groove is formed in one side of the rotating plate, a moving plate is slidably arranged in the fixed groove, a mounting seat is fixedly arranged on one side of the moving plate, a mounting groove is formed in one side of the mounting seat, a probe is movably arranged in the mounting groove, grooves are formed in the inner walls of the two sides of the mounting groove, clamping arms are slidably arranged in the two grooves and are in contact with the probe, a fixed cavity is formed in the mounting seat, two through holes are formed in the inner wall of one side of the fixed cavity, connecting rods are slidably arranged in the two through holes, one ends of the connecting rods are welded on the, both racks are engaged with the gear.
Preferably, a slide hole is formed in the inner wall of one side of the groove, a slide rod is slidably mounted in the slide hole, one end of the slide rod is welded on the clamping arm, a pull ring is fixedly mounted at the other end of the slide rod, a pressure spring is sleeved on the slide rod, one end of the pressure spring is welded on one side of the clamping arm, the other end of the pressure spring is welded on the inner wall of one side of the groove, the clamping arm extrudes the pressure spring, the pressure spring elastically deforms, and the clamping arm drives the connecting rod.
Preferably, one side of the movable plate is provided with a threaded hole, a screw rod is installed in the threaded hole, one end of the screw rod is rotatably installed on the inner wall of one side of the fixed groove, an adjusting seat is fixedly installed at the other end of the screw rod, the adjusting seat is rotatably installed on one side of the rotating plate and drives the screw rod to rotate, the screw rod drives the movable plate to move, and the movable plate drives the probe on the installation seat to move.
Preferably, all seted up on the both sides inner wall of spread groove and rotated the groove, the equal fixed mounting in both sides of rotor plate has the turning block, and the turning block rotates to be installed in the rotation inslot that corresponds, and four universal wheels are installed to the bottom of base, and the universal wheel conveniently drives detection device shift position.
Preferably, the inner walls of the two sides of the fixing groove are provided with sliding grooves, the sliding blocks are fixedly mounted on the two sides of the moving plate, the sliding blocks are slidably mounted in the corresponding sliding grooves, the moving plate is driven to slide in the sliding grooves when moving, and the position of the moving plate when moving can be stabilized.
Compared with the prior art, the beneficial effects of the utility model reside in that:
(1) according to the scheme, the universal wheel drives the detection device to move the use position, when the universal wheel moves to the position needing in-situ detection, the rotating plate is rotated, the rotating plate rotates in the connecting groove and drives the moving plate to rotate, the moving plate drives the mounting seat to rotate, the pull ring is pulled, the slide bar drives the clamping arms to move, the clamping arms extrude the pressure spring, the clamping arms drive the connecting rod to move, the racks drive the gear to rotate, the gear drives the other rack to move, and the two clamping arms move towards the directions away from each other;
(2) according to the scheme, the probe is placed in the mounting groove, the pull ring is loosened, the clamping arms are driven to reset and move due to the elastic action of the pressure spring, the probe is clamped and fixed by the two clamping arms, the mounting seat drives the probe to rotate, the adjusting seat is rotated, the lead screw drives the movable plate to move, and then the probe can be used for in-situ testing;
the utility model discloses rational in infrastructure, convenient operation, this detection device portable removes the use, and the user state is convenient for adjust, does not occupy the use volume, and is convenient for change not unidimensional probe.
Drawings
Fig. 1 is a schematic view of a front view structure provided by the present invention;
fig. 2 is a schematic structural view of the fixing base, the rotating plate and the rotating block provided by the present invention;
fig. 3 is a schematic view of a part a of the structure of the present invention.
In the figure: 1. a base; 2. a fixed seat; 3. a rotating plate; 4. fixing grooves; 5. moving the plate; 6. a mounting seat; 7. mounting grooves; 8. a probe; 9. a clamp arm; 10. a fixed cavity; 11. a rack; 12. a gear; 13. a connecting rod; 14. a pressure spring; 15. connecting grooves; 16. rotating the block; 17. and a screw rod.
Detailed Description
The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments.
Referring to fig. 1-3, an in-situ test probe calibration detection device comprises a base 1, a fixed seat 2 is fixedly installed on the top of the base 1, a connecting groove 15 is formed in the top of the fixed seat 2, a rotating plate 3 is rotatably installed in the connecting groove 15, a fixed groove 4 is formed in one side of the rotating plate 3, a moving plate 5 is slidably installed in the fixed groove 4, an installation seat 6 is fixedly installed on one side of the moving plate 5, an installation groove 7 is formed in one side of the installation seat 6, a probe 8 is movably installed in the installation groove 7, grooves are formed in the inner walls of the two sides of the installation groove 7, clamping arms 9 are slidably installed in the two grooves, the two clamping arms 9 are in contact with the probe 8, a fixed cavity 10 is formed in the installation seat 6, two through holes are formed in the inner wall of one side of the fixed cavity 10, connecting, all fixedly connected with rack 11 on two connecting rods 13, gear 12 is installed to the internal rotation of fixed chamber 10, and two racks 11 all mesh with gear 12.
In this embodiment, a slide hole has been seted up on one side inner wall of recess, slidable mounting has the slide bar in the slide hole, the one end welding of slide bar is on centre gripping arm 9, the other end fixed mounting of slide bar has the pull ring, the cover is equipped with pressure spring 14 on the slide bar, the one end welding of pressure spring 14 is in one side of centre gripping arm 9, the other end welding of pressure spring 14 is on one side inner wall of recess, centre gripping arm 9 extrudees pressure spring 14, elastic deformation takes place for pressure spring 14, centre gripping arm 9 drives connecting rod 13 and removes.
In this embodiment, a threaded hole is formed in one side of the movable plate 5, a screw rod 17 is installed in the threaded hole, one end of the screw rod 17 is rotatably installed on the inner wall of one side of the fixed groove 4, an adjusting seat is fixedly installed at the other end of the screw rod 17, the adjusting seat is rotatably installed on one side of the rotating plate 3, the adjusting seat drives the screw rod 17 to rotate, the screw rod 17 drives the movable plate 5 to move, and the movable plate 5 drives the probe 8 on the installation seat 6 to move.
In this embodiment, all seted up on the both sides inner wall of spread groove 15 and rotated the groove, the equal fixed mounting in both sides of rotor plate 3 has turning block 16, and turning block 16 rotates to be installed in the rotation inslot that corresponds, and four universal wheels are installed to base 1's bottom, and the universal wheel conveniently drives detection device shift position.
In this embodiment, the inner walls of the two sides of the fixing groove 4 are both provided with sliding grooves, the two sides of the moving plate 5 are both fixedly provided with sliding blocks, the sliding blocks are slidably mounted in the corresponding sliding grooves, the moving plate 5 is driven to slide in the sliding grooves when moving, and the position of the moving plate 5 when moving can be stabilized.
In this embodiment, the worker checks each component and can use the component after ensuring no error, the universal wheel drives the detection device to move the use position, when the component is moved to the position needing to be detected in situ, the rotating plate 3 is rotated, the rotating plate 3 rotates in the connecting groove 15 and drives the moving plate 5 to rotate, the moving plate 5 drives the mounting seat 6 to rotate, the pull ring is pulled, the pull ring drives the sliding rod to move, the sliding rod drives the clamping arms 9 to move, the clamping arms 9 extrude the pressure spring 14, the pressure spring 14 generates elastic deformation, the clamping arms 9 drive the connecting rod 13 to move, the connecting rod 13 drives the rack 11 to move, the rack 11 drives the gear 12 to rotate, the gear 12 drives the other rack 11 to move, the rack 11 drives the corresponding clamping arms 9 to move, the two clamping arms 9 move in the directions away from each other, the probe 8 is placed in the mounting groove 7, the pull ring is loosened, the clamping arms, two centre gripping arms 9 remove to the direction that is close to each other, and two centre gripping arms 9 carry out the centre gripping to probe 8 fixedly, and but two centre gripping arms 9 centre gripping unidimensional probe 8, and mount pad 6 drives probe 8 and rotates, rotates and adjusts the seat, adjusts the seat and drives lead screw 17 and rotate, and lead screw 17 drives movable plate 5 and removes, and movable plate 5 drives probe 8 on the mount pad 6 and removes, can use probe 8 to carry out the normal position test, the utility model discloses rational in infrastructure, convenient operation, this detection device portable removes the use, and the user state is convenient for adjust, does not occupy the use volume, and is convenient for change unidimensional probe 8.
The utility model discloses the standard part that uses all can purchase from the market, and dysmorphism piece all can be customized according to the description with the record of drawing of description, and the concrete connection mode of each part all adopts conventional means such as ripe bolt, rivet, welding among the prior art, and machinery, part and equipment all adopt prior art, and conventional model, including circuit connection adopts conventional connection mode among the prior art, does not detailed here again.
Claims (5)
1. The in-situ test probe calibration detection device comprises a base (1) and is characterized in that a fixed seat (2) is fixedly mounted at the top of the base (1), a connecting groove (15) is formed in the top of the fixed seat (2), a rotating plate (3) is rotatably mounted in the connecting groove (15), a fixed groove (4) is formed in one side of the rotating plate (3), a movable plate (5) is slidably mounted in the fixed groove (4), a mounting seat (6) is fixedly mounted on one side of the movable plate (5), a mounting groove (7) is formed in one side of the mounting seat (6), a probe (8) is movably mounted in the mounting groove (7), grooves are formed in inner walls of two sides of the mounting groove (7), clamping arms (9) are slidably mounted in the two grooves, the two clamping arms (9) are in contact with the probe (8), and a fixed cavity (10) is formed in, two through holes are formed in the inner wall of one side of the fixed cavity (10), the connecting rods (13) are arranged in the two through holes in a sliding mode, one ends of the connecting rods (13) are welded to the corresponding clamping arms (9), racks (11) are fixedly connected to the two connecting rods (13), the gears (12) are installed in the fixed cavity (10) in a rotating mode, and the two racks (11) are all meshed with the gears (12).
2. The in-situ test probe calibration detection device according to claim 1, wherein a slide hole is formed in an inner wall of one side of the groove, a slide rod is slidably mounted in the slide hole, one end of the slide rod is welded to the clamping arm (9), a pull ring is fixedly mounted at the other end of the slide rod, a pressure spring (14) is sleeved on the slide rod, one end of the pressure spring (14) is welded to one side of the clamping arm (9), and the other end of the pressure spring (14) is welded to an inner wall of one side of the groove.
3. The in-situ test probe calibration and detection device according to claim 1, wherein a threaded hole is formed in one side of the movable plate (5), a lead screw (17) is installed in the threaded hole, one end of the lead screw (17) is rotatably installed on the inner wall of one side of the fixed groove (4), an adjusting seat is fixedly installed at the other end of the lead screw (17), and the adjusting seat is rotatably installed on one side of the rotating plate (3).
4. The in-situ test probe calibration and detection device according to claim 1, wherein the inner walls of the two sides of the connecting groove (15) are both provided with a rotating groove, the two sides of the rotating plate (3) are both fixedly provided with a rotating block (16), the rotating block (16) is rotatably arranged in the corresponding rotating groove, and the bottom of the base (1) is provided with four universal wheels.
5. The in-situ test probe calibration and detection device according to claim 1, wherein sliding grooves are formed in inner walls of two sides of the fixing groove (4), sliding blocks are fixedly mounted on two sides of the moving plate (5), and the sliding blocks are slidably mounted in the corresponding sliding grooves.
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CN202020060925.6U CN211205361U (en) | 2020-01-11 | 2020-01-11 | In-situ test probe calibration detection device |
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CN202020060925.6U CN211205361U (en) | 2020-01-11 | 2020-01-11 | In-situ test probe calibration detection device |
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Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN112097986A (en) * | 2020-09-17 | 2020-12-18 | 中铝国际工程股份有限公司 | Underground engineering three-dimensional stress field monitoring and early warning device and monitoring method thereof |
CN112281795A (en) * | 2020-09-18 | 2021-01-29 | 磐索地勘科技(广州)有限公司 | Deep sea static sounding probe calibration device and method |
-
2020
- 2020-01-11 CN CN202020060925.6U patent/CN211205361U/en active Active
Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN112097986A (en) * | 2020-09-17 | 2020-12-18 | 中铝国际工程股份有限公司 | Underground engineering three-dimensional stress field monitoring and early warning device and monitoring method thereof |
CN112281795A (en) * | 2020-09-18 | 2021-01-29 | 磐索地勘科技(广州)有限公司 | Deep sea static sounding probe calibration device and method |
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