CN214372592U - Fuse continuous detection equipment - Google Patents
Fuse continuous detection equipment Download PDFInfo
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- CN214372592U CN214372592U CN202023283160.1U CN202023283160U CN214372592U CN 214372592 U CN214372592 U CN 214372592U CN 202023283160 U CN202023283160 U CN 202023283160U CN 214372592 U CN214372592 U CN 214372592U
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- inclined plate
- sliding platform
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Abstract
The utility model discloses a fuse continuous detection equipment, including base, casing, feeding mechanism, receiving mechanism, sliding platform, image detector and numerical control device, casing and base fixed connection, sliding platform fixed mounting are on the base, and receiving mechanism is located sliding platform's below, and image detector and feeding mechanism fixed mounting are on the casing, and image detector is located sliding platform directly over, and feeding mechanism is located image detector's side, and numerical control device is installed on image detector's opposite side. The utility model has the advantages that: fuse check out test set installs feed mechanism, receiving mechanism and sliding platform, connects the material through feed mechanism's automatic feed and receiving mechanism's automation, realizes automatic image detection to reduce the cost of labor that detects, avoid the false retrieval and the hourglass of fuse to examine, effectively improve the mode that detects and improve detection efficiency.
Description
Technical Field
The utility model relates to a fuse detects technical field, especially relates to a fuse continuous detection equipment.
Background
The fuse has the function of protecting an electric appliance, when the current abnormally rises to a certain height and heat, components in the circuit can be damaged, even the circuit is burnt to cause fire, therefore, the fuse is arranged in the circuit, when the current flows through the fuse, the fuse can generate heat, the heating value of the fuse is increased along with the increase of time, the size of the current and the resistance determines the speed of generating heat, the construction and the installation condition of the fuse determine the speed of dissipating heat, if the speed of generating heat is less than the speed of dissipating heat, the fuse can not be fused, if the speed of generating heat is equal to the speed of dissipating heat, the fuse can not be fused within a considerable time, if the speed of generating heat is greater than the speed of dissipating heat, the generated heat is more and more, and the increase of the heat is reflected on the rise of temperature, when the temperature rises above the melting point of the fuse, the fuse is fused, and the fuse fuses to cut off current, so that the effect of protecting the safe operation of a circuit is achieved.
The fuse is the indispensable entry protection of electrical apparatus, the manufacture factory is very strict when detecting the outgoing of fuse quality, current fuse factory generally adopts artifical the detection, it adopts branch worker section flow process to detect, the fuse gets into artifical image detection after accomplishing the equipment, artifical image detection and automated production are equipped with and link up unmatched problem, and the inefficiency of artifical detection, the condition of undetected and false positive can take place occasionally, the mode poor stability picture of taking through the manual work simultaneously can rock, lead to the formation of image unclear, the error rate is higher.
SUMMERY OF THE UTILITY MODEL
An object of the utility model is to provide a fuse is check out test set in succession to realize that automatic image detects, reduce the cost of labor that detects, avoid the false retrieval and the hourglass of fuse to examine, effectively improve the mode that detects and improve detection efficiency.
A fuse continuous detection device comprises a base, a shell, a feeding mechanism, a material receiving mechanism, a sliding platform, an image detector and a numerical control device, wherein the shell is fixedly connected with the base, the sliding platform is fixedly arranged on the base, the material receiving mechanism is positioned below the sliding platform, the image detector and the feeding mechanism are fixedly arranged on the shell, the image detector is positioned right above the sliding platform, the feeding mechanism is positioned at the side edge of the image detector, the numerical control device is arranged at the other side edge of the image detector, the feeding mechanism and the material receiving mechanism are respectively positioned at two ends of the shell, the sliding platform comprises a sliding rail and a fuse box, the fuse box is placed on the sliding rail, the fuse box is a cuboid box, a bottom plate of the fuse box is in sliding connection with the sliding rail in a matching manner, a numerical control switch is arranged on the bottom plate of the fuse box, the feeding mechanism is a cuboid box, and a numerical control switch is arranged below the feeding mechanism, the numerical control switch and the sliding platform are in signal connection with the numerical control device, the material receiving mechanism is provided with a material receiving pipeline, one end of the material receiving pipeline is communicated with a bottom plate of the fuse box, and the other end of the material receiving pipeline is communicated with the material receiving mechanism.
Further, feeding mechanism contains out the magazine, numerical control switch and feed pipeline, and the numerical control switch is located out between magazine and the feed pipeline, and the one end and the ejection of compact box intercommunication of numerical control switch, the other end and the feed pipeline intercommunication of numerical control switch.
Furthermore, the discharging box is a cuboid box, and an inclined plane is arranged in the discharging box.
Furthermore, the fuse box is a cuboid box, and an inclined plane and a numerical control switch are arranged in the fuse box.
The safety box is internally provided with an inclined plane and a numerical control switch, and the detected part in the safety box automatically slides into the material receiving mechanism, so that the automatic detection and receiving of the part are realized, the labor intensity of an operator is reduced, and the fatigue operation of the operator is avoided.
Further, the image detector is provided with a display screen.
Furthermore, the slide rail of the sliding platform comprises a first rail and a second rail, the first rail and the second rail are parallel to each other, and the fuse box is located between the first rail and the second rail.
First track and second track are parallel to each other, and the fuse box is located between first track and the second track, and the fuse box is good at gliding stability on the track, and the problem of rocking that arouses when avoiding the fuse box to slide improves the image definition, and then shortens test time.
Furthermore, the discharging box is provided with an inclined plane, the inclined plane comprises a first inclined plate, a second inclined plate, a third inclined plate and a fourth inclined plate, the first inclined plate and the third inclined plate are opposite in position, the second inclined plate and the fourth inclined plate are opposite in position, and the first inclined plate, the second inclined plate, the third inclined plate and the fourth inclined plate form an inverted four-pyramid body.
Furthermore, the connecting pipe of the material receiving pipeline and the connecting pipe of the material feeding pipeline are hollow circular pipelines, the numerical control switch is a circular switch, and the shapes of the numerical control switch, the material receiving pipeline and the material feeding pipeline are matched with each other.
The utility model has the advantages that: fuse check out test set installs feed mechanism, receiving mechanism and sliding platform, connects the material through feed mechanism's automatic feed and receiving mechanism's automation, realizes automatic image detection to reduce the cost of labor that detects, avoid the false retrieval and the hourglass of fuse to examine, effectively improve the mode that detects and improve detection efficiency. The safety box is internally provided with an inclined plane and a numerical control switch, and the detected part in the safety box automatically slides into the material receiving mechanism, so that the automatic detection and receiving of the part are realized, the labor intensity of an operator is reduced, and the fatigue operation of the operator is avoided. First track and second track are parallel to each other, and the fuse box is located between first track and the second track, and the fuse box is good at gliding stability on the track, and the problem of rocking that arouses when avoiding the fuse box to slide improves the image definition, and then shortens test time.
Drawings
Fig. 1 is a schematic structural view of a fuse continuity testing apparatus.
Fig. 2 is a schematic structural view of a sliding platform.
The labels in the figure are: the device comprises a base 1, a shell 2, a feeding mechanism 3, a material receiving mechanism 4, a sliding platform 5, an image detector 6, a numerical control device 7, a sliding rail 8, a fuse box 9 and a numerical control switch 10.
Detailed Description
Not enough to prior art exists, the utility model provides a fuse is check out test set in succession to realize that automatic image detects, reduce the cost of labor that detects, avoid the false retrieval and the hourglass of fuse to examine, effectively improve the mode that detects and improve detection efficiency.
In order to solve the technical problem, the utility model adopts the following technical scheme:
as an embodiment, as shown in fig. 1, a fuse continuous detection device includes a base 1, a housing 2, a feeding mechanism 3, a receiving mechanism 4, a sliding platform 5, an image detector 6 and a numerical control device 7, the housing 2 is fixedly connected with the base 1, the sliding platform 5 is fixedly installed on the base 1, the receiving mechanism 4 is located below the sliding platform 5, the image detector 6 and the feeding mechanism 3 are fixedly installed on the housing 2, the image detector 6 is located right above the sliding platform 5, the feeding mechanism 3 is located at a side of the image detector 6, the numerical control device 7 is installed at the other side of the image detector 6, the feeding mechanism 3 and the receiving mechanism 4 are respectively located at two ends of the housing 2, the sliding platform 5 includes a slide rail 8 and a fuse box 9, the fuse box 9 is placed on the slide rail 8, the fuse box 9 is a cuboid box, a bottom plate of the fuse box 9 is slidably connected with the slide rail 8, the bottom plate of fuse box 9 is provided with numerical control switch 10, and feed mechanism 3 is the cuboid box, and the below of feed mechanism 3 is provided with numerical control switch 10, and numerical control switch 10 and sliding platform 5 and numerical control device 7 signal connection, receiving mechanism 4 is provided with the material receiving pipeline, and the one end of receiving pipeline communicates with the bottom plate of fuse box 9, and the other end and the receiving mechanism 4 intercommunication of receiving pipeline.
Preferably, the fuse detection equipment is provided with a feeding mechanism 3, a receiving mechanism 4 and a sliding platform 5, and automatic feeding through the feeding mechanism 3 and automatic receiving of the receiving mechanism 4 realize automatic image detection, so that the labor cost of detection is reduced, false detection and missing detection of fuses are avoided, the detection mode is effectively improved, and the detection efficiency is improved.
Preferably, feeding mechanism 3 contains out the magazine, numerical control switch 10 and feed pipeline, and numerical control switch 10 is located out between magazine and the feed pipeline, and numerical control switch 10's one end and ejection of compact box intercommunication, numerical control switch 10's the other end and feed pipeline intercommunication.
Preferably, the discharging box is a cuboid box, and an inclined plane is arranged in the discharging box.
Preferably, the fuse box 9 is a cuboid box, and an inclined plane and a numerical control switch 10 are arranged in the fuse box 9.
An inclined plane and a numerical control switch 10 are arranged in the fuse box 9, and a detected part in the fuse box 9 automatically slides into the material receiving mechanism 4, so that the automatic detection and receiving of the part are realized, the labor intensity of an operator is reduced, and the fatigue operation of the operator is avoided.
Preferably, the image detector 6 is provided with a display screen.
As an embodiment, as shown in fig. 2, the sliding rail 8 of the sliding platform 5 comprises a first rail and a second rail, the first rail and the second rail are parallel to each other, and the fuse box 9 is located between the first rail and the second rail.
Preferably, first track and second track are parallel to each other, and fuse box 9 is located between first track and the second track, and fuse box 9 is good at gliding stability on the track, avoids the rocking problem that fuse box 9 arouses when sliding, improves the image definition, and then shortens test time.
Preferably, the discharge box is provided with an inclined plane, the inclined plane comprises a first inclined plate, a second inclined plate, a third inclined plate and a fourth inclined plate, the first inclined plate and the third inclined plate are opposite in position, the second inclined plate and the fourth inclined plate are opposite in position, and the first inclined plate, the second inclined plate, the third inclined plate and the fourth inclined plate form an inverted four-pyramid body.
Preferably, the connecting pipe of the material receiving pipeline and the material supplying pipeline is a hollow circular pipeline, the numerical control switch 10 is a circular switch, and the shapes of the numerical control switch 10, the material receiving pipeline and the material supplying pipeline are matched with each other.
The utility model has the advantages that: fuse check out test set installs feed mechanism, receiving mechanism and sliding platform, connects the material through feed mechanism's automatic feed and receiving mechanism's automation, realizes automatic image detection to reduce the cost of labor that detects, avoid the false retrieval and the hourglass of fuse to examine, effectively improve the mode that detects and improve detection efficiency. The safety box is internally provided with an inclined plane and a numerical control switch, and the detected part in the safety box automatically slides into the material receiving mechanism, so that the automatic detection and receiving of the part are realized, the labor intensity of an operator is reduced, and the fatigue operation of the operator is avoided. First track and second track are parallel to each other, and the fuse box is located between first track and the second track, and the fuse box is good at gliding stability on the track, and the problem of rocking that arouses when avoiding the fuse box to slide improves the image definition, and then shortens test time.
All patents and publications mentioned in the specification of the invention are indicative of the state of the art to which this invention pertains and of the technology disclosed herein as being applicable. All patents and publications cited herein are hereby incorporated by reference to the same extent as if each individual publication was specifically and individually indicated to be incorporated by reference. The invention described herein may be practiced in the absence of any element or elements, limitation or limitations, which limitation is not specifically disclosed herein. For example, in each of the examples herein the terms "comprising", "consisting essentially of", and "consisting of" may be substituted for the remaining 2 terms of either. The terms and expressions which have been employed herein are used as terms of description and not of limitation, and there is no intention in the use of such terms and expressions of excluding any equivalents of the features shown and described, but it is recognized that various modifications and changes may be made within the scope of the invention and the claims which follow. It is to be understood that the embodiments described herein are preferred embodiments and features and that modifications and variations may be made by one skilled in the art in light of the teachings of the present disclosure, and are to be considered within the purview of this disclosure and scope of the invention as defined by the appended claims and the independent claims.
Claims (8)
1. A fuse continuous detection device is characterized in that: the image detection device comprises a base, a shell, a feeding mechanism, a receiving mechanism, a sliding platform, an image detector and a numerical control device, wherein the shell is fixedly connected with the base, the sliding platform is fixedly arranged on the base, the receiving mechanism is positioned below the sliding platform, the image detector and the feeding mechanism are fixedly arranged on the shell, the image detector is positioned right above the sliding platform, the feeding mechanism is positioned on the side edge of the image detector, the numerical control device is arranged on the other side edge of the image detector, the feeding mechanism and the receiving mechanism are respectively positioned at two ends of the shell, the sliding platform comprises a sliding rail and a fuse box, the fuse box is placed on the sliding rail, the fuse box is a cuboid box, the bottom plate of the fuse box is in sliding type matching connection with the sliding rail, a numerical control switch is arranged on the bottom plate of the fuse box, the feeding mechanism is a cuboid box, a numerical control switch is arranged below the feeding mechanism, and the sliding platform are in signal connection with the numerical control device, the receiving mechanism is provided with a receiving pipeline, one end of the receiving pipeline is communicated with the bottom plate of the fuse box, and the other end of the receiving pipeline is communicated with the receiving mechanism.
2. A fuse continuity testing device according to claim 1, characterized in that: the feeding mechanism contain a discharging box, a numerical control switch and a feeding pipeline, the numerical control switch is located between the discharging box and the feeding pipeline, one end of the numerical control switch is communicated with the discharging box, and the other end of the numerical control switch is communicated with the feeding pipeline.
3. A fuse continuity testing device according to claim 2, characterized in that: the discharging box is a cuboid box, and an inclined plane is arranged in the discharging box.
4. A fuse continuity testing device according to claim 1, characterized in that: the fuse box is a cuboid box, and an inclined plane and a numerical control switch are arranged in the fuse box.
5. A fuse continuity testing device according to claim 1, characterized in that: the image detector is provided with a display screen.
6. A fuse continuity testing device according to claim 1, characterized in that: the slide rail of the sliding platform comprises a first rail and a second rail, the first rail and the second rail are parallel to each other, and the fuse box is located between the first rail and the second rail.
7. A fuse continuity testing device according to claim 2, characterized in that: the discharging box is provided with an inclined plane, the inclined plane is composed of a first inclined plate, a second inclined plate, a third inclined plate and a fourth inclined plate, the first inclined plate and the third inclined plate are opposite in position, the second inclined plate and the fourth inclined plate are opposite in position, and the first inclined plate, the second inclined plate, the third inclined plate and the fourth inclined plate form an inverted four-pyramid body.
8. A fuse continuity testing device according to claim 1, characterized in that: the connecting pipe of the material receiving pipeline and the material feeding pipeline is a hollow circular pipeline, the numerical control switch is a circular switch, and the shapes of the numerical control switch, the material receiving pipeline and the material feeding pipeline are matched with each other.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
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CN202023283160.1U CN214372592U (en) | 2020-12-30 | 2020-12-30 | Fuse continuous detection equipment |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
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CN202023283160.1U CN214372592U (en) | 2020-12-30 | 2020-12-30 | Fuse continuous detection equipment |
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CN214372592U true CN214372592U (en) | 2021-10-08 |
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CN202023283160.1U Active CN214372592U (en) | 2020-12-30 | 2020-12-30 | Fuse continuous detection equipment |
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2020
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