CN220334011U - Sleeve transferring device of sleeve detection equipment - Google Patents

Abstract

The utility model discloses a sleeve transfer device of sleeve detection equipment, which comprises a conveying part and a feeding part, wherein the conveying part is used for conveying a sleeve to a sleeve; the conveying part comprises a conveying space, and the conveying space is provided with a conveying inlet; the feeding part comprises a feeding space, and a feeding outlet is arranged in the feeding space; the feeding space is not communicated with the conveying space, so that the sleeve in the conveying space is not influenced when conveyed in the feeding space, and the sleeve conveying device can be more stable when conveyed; the conveying part comprises a conveying device for pushing the sleeve to move in the conveying space, and the conveying device is provided with a conveying pushing block for pushing the sleeve; the feeding part comprises a feeding device, and a feeding pushing block is arranged on the feeding device and is provided with a movable path for pushing the sleeve to the feeding pushing block; avoid only carrying the sleeve pipe through conveyor, prevent that the sleeve pipe is more and its weight is great when carrying space and pay-off space are longer, and conveyor can't be effectual and quick carry the sleeve pipe, causes detection efficiency lower.

Description

Sleeve transferring device of sleeve detection equipment

Technical Field

The utility model relates to the field of design and manufacture of detection equipment, in particular to a sleeve transfer device of sleeve detection equipment.

Technical Field

The sleeve is a pipeline or iron ring with a protective function; the sleeve is widely applied to construction sites and building sites, constructors imbed the sleeve into a wall body or underground in advance, and then penetrate other line pipelines such as water pipes or wires into the sleeve, so that the sleeve plays a role in protection.

Because the application range of the sleeve is wide, the sleeve is in great demand and needs mass production; the sleeve can be delivered only by quality detection after production is completed; the quality inspection workload is huge, and for this reason, people usually adopt automatic detection equipment to detect the sleeve so as to accelerate the detection efficiency; in the inspection apparatus, the speed of conveying the inspection product and whether the inspection product can be stabilized have a critical influence on the inspection speed.

Disclosure of Invention

The utility model provides a sleeve transfer device of sleeve detection equipment, which is efficient and stable.

The technical scheme of the utility model is as follows:

a sleeve transfer device of sleeve detection equipment comprises a detection device, a conveying part for conveying the sleeve to the detection device and a feeding part for conveying the sleeve to the conveying part; the conveying part comprises a conveying space, and the conveying space is provided with a conveying inlet for the sleeve to enter; the feeding part comprises a feeding space, and the feeding space is provided with a feeding outlet for the sleeve to leave; the sleeve detection equipment further comprises a base, and the detection device and the conveying part are arranged on the base; the feeding space is not communicated with the conveying space; the conveying part comprises a conveying device for pushing the sleeve to move in the conveying space, the conveying device is provided with a conveying pushing block for pushing the sleeve, the conveying pushing block is arranged outside the conveying space, and the conveying inlet is positioned on the moving path of the conveying pushing block; the feeding part comprises a feeding device, and a feeding pushing block is arranged on the feeding device and is provided with a movable path for pushing the sleeve to the feeding pushing block.

Further, concave spaces are formed on the surfaces of the feeding pushing block and the conveying pushing block, which are in contact with the sleeve; the feeding pushing block and the conveying pushing block are respectively provided with a conveying opening for the sleeve to enter and exit the concave space; the conveying opening of the conveying pushing block is arranged towards the conveying inlet, and the conveying opening of the conveying pushing block is arranged towards the movable path of the conveying pushing block.

Further, a sleeve inlet is formed in one side of the feeding push block corresponding to the feeding outlet and one side of the conveying push block corresponding to the feeding push block, so that the sleeve can enter the concave space of the feeding push block and the conveying push block.

Further, one end of the feeding part, provided with a feeding outlet, is abutted to the base; a blocking block is arranged on the base and is opposite to the feeding outlet; a transition area is formed between the feeding outlet and the blocking block, and the transition area and the conveying inlet are positioned on the same straight line.

Further, the transition area is positioned on the movable path of the feeding pushing block; the transition area is in the same straight line with the movable paths of the conveying inlet and the feeding pushing block.

Further, the feeding space and the conveying space are both in a straight line shape; the feeding space and the conveying space are parallel to each other and are positioned in different straight lines; the transition area is mutually perpendicular to the feeding space and the conveying space; the movable path of the feeding pushing block is perpendicular to the movable path of the conveying pushing block.

Further, a gap is formed in the side wall of one end of the conveying inlet of the conveying space, and the conveying space is communicated with the transition area through the gap.

Furthermore, the feeding space is obliquely arranged, one end of the feeding inlet is a high point, and one end of the feeding outlet is a low point.

The beneficial effects are that: in the utility model, the feeding space is not communicated with the conveying space, so that the sleeve in the conveying space is not influenced when conveyed in the feeding space, and the sleeve conveying device can be more stable when conveyed; the conveying device and the feeding device are respectively arranged, so that the problem that the detection efficiency is low due to the fact that the conveying device can only convey the sleeve through the conveying device, and further, when the conveying space and the feeding space are long, the sleeve is more and the weight of the sleeve is large, and the conveying device cannot effectively and rapidly convey the sleeve.

In the utility model, the conveying pushing block is arranged outside the conveying space, and the conveying pushing block does not need to enter the conveying space, so that the structure of the conveying pushing block does not need to be arranged according to the shape of the conveying space, and the structure of the conveying pushing block is simpler.

In the utility model, when the feeding push block and the conveying push block are contacted with the sleeve, the sleeve is positioned in the concave space, so that the feeding push block and the conveying push block can push the sleeve more stably; the conveying opening of the conveying pushing block is arranged towards the conveying inlet, the conveying opening of the conveying pushing block is arranged towards the movable path of the conveying pushing block, and the sleeve is sequentially conveyed into the conveying space through the cooperation of the conveying pushing block and the conveying pushing block.

In general, in the process of transferring a pushed object between two movable devices, one device is required to push the pushed object onto the movable path of the other device, and then the other device can continue pushing the object; therefore, when the two devices work, the two devices need to move sequentially, so that interference between the two devices or interference between the pushed object and the two devices can be avoided, and the efficiency of transferring the object between the two devices is lower. According to the utility model, through the arrangement of the sleeve inlet, the sleeve can enter the concave space of the feeding push block and the conveying push block through the sleeve inlet, so that the feeding push block and the conveying push block can simultaneously and movably transfer and convey the sleeve; in addition, physical interference between the feeding push block and the conveying push block or between the sleeve and the feeding push block and the conveying push block is avoided in the process of transferring and conveying the sleeve; thereby improving the efficiency of the utility model in transferring and delivering the cannula.

In the utility model, one end of the feeding part, which is provided with the feeding outlet, is abutted against the base; a blocking block is arranged on the base and is opposite to the feeding outlet; the movement of the sleeve reaching the base is limited by the blocking block, so that excessive movement of the sleeve in the feeding space when reaching the base is avoided, and the sleeve cannot be fed to the conveying inlet by the feeding device; so that the utility model can more stably carry out the sleeve transportation.

In the utility model, the transition area is positioned on the movable path of the feeding pushing block; the transition area is in the same straight line with the movable paths of the conveying inlet and the feeding pushing block; the structure of the feeding device can be more concise, and the feeding pushing block can be driven to realize linear movement.

In the utility model, the movable path of the feeding pushing block is perpendicular to the movable path of the conveying pushing block, so that the length of the transition area is in the shortest state, and the feeding pushing block is beneficial to rapidly conveying the sleeve to the conveying inlet.

In the utility model, the side wall of the conveying space, which is provided with one end of the conveying inlet, is provided with the notch, and the conveying space is communicated with the transition area through the notch, so that the sleeve can enter the conveying inlet of the conveying space from the side surface of the conveying part, and the interference between the feeding push block and the sleeve and the conveying push block is avoided, and the conveying of the sleeve is influenced.

In the utility model, the feeding space is obliquely arranged, one end of the feeding inlet is a high point, and one end of the feeding outlet is a low point; so that the sleeve can slide to a lower feeding outlet under the action of self gravity after entering the feeding space from the feeding inlet; the structure of the utility model is simpler; meanwhile, a pushing device for pushing the sleeve to move in the feeding space can be omitted from being arranged on the feeding part, so that the cost of the utility model is lower.

Drawings

FIG. 1 is a cross-sectional view of the entire present utility model.

Fig. 2 is a block diagram of the bottom of the base.

Fig. 3 is a structural view of the adjusting device, the feeding device and the conveying part arranged on the base.

Fig. 4 is a block diagram of the unassembled adjustment device of fig. 3.

Fig. 5 is a structural view of the feeding portion.

Fig. 6 is a structural view of the feed pusher.

Fig. 7 is a state diagram of the transport pusher.

Reference numerals in the drawings:

1. a base; 2. a conveying section; 3. an adjusting device; 4. a detection device; 5. a feeding part; 6. a blocking piece; 7. a master control device; 11. a discharge passage; 12. an assembly space; 13. a cushion block; 21. a conveying space; 22. a conveying device; 31. a movable block; 32. a pushing block; 51. a feeding space; 52. a feeding device; 61. a transition region; 101. a concave space; 102. a delivery opening; 103. a cannula inlet; 211. a delivery inlet; 212. a delivery outlet; 213. a notch; 214. a left baffle; 215. a right baffle; 221. a conveying cylinder; 222. conveying the pushing block; 511. a feed inlet; 512. a feed outlet; 521. and feeding the pushing block.

Detailed Description

The utility model will be further described with reference to the drawings and specific examples. It should be noted that the examples are only specific to the present utility model and are for the purpose of better understanding of the technical solutions of the present utility model to those skilled in the art, and should not be construed as limiting the present utility model.

In the description of the present utility model, it should be noted that, as the terms "center," "upper," "lower," "left," "right," "vertical," "horizontal," "inner," "outer," and the like are used for convenience of description and simplicity of description, only as to the orientation or positional relationship shown in the drawings, and not as an indication or suggestion that the apparatus or element in question must have a specific orientation, be constructed and operated in a specific orientation, and thus should not be construed as limiting the utility model.

In the description of the present utility model, it should be noted that unless explicitly stated and limited otherwise, the terms "mounted," "connected," and "connected" should be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communication between two elements. The specific meaning of the above terms in the present utility model will be understood in specific cases to those skilled in the art.

Example 1: as shown in fig. 1 and 3 to 7, a casing transfer device of a casing inspection apparatus includes an inspection device 4, a conveying section 2 that conveys a casing to the inspection device 4, and a feeding section 5 that conveys the casing to the conveying section 2; the conveying part 2 comprises a conveying space 21, and the conveying space 21 is provided with a conveying inlet 211 for the sleeve to enter; the feeding part 5 comprises a feeding space 51, and the feeding space 51 is provided with a feeding outlet 512 for the sleeve to leave; the sleeve detection equipment further comprises a base 1, and the detection device 4 and the conveying part 2 are arranged on the base 1; the feeding space 51 is not communicated with the conveying space 21, so that the sleeve in the conveying space 21 is not influenced when conveyed in the feeding space 51, and the sleeve conveying device can be more stable when conveyed; the conveying part 2 comprises a conveying device 22 for pushing the sleeve to move in the conveying space 21, and the conveying device 22 is provided with a conveying pushing block 222 for pushing the sleeve; the conveying pushing block 222 is arranged outside the conveying space 21, and the conveying inlet 211 is positioned on the movable path of the conveying pushing block 222; the conveying pushing block 222 is arranged outside the conveying space 21, and the conveying pushing block 222 does not need to enter the conveying space 21, so that the structure of the conveying pushing block 222 does not need to be arranged according to the shape of the conveying space 21, and the structure of the conveying pushing block is simpler; the feeding part 5 comprises a feeding device 52, and a feeding pushing block 521 is arranged on the feeding device 52 and has a movable path for pushing the sleeve to the conveying pushing block 222; the conveying device 22 and the feeding device 52 are respectively arranged, so that the utility model can avoid that the conveying device 22 only conveys the sleeve, and further, when the conveying space 21 and the feeding space 51 are longer, the sleeve is more and the weight is larger, and the conveying device 22 can not effectively and rapidly convey the sleeve, so that the detection efficiency is lower.

In this embodiment, the surfaces of the feeding pushing block 521 and the conveying pushing block 222, which are in contact with the sleeve, are provided with concave spaces 101; and the feeding pushing block 521 and the conveying pushing block 222 are respectively provided with a conveying opening 102 for the sleeve to enter and exit the concave space 101; the conveying opening 102 of the conveying pushing block 222 is arranged towards the conveying inlet 211, and the conveying opening 102 of the conveying pushing block 521 is arranged towards the movable path of the conveying pushing block 222; when the feeding push block 521 and the conveying push block 222 are in contact with the sleeve, the sleeve is positioned in the concave space 101, so that the feeding push block 521 and the conveying push block 222 can push the sleeve more stably; the delivery opening 102 of the delivery pusher 222 is disposed toward the delivery inlet 211, and the delivery opening 102 of the delivery pusher 521 is disposed toward the movable path of the delivery pusher 222, so that the bushings are sequentially fed into the delivery space 21 by the cooperation of the delivery pusher 521 and the delivery pusher 222.

In general, in the process of transferring a pushed object between two movable devices, one device is required to push the pushed object onto the movable path of the other device, and then the other device can continue pushing the object; therefore, when the two devices work, the two devices need to move sequentially, so that interference between the two devices or interference between the pushed object and the two devices can be avoided, and the efficiency of transferring the object between the two devices is lower. In this embodiment, a sleeve inlet 103 is provided on one side of the feeding pusher 521 corresponding to the feeding outlet 512 and one side of the conveying pusher 222 corresponding to the feeding pusher 521, so that a sleeve can enter the concave spaces 101 of the feeding pusher 521 and the conveying pusher 222; through the arrangement of the sleeve inlet 103, the sleeve can enter the concave space 101 of the feeding push block 521 and the conveying push block 222 through the sleeve inlet 103, so that the feeding push block 521 and the conveying push block 222 can simultaneously and movably transfer and convey the sleeve; and avoids physical interference between the feeding pusher 521 and the conveying pusher 222 or between the casing and the feeding pusher 521 and the conveying pusher 222 in the process of transferring and conveying the casing; thereby improving the efficiency of the utility model in transferring and delivering the cannula.

In the present embodiment, one end of the feeding portion 5, where the feeding outlet 512 is provided, is abutted against the base 1; a blocking block 6 is arranged on the base 1, and the blocking block 6 is arranged opposite to the feeding outlet 512; further, the movement of the sleeve reaching the base 1 is limited by the blocking block 6, so that the sleeve in the feeding space 51 is prevented from moving excessively when reaching the base 1, and cannot be sent to the conveying inlet 211 by the feeding device 52; the utility model can more stably carry out the conveying of the sleeve; the transition region 61 is formed between the feeding outlet 512 and the blocking block 6, and the transition region 61 and the conveying inlet 211 are on the same straight line, so that the interference between the feeding portion 5 and the conveying pushing block 222 and the influence on the activity can be avoided when the feeding portion 5 sends the sleeve to the conveying space 21 for detection.

In this embodiment, the transition region 61 is in the active path of the feed pusher 521; the transition region 61 is collinear with the movement path of the feed inlet 211 and the feed pusher 521; the structure of the feeding device 52 can be more concise, and the feeding pushing block 521 can be driven to realize linear movement.

In this embodiment, the feeding space 51 and the conveying space 21 are both linear; the feeding space 51 and the conveying space 21 are parallel to each other and are in different straight lines; the transition region 61 is perpendicular to the feed space 51 and the transport space 21; the moving paths of the feeding pushing block 521 and the moving path of the conveying pushing block 222 are perpendicular to each other, so that the length of the transition area 61 is in the shortest state, which is beneficial for the feeding pushing block 521 to quickly send the sleeve to the conveying inlet 211.

In this embodiment, a gap 213 is provided on a side wall of the conveying space 21 at one end of the conveying inlet 211, and the conveying space 21 is communicated with the transition region 61 through the gap 213, so that the sleeve can enter the conveying inlet 211 of the conveying space 21 from the side surface of the conveying part 2, and interference between the feeding push block 521 and the sleeve and the conveying push block 222 is avoided, and conveying of the sleeve is affected.

In this embodiment, the feeding space 51 is obliquely arranged, the feeding inlet 511 is located at a high point, and the feeding outlet 512 is located at a low point; so that the sleeve can slide to the lower feeding outlet 512 under the action of gravity after entering the feeding space 51 from the feeding inlet 511; the structure of the utility model is simpler; meanwhile, a pushing device for pushing the sleeve to move in the feeding space 51 can be omitted from being arranged on the feeding part 5, so that the cost of the utility model is lower.

In the embodiment, the device comprises a master control device 7, wherein the conveying device 22 and the feeding device 52 are connected with the master control device 7, and the cooperation between the conveying device 22 and the feeding device 52 is controlled by the master control device 7; and the whole device is more automatic, so that the device can operate more efficiently and stably.

Example 2: as shown in fig. 1 to 7, a cannula test device comprises a base 1 and a delivery part 2; the conveying part 2 comprises a conveying space 21 for conveying the sleeve and a conveying device 22 for pushing the sleeve to move in the conveying space 21; the conveying space 21 is arranged on the base 1; the base 1 is provided with a discharge channel 11 penetrating the base, an inlet of the discharge channel 11 is communicated with the bottom of the conveying space 21, and the inner diameter of the discharge channel 11 is larger than the diameter of the sleeve; so that the sleeve which does not meet the requirements can leave the conveying space 21 through the discharge through hole, and the screening work of the sleeve is completed; the base 1 is provided with an assembling space 12 communicated with the discharge channel 11; the base 1 is also provided with an adjusting device 3, and the adjusting device 3 is provided with an adjustable movable block 31; the movable block 31 is arranged in the assembly space 12, and the discharge channel 11 is positioned on the movable path of the movable block 31, so that the discharge channel 11 can be closed by the movement of the movable block 31, and further, the sleeve meeting the requirements is prevented from falling into the discharge through hole; so that the utility model can screen out unqualified sleeves from the utility model more efficiently by the movement of the movable block 31 only.

It is worth noting that the inner diameter of the discharge channel 11 itself and the inner diameter at the inlet of the discharge channel 11 must be greater than or equal to the diameter of the cannula.

In the present embodiment, the upper surface of the movable block 31 is in the same plane as the bottom surface of the conveying space 21; so that the sleeve can smoothly pass through the inlet of the discharge passage 11 when the movable block 31 closes the discharge passage 11; and prevents the sleeve from moving through the movable block 31.

In the present embodiment, the detecting means 4 is included; the top of the output space is provided with an opening, and the detection device 4 is arranged above the conveying space 21; the detection device 4 can clearly and completely detect the sleeve.

In this embodiment, two ends of the conveying space 21 are respectively provided with a conveying inlet 211 and a conveying outlet 212, so that the sleeve can enter and exit the conveying space 21; the detection means 4 are located between the delivery inlet 211 and the discharge channel 11, thereby enabling the present utility model to detect the cannula coming to the discharge channel 11; when the sleeve is not in accordance with the requirements, the movable block 31 is controlled to return to the assembly space 12, so that the sleeve which is not in accordance with the requirements falls into the discharge through hole; when the sleeve meets the requirements, the movable block 31 is controlled to be positioned in the discharge channel 11, so that the sleeve meeting the requirements stably passes through the discharge channel 11; furthermore, the utility model is more automatic, improves the detection and screening efficiency and simultaneously can reduce the error rate.

In the present embodiment, the outlet of the discharge passage 11 is provided at the lower surface of the base 1; and then make the sleeve pipe that accords with the requirement drop into the discharge through-hole after, can leave from the export of the discharge channel 11 of base 1 lower surface under the effort of self gravity, and then avoid a plurality of sleeve pipes to drop into the discharge through-hole and block up the discharge through-hole.

In the embodiment, a cushion block 13 is further arranged on the lower surface of the base 1, and the height of the cushion block 13 is greater than that of the sleeve; and then make the sleeve pipe leave the export of the discharge channel 11 of base 1 lower surface after, have sufficient space for people to take out the sleeve pipe from the below of discharge channel 11 export, further avoid blocking up the discharge through-hole.

In the present embodiment, the bottom of the movable block 31 is also provided with a pushing block 32; the pushing block 32 is located outside the discharge channel 11 and the assembly space 12, and by means of the arrangement of the pushing block 32, the movable block 31 can drive the pushing block 32 to move at the same time when resetting to seal the discharge channel 11, and push the sleeve below the channel outlet away from the position; the sleeve is prevented from accumulating below the channel outlet and blocking the discharge through hole; the horizontal height of the pushing block 32 is lower than the lower surface of the base 1, so that the pushing block 32 is prevented from physically interfering with the base 1 during movement, and the movement of the pushing block 32 is prevented from being influenced.

In this embodiment, the conveying device 22 includes a conveying cylinder 221, the conveying cylinder 221 is disposed on the base 1, a conveying pushing block 222 is disposed on a cylinder arm of the conveying cylinder 221, the conveying pushing block 222 is disposed outside the conveying space 21, and the conveying inlet 211 is located on a moving path of the conveying pushing block 222; therefore, the conveying pushing block 222 can push the sleeve without entering the conveying space 21, so that the conveying cylinder 221 and the conveying pushing block 222 are more convenient to arrange; meanwhile, the conveying pushing block 222 does not need to enter the conveying space 21, so that the structure of the conveying pushing block 222 does not need to be arranged according to the shape of the conveying space 21, and the structure of the utility model is simpler.

In the present embodiment, the feeding section 5 is further included, the feeding section 5 includes a feeding space 51, and the feeding space 51 is provided with a feeding inlet 511 and a feeding outlet 512; the feeding outlet 512 and the feeding inlet 211 are disposed in correspondence with each other, so that the bushings to be detected can be sequentially fed from the feeding space 51 to the feeding space 21.

In this embodiment, the feeding space 51 is obliquely arranged, and the feeding inlet 511 is located at a high point, and the feeding outlet 512 is located at a low point; so that the sleeve can slide to the lower feeding outlet 512 under the action of gravity after entering the feeding space 51 from the feeding inlet 511; the structure of the utility model is simpler; meanwhile, a pushing device for pushing the sleeve to move in the feeding space 51 can be omitted from being arranged on the feeding part 5, so that the cost of the utility model is lower.

In the present embodiment, one end of the feeding portion 5, where the feeding outlet 512 is provided, is abutted against the base 1; a blocking block 6 is arranged on the base 1, and the blocking block 6 is arranged opposite to the feeding outlet 512; further, the movement of the sleeve reaching the base 1 is limited by the blocking block 6, so that the sleeve in the feeding space 51 is prevented from moving excessively when reaching the base 1, and cannot be sent to the conveying inlet 211 by the feeding device 52; a transition area 61 is formed between the feeding outlet 512 and the blocking block 6, and the transition area 61 and the conveying inlet 211 are in the same straight line; the feeding part 5 comprises a feeding device 52, and a movable feeding pushing block 521 is arranged on the feeding device 52; the transition region 61 is on the active path of the feed pusher 521; the transition region 61 is collinear with the movement path of the feed inlet 211 and the feed pusher 521; by the arrangement and the matching of the transition area 61 and the feeding device 52, the feeding part 5 can be prevented from interfering with the conveying pushing block 222 to influence the activity in the process of conveying the sleeve to the conveying space 21 for detection; meanwhile, the utility model can also avoid that the conveying device 22 only conveys the sleeve, so that the sleeve is more and the weight is larger when the conveying space 21 and the feeding space 51 are longer, and the conveying device 22 can not effectively and rapidly convey the sleeve, so that the detection efficiency is lower.

In this embodiment, the feeding space 51 and the conveying space 21 are both linear; the feeding space 51 and the conveying space 21 are parallel to each other and are in different straight lines; thereby facilitating the feeding device 52 and the conveying device 22 and avoiding the interference of the feeding pushing block 521 and the conveying pushing block 222 when the feeding device 52 and the conveying device operate; and facilitates the setting of the blocking piece 6 and the formation of the transition region 61.

In this embodiment, the surfaces of the feeding pushing block 521 and the conveying pushing block 222 contacting the casing are provided with the concave space 101, and when the feeding pushing block 521 and the conveying pushing block 222 contact the casing, the casing is in the concave space 101, so that the feeding pushing block 521 and the conveying pushing block 222 can push the casing more stably; the feeding pushing block 521 and the conveying pushing block 222 are respectively provided with a conveying opening 102 with a concave space 101, and the conveying opening 102 is provided with a sleeve pipe to enable the feeding pushing block 521 and the conveying pushing block 222 to enter and exit the concave space 101, so that the feeding pushing block 521 and the conveying pushing block 222 can finish pushing work; the delivery opening 102 of the delivery pusher 222 is disposed toward the delivery inlet 211, and the delivery opening 102 of the delivery pusher 521 is disposed toward the movable path of the delivery pusher 222, so that the bushings are sequentially fed into the delivery space 21 by the cooperation of the delivery pusher 521 and the delivery pusher 222.

In general, in the process of transferring a pushed object between two movable devices, one device is required to push the pushed object onto the movable path of the other device, and then the other device can continue pushing the object; therefore, when the two devices work, the two devices need to move sequentially, so that interference between the two devices or interference between the pushed object and the two devices can be avoided, and the efficiency of transferring the object between the two devices is lower. In the present embodiment, a sleeve inlet 103 is provided on a side of the feeding pusher 521 corresponding to the feeding outlet 512 and a side of the conveying pusher 222 corresponding to the transition region 61, so that a sleeve enters the concave spaces 101 of the feeding pusher 521 and the conveying pusher 222; through the arrangement of the sleeve inlet 103, the sleeve can enter the concave space 101 of the feeding push block 521 and the conveying push block 222 through the sleeve inlet 103, so that the feeding push block 521 and the conveying push block 222 can simultaneously and movably transfer and convey the sleeve; and avoids physical interference between the feeding pusher 521 and the conveying pusher 222 or between the casing and the feeding pusher 521 and the conveying pusher 222 in the process of transferring and conveying the casing; and further, the efficiency of transferring and conveying the sleeve is improved, and the efficiency of detecting and screening unqualified sleeves is improved.

In this embodiment, a gap 213 is provided on a side wall of the conveying space 21 at one end of the conveying inlet 211, and the conveying space 21 is communicated with the transition region 61 through the gap 213, so that the sleeve can enter the conveying inlet of the conveying space 21 from the side surface of the conveying part 2, and interference between the feeding push block 521 and the sleeve and the conveying push block 222 is avoided, and conveying of the sleeve is affected.

In the present embodiment, the upper surface of the base 1 is provided with a left baffle 214 and a right baffle 215, and the conveying space 21 is formed by the cooperation of the left baffle 214 and the right baffle 215; the feeding space 51 is provided with a side close to the right baffle 215, and the corresponding opening 213 is provided on the right baffle 215; left baffle 214 and right baffle 215 pass through threaded connection's mode assembly at the upper surface of base 1 for the assembly of left baffle 214 and right baffle 215 is more convenient, and then makes the formation of conveying space 21 also more convenient. Meanwhile, as the left baffle 214 and the right baffle 215 are convenient to assemble, the inner diameter of the feeding space 51 can be correspondingly adjusted by adjusting the distance between the left baffle 214 and the right baffle 215 after being installed, and then the sleeves with different diameters can be detected and screened, so that the use environment of the feeding device is wider.

In the embodiment, the device comprises a master control device 7, wherein the conveying device 22, the adjusting device 3 and the feeding device 52 are connected with the master control device 7, and the coordination among the conveying device 22, the adjusting device 3 and the feeding device 52 is controlled by the master control device 7; therefore, the utility model is more automatic and is beneficial to improving the efficiency of detection and screening.

It should be noted that other technical solutions of the present utility model belong to the prior art, and are not described in detail.

The foregoing is merely a preferred embodiment of the present utility model, and it should be noted that modifications and adaptations to those skilled in the art may be made without departing from the concept of the present utility model, and such modifications and adaptations are intended to be comprehended within the scope of the present utility model.

Claims (8)

1. A sleeve transfer device of sleeve detection equipment comprises a detection device, a conveying part for conveying the sleeve to the detection device and a feeding part for conveying the sleeve to the conveying part; the conveying part comprises a conveying space, and the conveying space is provided with a conveying inlet for the sleeve to enter; the feeding part comprises a feeding space, and the feeding space is provided with a feeding outlet for the sleeve to leave; the sleeve detection equipment further comprises a base, and the detection device and the conveying part are arranged on the base; the feeding space is not communicated with the conveying space; the conveying part comprises a conveying device for pushing the sleeve to move in the conveying space, the conveying device is provided with a conveying pushing block for pushing the sleeve, the conveying pushing block is arranged outside the conveying space, and the conveying inlet is positioned on the moving path of the conveying pushing block; the feeding part comprises a feeding device, and a feeding pushing block is arranged on the feeding device and is provided with a movable path for pushing the sleeve to the feeding pushing block.

2. The cannula transfer device of the cannula detection apparatus of claim 1, wherein the surfaces of the feed pusher and the delivery pusher in contact with the cannula are each provided with a concave space; the feeding pushing block and the conveying pushing block are respectively provided with a conveying opening for the sleeve to enter and exit the concave space; the conveying opening of the conveying pushing block is arranged towards the conveying inlet, and the conveying opening of the conveying pushing block is arranged towards the movable path of the conveying pushing block.

3. The cannula transfer device of the cannula detection device of claim 2, wherein the side of the feed pusher corresponding to the feed outlet and the side of the delivery pusher corresponding to the feed pusher are both provided with cannula inlets for cannulas to enter the concave spaces of the feed pusher and the delivery pusher.

4. The cannula transfer device of the cannula detection apparatus of claim 1, wherein an end of the feeding portion where the feeding outlet is provided abuts the base; a blocking block is arranged on the base and is opposite to the feeding outlet; a transition area is formed between the feeding outlet and the blocking block, and the transition area and the conveying inlet are positioned on the same straight line.

5. A casing transfer device of a casing inspection apparatus according to claim 4, wherein the transition region is in the active path of the feed pusher; the transition area is in the same straight line with the movable paths of the conveying inlet and the feeding pushing block.

6. The cannula transfer device of the cannula detection apparatus of claim 5, wherein the feed space and the delivery space are both rectilinear; the feeding space and the conveying space are parallel to each other and are positioned in different straight lines; the transition area is mutually perpendicular to the feeding space and the conveying space; the movable path of the feeding pushing block is perpendicular to the movable path of the conveying pushing block.

7. The cannula transfer device of the cannula test apparatus of claim 6, wherein the delivery space is provided with a gap in a sidewall of the delivery inlet end through which the delivery space communicates with the transition region.

8. The cannula transfer device of the cannula detection apparatus of claim 1, wherein the feed space is sloped such that an end of the feed inlet is high and an end of the feed outlet is low.