CN220381193U - Adapter device of dual-output measurement alternating current-direct current sensor - Google Patents

Abstract

The utility model discloses an adaptation device of a double-output measurement alternating current/direct current sensor, which relates to the field of sensors and comprises an alternating current/direct current sensor, wherein a detection hole is formed in the alternating current/direct current sensor. According to the utility model, through the arrangement of the structures such as the first U-shaped clamping strip and the second U-shaped clamping strip, the linkage plate is pressed to drive the first U-shaped clamping strip and the second U-shaped clamping strip to move, so that the gap between the first U-shaped clamping strip and the second U-shaped clamping strip is enlarged, and meanwhile, shielding of the detection hole is avoided, at the moment, the detection hole on the AC/DC current sensor and the gap formed between the first U-shaped clamping strip and the second U-shaped clamping strip can be sleeved on a line segment to be detected, then the linkage plate is loosened, the first U-shaped clamping strip and the second U-shaped clamping strip can be driven to move and reset under the action of the limiting spring, the gap between the first U-shaped clamping strip and the second U-shaped clamping strip is reduced until the line segment is clamped, the connection between the AC/DC current sensor and the line segment is completed, the AC/DC current sensor is prevented from shaking and wearing on the line segment in the detection process, and the detection stability is improved.

Description

Adapter device of dual-output measurement alternating current-direct current sensor

Technical Field

The utility model relates to the technical field of sensors, in particular to an adaptive device of a double-output measurement alternating current-direct current sensor.

Background

The double-output measuring AC/DC current sensor is a device for detecting AC/DC current, which can sense the information of the detected AC/DC current, and can convert the sensed information into electric signals or other information output in the required form according to a certain rule so as to meet the requirements of information transmission, processing, storage, display, recording, control and the like, and the double-output measurement is generally made into a signal with one path of 4-20 mA and the other path of 20-4 mA, so that the design is mainly used for reducing the power consumption.

In the prior art, in the process of installing a dual-output measurement AC/DC current sensor, a measuring hole on the sensor needs to be sleeved on a line segment to be measured, but the fixing effect is poor because the sensor is directly sleeved on the line segment, after the sensor is installed, the sensor is easy to shake on the measuring line segment, friction is caused between the sensor and the line segment, abrasion is caused, and the measuring stability of the sensor is influenced, so that the requirement of people is met by an adapting device of the dual-output measurement AC/DC current sensor.

Disclosure of Invention

The utility model aims to provide an adapting device of a double-output measuring alternating current/direct current sensor, which aims to solve the problems that in the process of installing the double-output measuring alternating current/direct current sensor provided in the prior art, a measuring hole on the sensor needs to be sleeved on a line segment to be measured, but the sensor is easy to shake on the measuring line segment after the sensor is installed due to poor fixing effect, and friction is caused between the sensor and the line segment, so that the stability of the measurement of the sensor is affected.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the utility model provides an adapter device of two output measurement's alternating current-direct current sensor, includes alternating current-direct current sensor, be equipped with the detection hole on the alternating current-direct current sensor, one side symmetry fixed mounting of alternating current-direct current sensor has two fixed plates, installs same clamping structure on two fixed plates, and the top side symmetry fixed mounting of alternating current-direct current sensor has two gag lever posts, and fixed mounting has same baffle on two gag lever posts, and slidable mounting has same linkage board on two gag lever posts, installs the linkage structure on the linkage board, and the equal fixed mounting in both sides of baffle has the connecting strip, all installs limit structure on two connecting strips.

Preferably, the clamping structure comprises four connecting rods, the four connecting rods are symmetrically and slidably mounted on the two fixing plates respectively, the same connecting plate is fixedly mounted on the two connecting rods located on the same side, a first U-shaped clamping strip and a second U-shaped clamping strip are fixedly mounted on the two connecting plates respectively, two dislocation grooves are formed in the first U-shaped clamping strip, and the second U-shaped clamping strip is slidably mounted in the two dislocation grooves.

Preferably, two limit bars are symmetrically and fixedly arranged on one side of the alternating current/direct current sensor, limit sliding grooves are formed in the two limit bars, two limit sliding blocks are slidably arranged in the two limit sliding grooves, and four limit sliding blocks are symmetrically and fixedly arranged on two sides of the two connecting plates respectively.

Preferably, two sliding holes are formed in the fixing plate, the two connecting rods are respectively and slidably installed in the two sliding holes, limiting springs are respectively and slidably sleeved on the two sliding holes, and two ends of the two limiting springs are respectively and fixedly installed on one side, close to the fixing plate and the connecting plate, of the fixing plate.

Preferably, the linkage structure comprises two first connecting blocks, the two first connecting blocks are fixedly arranged on the linkage plate, the two first connecting blocks are respectively provided with a linkage rod in a rotating mode, the two linkage rods are respectively provided with a second connecting block in a rotating mode, and the two second connecting blocks are respectively and fixedly arranged on the first U-shaped holding strip and the second U-shaped holding strip.

Preferably, the first connecting block and the second connecting block are respectively provided with a linkage hole, the two linkage holes are respectively internally provided with a linkage shaft in a rotating way, and the two linkage shafts are respectively and fixedly arranged at two ends of the linkage rod.

Preferably, the limiting structure comprises two movable clamping plates, the two movable clamping plates are respectively rotatably arranged on the two connecting strips, two limiting clamping grooves are formed in the linkage plate, and the two movable clamping plates are respectively matched with the two limiting clamping grooves.

Preferably, the connecting bar is provided with a movable hole, the movable hole is rotationally provided with a connecting shaft, the connecting shaft is fixedly arranged on the movable clamping plate, a torsion spring is fixedly sleeved on the connecting shaft, one end of the torsion spring is fixedly arranged on the inner wall of the movable hole, and the other end of the torsion spring is fixedly arranged on the connecting shaft.

The beneficial effects of the utility model are as follows:

according to the utility model, through the arrangement of the structures such as the first U-shaped clamping strip and the second U-shaped clamping strip, the linkage plate is pressed to drive the first U-shaped clamping strip and the second U-shaped clamping strip to move, so that a gap between the first U-shaped clamping strip and the second U-shaped clamping strip is enlarged, and meanwhile, shielding of a detection hole is avoided, at the moment, a detection hole on an alternating current-direct current sensor and a gap formed between the first U-shaped clamping strip and the second U-shaped clamping strip can be sleeved on a line segment to be detected, then the linkage plate is loosened, the first U-shaped clamping strip and the second U-shaped clamping strip can be driven to move and reset under the action of the limiting spring, the gap between the first U-shaped clamping strip and the second U-shaped clamping strip is reduced until the line segment is clamped, the alternating current-direct current sensor and the line segment are connected, the alternating current-direct current sensor is prevented from shaking on the line segment in the detection process, and the detection stability is improved.

According to the utility model, through the arrangement of the linkage plate, the gap between the first U-shaped clamping strip and the second U-shaped clamping strip can be adjusted to different sizes by pressing the linkage plate, so that the U-shaped clamping strip can be suitable for clamping line segments with different thicknesses.

Drawings

Fig. 1 is a schematic structural diagram of an adapting device of a dual-output measurement ac/dc current sensor according to the present utility model;

fig. 2 is a schematic structural diagram of a linkage plate portion of an adapting device of a dual-output measurement ac/dc current sensor according to the present utility model;

fig. 3 is a schematic structural diagram of a portion a in fig. 2 of an adapting device of a dual-output measurement ac/dc current sensor according to the present utility model;

fig. 4 is a schematic structural diagram of a first U-shaped clip strip and a second U-shaped clip strip of an adapting device of a dual-output measurement ac/dc current sensor according to the present utility model.

In the figure: 100. an alternating current/direct current sensor; 101. a detection hole; 200. a fixing plate; 201. a connecting rod; 202. a connecting plate; 203. a first U-shaped clip strip; 204. the second U-shaped clamping strip; 205. a dislocation groove; 206. a limit bar; 207. limiting sliding grooves; 208. a limit sliding block; 209. a sliding hole; 210. a limit spring; 300. a limit rod; 301. a baffle; 302. a linkage plate; 303. a first connection block; 304. a linkage rod; 305. a second connection block; 306. a linkage hole; 307. a linkage shaft; 400. a connecting strip; 401. a movable clamping plate; 402. a limit clamping groove; 403. a movable hole; 404. a connecting shaft; 405. and (3) a torsion spring.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments.

Referring to fig. 1 to 4, an adapting device of a dual-output measurement ac/dc current sensor includes an ac/dc current sensor 100, a detection hole 101 is provided on the ac/dc current sensor 100, two fixing plates 200 are symmetrically and fixedly installed on one side of the ac/dc current sensor 100, the same clamping structure is installed on the two fixing plates 200, two limit levers 300 are symmetrically and fixedly installed on the top side of the ac/dc current sensor 100, the same baffle 301 is fixedly installed on the two limit levers 300, the same linkage plate 302 is slidingly installed on the two limit levers 300, a linkage structure is installed on the linkage plate 302, connecting strips 400 are fixedly installed on both sides of the baffle 301, limit structures are installed on the two connecting strips 400, the linkage plate 302 can be pressed before installation, so that the linkage plate 302 slides on the two limit levers 300, the linkage plate 302 slides and drives the two first connecting blocks 303 to move, and the two first connecting blocks 303 respectively drive one ends of the two linkage rods 304 to turn over and move through the cooperation of the linkage holes 306 and the linkage shafts 307, so that the other ends of the two linkage rods 304 drive the two second connecting blocks 305 to approach each other, the two second connecting blocks 305 approaching each other respectively drive the first U-shaped clamping strip 203 and the second U-shaped clamping strip 204 to move towards one side approaching each other, the continuously moving first U-shaped clamping strip 203 and second U-shaped clamping strip 204 respectively drive the two connecting plates 202 to move, the moving two connecting plates 202 respectively drive the limiting sliding blocks 208 on the limiting sliding grooves 207 on the limiting strips 206 to slide, and further the moving directions of the first U-shaped clamping strip 203 and the second U-shaped clamping strip 204 are limited, the continuously moving connecting plate 202 compresses the two limiting springs 210 and drives the two connecting rods 201 to slide in the two sliding holes 209 on the fixed plate 200 respectively, so that the moving direction of the connecting plate 202 is limited, the second U-shaped clamping strip 204 moves while sliding in the dislocation groove 205 on the first U-shaped clamping strip 203, the gap between the first U-shaped clamping strip 203 and the second U-shaped clamping strip 204 becomes larger in the process of continuously moving the first U-shaped clamping strip 203 and the second U-shaped clamping strip 204, shielding to the detection hole 101 is relieved, the linkage plate 302 is far away from the movable clamping plate 401 in the process of continuously moving, and the torsion spring 405 is in a compressed state, when the linkage plate 302 is far away from the movable clamping plate 401, the torsion spring 405 releases and drives the connecting shaft 404 to rotate in the movable hole 403 on the connecting strip 400, so that the rotating effect is realized, the continuously rotating connecting shaft 404 drives the movable clamping plate 401 to overturn, when the gap between the first U-shaped clamping strip 203 and the second U-shaped clamping strip 204 exceeds the size of the detection hole 101, the movable clamping plate 401 can also turn down by ninety degrees under the action of the torsion spring 405, then the linkage plate 302 is loosened, the first U-shaped clamping strip 203 and the second U-shaped clamping strip 204 are not extruded by the linkage plate 302 any more, at the moment, the two connecting plates 202 are respectively pushed by the limit springs 210 compressed at two sides to restore to the original position, so that the two connecting plates 202 respectively drive the first U-shaped clamping strip 203 and the second U-shaped clamping strip 204 to move and reset, the first U-shaped clamping strip 203 and the second U-shaped clamping strip 204 push the linkage plate 302 to move and reset through the cooperation of the two linkage rods 304, so that the two limit clamping grooves 402 on the linkage plate 302 can be sleeved on the two movable clamping plates 401, the linkage plate 302 is blocked by the two movable clamping plates 401 and can only move upwards for a small distance, the gap between the first U-shaped clamping strip 203 and the second U-shaped clamping strip 204 is in a normally open state, at this time, when the detection hole 101 on the ac/dc current sensor 100 is sleeved on a line segment to be tested, only the linkage plate 302 needs to be pressed down again to enable the limiting clamping groove 402 to be far away from the movable clamping plate 401 during fixing, at this time, the two movable clamping plates 401 are turned over to enable the linkage plate 302 not to be blocked by the movable clamping plate 401 any more, at this time, the first U-shaped clamping strip 203 and the second U-shaped clamping strip 204 are not extruded by the two linkage rods 304 any more, under the action of the limiting springs 210 at two sides, the first U-shaped clamping strip 203 and the second U-shaped clamping strip 204 can be moved and reset, the gap between the first U-shaped clamping strip 203 and the second U-shaped clamping strip 204 to be reset is smaller and smaller until the line segment is clamped at the middle position, and therefore connection and fixing of the line segment and the ac/dc current sensor 100 are completed, and the line segment fixing device can be suitable for being used for line segments with different sizes.

Further, the clamping structure comprises four connecting rods 201, the four connecting rods 201 are symmetrically and slidably mounted on two fixing plates 200 respectively, two connecting rods 201 located on the same side are fixedly provided with the same connecting plate 202, two limiting sliding blocks 208 on the two connecting plates 202 are fixedly mounted in limiting sliding grooves 207 on limiting sliding grooves 206 respectively, two dislocation grooves 205 are formed in the first U-shaped clamping strips 203, the second U-shaped clamping strips 204 are slidably mounted in the two dislocation grooves 205, two second connecting blocks 305 which are close to each other respectively drive the first U-shaped clamping strips 203 and the second U-shaped clamping strips 204 to move towards one side which is close to each other, the continuously moving first U-shaped clamping strips 203 and second U-shaped clamping strips 204 respectively drive the two connecting plates 202 to move, the continuously moving limiting sliding blocks 208 on the limiting sliding grooves 207 respectively, the continuously moving connecting plates 202 are further limited in the limiting sliding grooves 207 on the limiting sliding grooves 206, the continuously moving connecting plates 202 are compressed by the two limiting sliding springs 210 respectively, the two limiting sliding grooves 205 on the two connecting plates 200 are further limited in the limiting sliding grooves 204, and the continuously moving direction of the two U-shaped clamping strips 204 can be simultaneously, and the two connecting plates are continuously moving in the limiting sliding grooves 204 are simultaneously, and the two limiting sliding grooves 204 are prevented from moving in the sliding directions between the two U-shaped clamping strips 203 and the two limiting sliding grooves 204.

Further, two limit bars 206 are symmetrically and fixedly installed on one side of the ac/dc current sensor 100, limit sliding grooves 207 are formed in the two limit bars 206, two limit sliding blocks 208 are slidably installed in the two limit sliding grooves 207, four limit sliding blocks 208 are symmetrically and fixedly installed on two sides of the two connecting plates 202 respectively, the two moving connecting plates 202 respectively drive the upper limit sliding blocks 208 to slide in the limit sliding grooves 207 on the limit bars 206, and further the moving directions of the first U-shaped holding bars 203 and the second U-shaped holding bars 204 are limited.

Further, two sliding holes 209 are formed in the fixing plate 200, two connecting rods 201 are respectively slidably mounted in the two sliding holes 209, limiting springs 210 are respectively sleeved on the two sliding holes 209 in a sliding manner, two ends of each limiting spring 210 are respectively fixedly mounted on one side, close to the fixing plate 200 and the connecting plate 202, of the connecting plate 202 which continuously moves, then the two limiting springs 210 are compressed, the two connecting rods 201 are driven to respectively slide in the two sliding holes 209 on the fixing plate 200, and accordingly the moving direction of the connecting plate 202 is limited.

Further, the linkage structure includes two first connecting blocks 303, two first connecting blocks 303 are all fixedly installed on the linkage plate 302, linkage rods 304 are all rotatably installed on two first connecting blocks 303, second connecting blocks 305 are all rotatably installed on two linkage rods 304, two second connecting blocks 305 are respectively fixedly installed on the first U-shaped clamping strip 203 and the second U-shaped clamping strip 204, the linkage plate 302 is pressed, the linkage plate 302 slides on two limiting rods 300, the linkage plate 302 can drive the two first connecting blocks 303 to move while sliding, one ends of the two linkage rods 304 are respectively driven to overturn and move through the cooperation of linkage holes 306 and linkage shafts 307 while the two first connecting blocks 303 move, the other ends of the two linkage rods 304 drive the two second connecting blocks 305 to be close to each other, and the two second connecting blocks 305 which are close to each other can respectively drive the first U-shaped clamping strip 203 and the second U-shaped clamping strip 204 to move towards one side which is close to each other.

Further, the first connecting block 303 and the second connecting block 305 are provided with linkage holes 306, linkage shafts 307 are rotatably installed in the two linkage holes 306, the two linkage shafts 307 are fixedly installed at two ends of the linkage rod 304 respectively, and one ends of the two linkage rods 304 are driven to turn over and move respectively through the cooperation of the linkage holes 306 and the linkage shafts 307 while the two first connecting blocks 303 move, so that the other ends of the two linkage rods 304 drive the two second connecting blocks 305 to approach each other.

Further, limit structure includes two movable clamp plates 401, two movable clamp plates 401 rotate respectively and install on two connecting strips 400, set up two limit clamping grooves 402 on the linkage plate 302, two movable clamp plates 401 respectively with two limit clamping grooves 402 looks adaptations, the linkage plate 302 can keep away from movable clamp plates 401 at the in-process that keeps moving, because torsional spring 405 is in compressed state, when movable clamp plates 401 are kept away from to linkage plate 302, torsional spring 405 can release and drive connecting axle 404 in the movable hole 403 rotation on connecting strip 400, realize the pivoted effect, continuously pivoted connecting axle 404 can drive movable clamp plates 401 and overturn, when the space between first U type holding strip 203 and the second U type holding strip 204 exceeds the size of detecting hole 101, movable clamp plates 401 also can overturn ninety degrees down under the effect of torsional spring 405, then at the release linkage plate 302, first U type holding strip 203 and second U type holding strip 204 no longer receive the extrusion of linkage plate 302, the limit spring 210 that both sides compress can promote two connecting plates 202 respectively and resume the normal position, make two U type holding strips 203 drive two U type holding strips 203 and two movable clamp plates 204 and can make two movable clamp plates 202 to move the linkage plate 302 and can make two sections and two U type holding strip 204 and two movable clamp plates 204 move the linkage plates 302 and can make the linkage plate 302 move up the linkage plate 302 and can the small.

Further, a movable hole 403 is formed in the connecting bar 400, a connecting shaft 404 is rotatably mounted in the movable hole 403, the connecting shaft 404 is fixedly mounted on the movable clamping plate 401, a torsion spring 405 is fixedly sleeved on the connecting shaft 404, one end of the torsion spring 405 is fixedly mounted on the inner wall of the movable hole 403, the other end of the torsion spring 405 is fixedly mounted on the connecting shaft 404, and when the linkage plate 302 is far away from the movable clamping plate 401, the torsion spring 405 can release and drive the connecting shaft 404 to rotate in the movable hole 403 on the connecting bar 400, so that the rotating effect is achieved.

The working principle of the utility model is as follows:

before installation, the linkage plate 302 can be pressed, the linkage plate 302 slides on the two limiting rods 300, the linkage plate 302 slides and simultaneously drives the two first connecting blocks 303 to move, the two first connecting blocks 303 respectively drive one ends of the two linkage rods 304 to turn over and move through the cooperation of the linkage holes 306 and the linkage shafts 307, the other ends of the two linkage rods 304 drive the two second connecting blocks 305 to be close to each other, the two second connecting blocks 305 which are close to each other respectively drive the first U-shaped holding strip 203 and the second U-shaped holding strip 204 to move towards one side which is close to each other, the continuously moving first U-shaped holding strip 203 and the second U-shaped holding strip 204 respectively drive the two connecting plates 202 to move, the moving two connecting plates 202 respectively drive the limiting slide blocks 208 on the limiting strips 206 to slide in the limiting slide grooves 207 on the limiting strips 206, the moving connecting springs 202 compress the two connecting plates 210 and drive the two connecting rods to respectively to block the two connecting rods to move in the two connecting rods 200 to slide in the direction of the first U-shaped holding strip 200, the two connecting plates 203 continuously moving in the opposite direction of the first U-shaped holding strip 203 and the second U-shaped holding strip 204 are far away from the limiting slide in the limiting grooves 401, and simultaneously release the two connecting plates 202 to move in the moving direction of the first U-shaped holding strip 200, and the second U-shaped holding strip 204 continuously moves away from the limiting torsion spring 401, and the moving in the moving direction of the first holding strip is far away from the moving plate 203, and the moving in the limiting slide plate 204 is far from the limiting plate 204, and the moving in the moving direction of the limiting plate is simultaneously, and the moving plate 200, when the gap between the first U-shaped clamping strip 203 and the second U-shaped clamping strip 204 exceeds the size of the detection hole 101, the movable clamping plate 401 can also turn down by ninety degrees under the action of the torsion spring 405, then when the linkage plate 302 is released, the first U-shaped clamping strip 203 and the second U-shaped clamping strip 204 are not extruded by the linkage plate 302 any more, at the moment, the two connecting plates 202 are respectively pushed by the limit springs 210 compressed at two sides to restore to the original position, so that the two connecting plates 202 respectively drive the first U-shaped clamping strip 203 and the second U-shaped clamping strip 204 to move and reset, the first U-shaped clamping strip 203 and the second U-shaped clamping strip 204 push the linkage plate 302 to move and reset through the cooperation of the two linkage rods 304, so that the two limit clamping grooves 402 on the linkage plate 302 can be sleeved on the two movable clamping plates 401, the linkage plate 302 is blocked by the two movable clamping plates 401, the gap between the first U-shaped clamping strip 203 and the second U-shaped clamping strip 204 is in a normally open state only by moving upwards for a small distance, at the moment, when the detection hole 101 on the alternating current/direct current sensor 100 is sleeved on a line segment to be tested, the linkage plate 302 is only required to be pressed downwards again to keep the limit clamping groove 402 away from the movable clamping plate 401 during fixing, at the moment, when the two movable clamping plates 401 are turned over, the linkage plate 302 is not blocked by the movable clamping plate 401, at the moment, the first U-shaped clamping strip 203 and the second U-shaped clamping strip 204 are not extruded by the two linkage rods 304, under the action of the limit springs 210 at two sides, the first U-shaped clamping strip 203 and the second U-shaped clamping strip 204 are moved and reset, the gap between the reset first U-shaped clamping strip 203 and the second U-shaped clamping strip 204 is smaller and smaller until the line segment is clamped at the middle position, and the connection and fixing of the line segment and the alternating current/direct current sensor 100 are completed, and the device is applicable to line segment fixing of different sizes.

The foregoing is only a preferred embodiment of the present utility model, but the scope of the present utility model is not limited thereto, and any person skilled in the art, who is within the scope of the present utility model, should make equivalent substitutions or modifications according to the technical scheme of the present utility model and the inventive concept thereof, and should be covered by the scope of the present utility model.

Claims (8)

1. The utility model provides an adaptation device of dual output measurement's alternating current-direct current sensor, includes alternating current-direct current sensor (100), be equipped with detection hole (101), its characterized in that on alternating current-direct current sensor (100): one side symmetry fixed mounting of alternating current-direct current sensor (100) has two fixed plates (200), install same clamping structure on two fixed plates (200), the topside symmetry fixed mounting of alternating current-direct current sensor (100) has two gag levers (300), fixed mounting has same baffle (301) on two gag levers (300), slidable mounting has same linkage board (302) on two gag levers (300), install linkage structure on linkage board (302), the equal fixed mounting of both sides of baffle (301) has connecting strip (400), limit structure is all installed on two connecting strips (400).

2. The adapting device of a dual-output measured ac/dc current sensor according to claim 1, wherein: the clamping structure comprises four connecting rods (201), the four connecting rods (201) are symmetrically and slidably mounted on two fixing plates (200) respectively, the same connecting plate (202) is fixedly mounted on the two connecting rods (201) located on the same side, a first U-shaped clamping strip (203) and a second U-shaped clamping strip (204) are fixedly mounted on the two connecting plates (202) respectively, two dislocation grooves (205) are formed in the first U-shaped clamping strip (203), and the second U-shaped clamping strip (204) is slidably mounted in the two dislocation grooves (205).

3. The adapting device of a dual-output measured ac/dc current sensor according to claim 1, wherein: two limit bars (206) are symmetrically and fixedly arranged on one side of the alternating current/direct current sensor (100), limit sliding grooves (207) are formed in the two limit bars (206), two limit sliding blocks (208) are slidably arranged in the two limit sliding grooves (207), and four limit sliding blocks (208) are symmetrically and fixedly arranged on two sides of the two connecting plates (202) respectively.

4. The adapting device of a dual-output measured ac/dc current sensor according to claim 1, wherein: two sliding holes (209) are formed in the fixing plate (200), two connecting rods (201) are respectively and slidably mounted in the two sliding holes (209), limiting springs (210) are respectively and slidably sleeved on the two sliding holes (209), and two ends of the two limiting springs (210) are respectively and fixedly mounted on one side, close to each other, of the fixing plate (200) and the connecting plate (202).

5. The adapting device of a dual-output measured ac/dc current sensor according to claim 1, wherein: the linkage structure comprises two first connecting blocks (303), the two first connecting blocks (303) are fixedly arranged on a linkage plate (302), linkage rods (304) are rotatably arranged on the two first connecting blocks (303), second connecting blocks (305) are rotatably arranged on the two linkage rods (304), and the two second connecting blocks (305) are fixedly arranged on the first U-shaped clamping strip (203) and the second U-shaped clamping strip (204) respectively.

6. The adapting device of a dual-output measured ac/dc current sensor according to claim 5, wherein: linkage holes (306) are formed in the first connecting block (303) and the second connecting block (305), linkage shafts (307) are rotatably mounted in the two linkage holes (306), and the two linkage shafts (307) are fixedly mounted at two ends of the linkage rod (304) respectively.

7. The adapting device of a dual-output measured ac/dc current sensor according to claim 1, wherein: the limiting structure comprises two movable clamping plates (401), the two movable clamping plates (401) are respectively rotatably mounted on the two connecting strips (400), two limiting clamping grooves (402) are formed in the linkage plate (302), and the two movable clamping plates (401) are respectively matched with the two limiting clamping grooves (402).

8. The adapting device of a dual-output measured ac/dc current sensor according to claim 1, wherein: the connecting strip (400) is provided with a movable hole (403), a connecting shaft (404) is rotatably installed in the movable hole (403), the connecting shaft (404) is fixedly installed on the movable clamping plate (401), a torsion spring (405) is fixedly sleeved on the connecting shaft (404), one end of the torsion spring (405) is fixedly installed on the inner wall of the movable hole (403), and the other end of the torsion spring (405) is fixedly installed on the connecting shaft (404).