CN111157181A - Continuous bottle inverting extrusion leakage detection system - Google Patents

Abstract

The invention provides a continuous inverted bottle extrusion leakage detection system, which comprises an extrusion mechanism, a detection mechanism and an inverted bottle conveying chain mechanism for guiding and conveying filled bottles, wherein the inverted bottle conveying chain mechanism is sequentially provided with an inverted bottle section, a detection section and a vertical bottle section along the conveying direction, bottles conveyed by a filling production line are continuously inverted in batches from an upright state to a horizontal state for a period of time by the inverted bottle conveying chain mechanism, then the bottles are stably returned to the upright state and transferred to the next production line, the extrusion mechanism is arranged on the horizontal conveying section to extrude the bottles, the detection mechanism shoots and detects the leakage condition of a bottle opening, and an unqualified bottle is removed by a removing mechanism, so that continuous leakage detection is realized in the conveying process, the operation among the working procedures is compact, the detection efficiency is high, the leakage can be concentrated at the bottle opening, the detection sensitivity is improved, and the problems of low detection efficiency, low leakage detection efficiency, low cost and the like in the prior art are solved, Easy to miss detection.

Description

Continuous bottle inverting extrusion leakage detection system

Technical Field

The invention relates to the field of leakage detection of filling bottles, in particular to a continuous inverted bottle extrusion leakage detection system.

Background

The leakage problem often occurs due to the problems of not tight sealing cover and the like after the PEP and other plastic bottles are filled, particularly for the filling of perishable beverages such as milk products or toxic liquids such as pesticides, if the plastic bottles are not sealed, such finished products are on the market or rapidly precipitate to deteriorate or leak out, thereby not only harming the health of consumers, but also bringing adverse effects to the brand image of enterprises. Therefore, before the bottled product leaves the factory, leakage detection is needed, and the conventional method is to extrude the bottle body and observe whether liquid leaks out.

Chinese patent application No. CN200420033002.2 discloses a plastic bottle leakage detecting extruder, which comprises a transmission mechanism and an extrusion mechanism, and is characterized in that: the extrusion mechanism comprises one or a plurality of extrusion rollers which are arranged side by side and driven by the transmission mechanism to rotate, the other side of the extrusion rollers opposite to each other is provided with a stressed support, a gap between each extrusion roller and the corresponding support is an extrusion rubbing space of the bottle, the bottle is horizontally laid in the extrusion rubbing space to be squeezed, the liquid splashing condition of the bottle body is observed in a matched manner, and the extrusion section is connected with the production line through the turnover cage.

However, in the above technical scheme, the filling bottles on the production line are turned over one by one and transferred to the extrusion section through the turning cage, and the bottles are extruded one by the extrusion mechanism, so that the detection efficiency is low; in addition, the manual observation mode is labor-intensive, and the missed detection is easy to occur especially for the condition of slight leakage.

Disclosure of Invention

In order to solve the problems, the invention provides a continuous inverted bottle extrusion leakage detection system, bottles transmitted by a filling production line are continuously and stably inverted from an upright state to a horizontal state in batches by arranging an inverted bottle conveying chain mechanism, are kept for a period of time and then are stably returned to the upright state for transfer output, an extrusion mechanism is arranged at the horizontal transmission section to extrude the bottles, and a detection mechanism is used for detecting leakage of the bottle mouth, so that continuous leakage detection is realized in the transmission process, the actions among the working procedures are compact, the detection efficiency is high, the leakage can be concentrated at the bottle mouth, the detection sensitivity is improved, and the technical problems of low detection efficiency and easy leakage detection in the prior art are solved.

In order to achieve the purpose, the invention provides the following technical scheme:

the utility model provides a continuous bottle-inverting extrusion system of leaking hunting, is including the bottle conveyor chain mechanism that is used for leading the bottle after the transmission filling and sets up extrusion mechanism and the detection mechanism on bottle transmission path, bottle conveyor chain mechanism has set gradually bottle inverting section, detection section and upright bottle section along its direction of transmission, extrusion mechanism and detection mechanism set up in detect the section, just detection mechanism is just under the state of lying the bottleneck setting of bottle, upright the bottle is by bottle inverting conveyor chain mechanism direction to the state of lying, after being extruded by extrusion mechanism and cooperation detection mechanism detects the bottleneck weeping condition, is exported to upright state by bottle inverting conveyor chain mechanism direction.

Preferably, the squeezing mechanism comprises a squeezing belt pulley, and the squeezing belt pulley is arranged along the transmission direction of the bottle inverting and conveying chain mechanism and is used for rolling and squeezing the bottle bodies of the bottles in a lying state.

Preferably, the bottle inverting and conveying mechanism comprises a conveying chain assembly and a rotary supporting chain plate assembly which run at the same speed, a plurality of groups of overturning guide assemblies are correspondingly clamped on the conveying chain assembly and the rotary supporting chain plate assembly between the bottle inverting section and the bottle erecting section, the conveying chain assembly and the rotary supporting chain plate assembly are kept in a relatively vertical state and are driven by the overturning guide assemblies to twist, and the bottles are sequentially inclined, laid, conveyed and inclined and erected.

Preferably, the turnover guide assembly is vertically arranged at the starting position of the bottle inverting section, the joint of the bottle inverting section and the detection section, the joint of the detection section and the bottle erecting section and the termination of the bottle erecting section, the turnover guide assembly connected with the transmission chain assembly is horizontally arranged at the starting position of the bottle inverting section and the termination of the bottle erecting section, and the turnover guide assembly connected with the transmission chain assembly is vertically arranged at the joint of the bottle inverting section and the detection section and the joint of the detection section and the bottle erecting section; the turnover guide assembly is respectively connected with the transmission chain assembly and one back side of the rotary support chain plate assembly in a clamping manner.

Preferably, the width of each of the single chain of the transmission chain assembly and the single chain plate of the rotary supporting chain plate assembly is adapted to the width of the bottle body of the bottle.

Preferably, the input front end and the output rear end of the bottle inverting and conveying chain mechanism are respectively provided with an auxiliary conveying chain mechanism, and a guide rail mechanism are respectively transitionally arranged between the auxiliary conveying chain mechanism and the input front end and the output rear end of the bottle inverting and conveying chain mechanism.

Preferably, the output rear end of the bottle inverting and conveying chain mechanism is further provided with a rejecting mechanism.

Preferably, the bottle-inverting conveying chain mechanism is installed on the frame, a detection door frame is arranged at the detection section outside the frame, and the extrusion mechanism is arranged inside the detection door frame in a lifting mode.

Preferably, the detection mechanism is arranged on the frame in a lifting manner and comprises a light source and a camera.

Preferably, a control host is installed outside the detection portal, and the control host is connected with the extrusion mechanism and the detection mechanism and controls the extrusion mechanism and the detection mechanism to operate.

The invention has the beneficial effects that:

(1) according to the invention, the bottles transmitted by the filling production line are continuously turned over from an upright state to a horizontal state in batches and are stably returned to the upright state to be transferred to the next production line after being kept for a period of time by arranging the bottle inverting conveying chain mechanism, the bottle bodies are extruded by arranging the extruding mechanism on the horizontal conveying section in a matched manner, the detection mechanism shoots to detect the leakage condition of the bottle opening, and the unqualified bottles are rejected by the rejection mechanism, so that continuous leakage detection in the transmission process is realized, the actions among the working procedures are compact, the detection efficiency is high, the leakage can be concentrated at the bottle opening, the detection sensitivity is improved, and the technical problems of low detection efficiency and easy leakage detection in the prior art are solved;

(2) in the invention, the bottle is placed upside down, the bottle mouth is filled with liquid, if liquid leaks, the bottle body is prevented from being damaged only by slight extrusion, and the leaked liquid can be concentrated at the bottle mouth in a lying state, so that the water quantity is larger, the leaked liquid can be easily photographed and found, and the detection sensitivity is improved;

(3) in the invention, the auxiliary conveying chain mechanisms are respectively arranged at the front input end and the rear output end of the bottle inverting conveying chain mechanism, and the guide rail mechanism are respectively arranged in a transition manner, so that the bottles on the filling production line are guided to the bottle inverting conveying chain mechanism through the guide rail mechanism to complete the bottle leakage detection, and then are guided to the auxiliary conveying chain mechanism through the guide rail mechanism to be transmitted to the next process, and the production continuity is improved.

In conclusion, the leakage detection device has the advantages of capability of continuously detecting leakage in batches, good production continuity, high detection efficiency and sensitivity and the like, and is particularly suitable for the field of leakage detection of filling bottles.

Drawings

FIG. 1 is a top view of the overall structure of the present invention;

FIG. 2 is a left side view of the detection section of the present invention;

FIG. 3 is a schematic view of the overall structure of the present invention;

FIG. 4 is an enlarged view taken at A in FIG. 1;

FIG. 5 is an enlarged view of FIG. 3 at D;

FIG. 6 is an enlarged view of FIG. 1 at B;

FIG. 7 is an enlarged view at C of FIG. 1;

FIG. 8 is a schematic view showing a leakage state of the bottle mouth when the squeezing mechanism squeezes.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

In the description of the present invention, it is to be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", and the like, indicate orientations and positional relationships based on those shown in the drawings, and are used only for convenience of description and simplicity of description, and do not indicate or imply that the equipment or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be considered as limiting the present invention.

Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of the present invention, "a plurality" means two or more unless specifically defined otherwise.

Examples

As shown in fig. 1-3, a continuous inverted bottle extrusion leakage detection system includes an inverted bottle conveying chain mechanism 3 for guiding and conveying filled bottles 10, and an extruding mechanism 1 and a detecting mechanism 2 which are arranged on a conveying path of the bottles 10, wherein the inverted bottle conveying chain mechanism 3 is sequentially provided with an inverted bottle section 100, a detecting section 200 and a bottle erecting section 300 along a conveying direction thereof, the extruding mechanism 1 and the detecting mechanism 2 are arranged in the detecting section 200, the detecting mechanism 2 is arranged right opposite to a bottle mouth of the bottles 10 in a flat lying state, the upright bottles 10 are guided to the flat lying state by the inverted bottle conveying chain mechanism 3, and are extruded by the extruding mechanism 1 and guided to the upright state by the inverted bottle conveying chain mechanism 3 after being matched with the detecting mechanism 2 to detect a leakage situation of the bottle mouth.

In this embodiment, the inverted bottle conveying chain mechanism 3 is arranged at the rear end of the filling line in a transition manner, bottles 10 conveyed by the filling line are stably inverted from an upright state to a flat lying state in batch and continuously in the inverted bottle section 100, enter the detection section 200, enter the upright bottle section 300 after the detection section 200 is laid down and kept for a period of time, stably return to the upright state and transfer to the next production line, and are matched with the flat lying transmission section, namely, the detection section 200 is provided with the extrusion mechanism 1 to extrude the bottles, and the detection mechanism 2 which is right opposite to the bottle mouth shoots and detects the leakage of the bottle mouth, and then unqualified bottles are rejected by the rejection mechanism 20, so that continuous leakage detection in the transmission process is realized, the actions among all the procedures are compact, the detection efficiency is high, and the leakage can be concentrated at the bottle mouth, and the detection sensitivity is.

It should be noted that, because the filling amount of the bottle is slightly smaller than the volume of the bottle, the bottle mouth of the bottle after filling is empty of liquid in the upright state, and if the bottle is squeezed in the upright state, the squeezing force required is larger and if there is a leakage, the leakage will flow down along the bottle body, and it is difficult to detect the leakage. In this embodiment, through laying down bottle 10, bottleneck department can be full of liquid, as shown in fig. 8, if there is the weeping, only need slightly squeeze can, avoid damaging the bottle, and the weeping can concentrate in bottleneck department under the state of lying, and the water yield is bigger, is shot the discovery more easily to improve detectivity.

Preferably, as shown in fig. 4, the pressing mechanism 1 includes a pressing pulley 11, and the pressing pulley 11 is disposed along the conveying direction of the bottle inverting conveyor chain mechanism 3 and performs rolling pressing on the body of the lying bottle 10.

In this embodiment, the squeezing pulley 11 is driven by a motor to rotate and is arranged along the conveying direction of the bottle inverting and conveying chain mechanism 3, and the bottom of the squeezing pulley can slightly interfere with the lying bottle body to perform batch rolling squeezing on the bottles 10 conveyed by continuous lying.

Preferably, as shown in fig. 2 and 5, the inverted bottle conveying chain mechanism 3 includes a conveying chain assembly 31 and a rotating support chain plate assembly 32 which run at the same speed, a plurality of groups of turning guide assemblies 33 are correspondingly clamped on the conveying chain assembly 31 and the rotating support chain plate assembly 32 between the inverted bottle section 100 and the bottle erecting section 300, and the conveying chain assembly 31 and the rotating support chain plate assembly 32 are kept in a relatively vertical state and are driven by the turning guide assemblies 33 to twist, so as to sequentially tilt, lay down and tilt the bottles 10.

In this embodiment, the chain assembly 31 and the rotating support chain plate assembly 32 are arranged side by side, the turning guide assembly 33 is respectively clamped on the chain assembly 31 and the rotating support chain plate assembly 32 to twist the chain assembly 31 and the rotating support chain plate assembly 32, and the arrangement position of the turning guide assembly 33 enables the chain assembly 31 and the rotating support chain plate assembly 32 between the bottle inverting section 100 and the bottle erecting section 300 to be always in a relatively vertical state, the chain assembly 31 is smoothly twisted from a horizontal state to a vertical state in the bottle inverting section 100, correspondingly, the rotating support chain plate assembly 32 is smoothly twisted from a vertical state to a horizontal state, and the bottle erecting section 300 is reversely twisted relative to the bottle inverting section 100, so that the bottles are stably inverted from the vertical state to a lying state and from the lying state to the vertical state in the conveying process.

Preferably, the turning guide assemblies 33 are respectively and vertically arranged at the starting position of the bottle inverting section 100, the joint position of the bottle inverting section 100 and the detection section 200, the joint position of the detection section 200 and the bottle erecting section 300 and the end position of the bottle erecting section 300 in pairs, the turning guide assemblies 33 connected with the conveying chain assembly 31 are horizontally arranged at the starting position of the bottle inverting section 100 and the end position of the bottle erecting section 300, and the turning guide assemblies 33 connected with the conveying chain assembly 31 are vertically arranged at the joint position of the bottle inverting section 100 and the detection section 200 and the joint position of the detection section 200 and the bottle erecting section 300; the turnover guide assembly 33 is engaged with the back surfaces of the transmission chain assembly 31 and the rotary support chain plate assembly 32.

It should be noted that, in this embodiment, the turning guide assemblies 33 are arranged in pairs and vertically in groups to form four groups, and by respectively arranging one group at the joint of the detection section 200 and the joint of the bottle inverting section 100 and the detection section 200, the transmission chain assembly 31 in the lying state is smoothly guided to the vertical state, and meanwhile, the rotation support chain assembly 32 in the vertical state is smoothly guided to the lying state; by respectively arranging a group at the joint of the detection section 200 and the bottle erecting section 300 and the termination of the bottle erecting section 300, the transmission chain assembly 31 in the vertical state is smoothly restored to the lying state, and meanwhile, the rotation support chain plate assembly 32 in the lying state is smoothly restored to the vertical state.

Preferably, the width of each of the individual chains of the conveying chain assembly 31 and the individual links of the pivoting support link assembly 32 is adapted to the width of the body of the bottle 10.

In this embodiment, since the bottles 10 are turned gradually during the conveying process, the widths of the single chains of the conveying chain assembly 31 and the single chain plates of the rotary supporting chain plate assembly 32 are both set to be suitable for the width of the bottle body of the bottle 10, so that the bottles 10 are prevented from shaking back and forth during the conveying and turning process, and the conveying stability is ensured.

As shown in fig. 6-7, the input front end and the output rear end of the bottle inverting conveying chain mechanism 3 are respectively provided with an auxiliary conveying chain mechanism 4, and an introduction rail mechanism 5 and an exit rail mechanism 6 are respectively transitionally arranged between the auxiliary conveying chain mechanism 4 and the input front end and the output rear end of the bottle inverting conveying chain mechanism 3.

In this embodiment, the auxiliary conveying chain mechanisms 4 are respectively arranged at the front input end and the rear output end of the bottle inverting conveying chain mechanism 3, and the guide rail mechanism 5 and the guide rail mechanism 6 are respectively arranged in a transitional manner, so that bottles filled in the filling production line are conveyed by the auxiliary conveying chain mechanism 4 at the front end, guided to the chain assembly 31 through the guide rail mechanism 5, further detected for missing bottles, guided to the auxiliary conveying chain mechanism 4 at the rear end through the guide rail mechanism 6, and conveyed to the next process, and the production continuity is improved.

Preferably, the output rear end of the bottle inverting conveying chain mechanism 3 is further provided with a rejecting mechanism 20.

In this embodiment, the rejecting mechanism 20 is disposed at the rear end of the rail guiding mechanism 6 and is controlled by the control host 9 to operate, when the detected bottles 10 are guided by the rail guiding mechanism 6 to enter the auxiliary conveying chain mechanism 4, the rejecting mechanism 20 receives a signal to reject the unqualified bottles 10, and correspondingly, a receiving hopper is further disposed at the rear end of the output for receiving the unqualified bottles 10.

It should be noted that the removing mechanism 20 adopted in this embodiment may adopt a structure such as air blowing or cylinder side pushing, which are common technical means in the art, and the detailed mechanism thereof is not described again.

Preferably, as shown in fig. 3, the bottle inverting and conveying mechanism further comprises a frame 7, the bottle inverting and conveying chain mechanism 3 is installed on the frame 7, a detection door frame 8 is arranged outside the frame 7 and at the detection section 200, and the squeezing mechanism 1 is arranged inside the detection door frame 8 in a lifting manner.

Preferably, the detection mechanism 2 is installed on the frame 7 in a lifting manner, and includes a light source and a camera.

Preferably, a control host machine 9 is installed outside the detection portal frame 8, and the control host machine 9 is connected with the extrusion mechanism 1 and the detection mechanism 2 and controls the operation of the extrusion mechanism 1 and the detection mechanism 2.

The working process is as follows:

when the bottle-pouring and conveying device works, an operator drives the bottle-pouring and conveying chain mechanism 3 and the auxiliary conveying chain mechanism 4 to operate through the control host machine 9, bottles 10 which are filled on a filling production line are transmitted by the auxiliary conveying chain mechanism 4 at the front end and are guided to the chain assembly 31 through the guide-in rail mechanism 5, after the bottle inverting section 100 is continuously and steadily inverted from the upright state to the flat state in batch, the bottle inverting section enters the detecting section 200 and keeps the flat state for a period of time of transmission, the bottle bodies are extruded by the extruding mechanism 1 in the process again, the detection mechanism 2 arranged right opposite to the bottle mouth shoots and detects the leakage condition of the bottle mouth and feeds the leakage condition back to the control host machine 9, after the detection is finished, the bottles 10 enter the bottle standing section 300 and are stably restored to be in a vertical state, and then are guided to the auxiliary conveying chain mechanism 4 at the rear end through the guide-out rail mechanism 6, the rejecting mechanism 20 receives signals of the control host machine 9 to reject unqualified bottles, and the qualified bottles are transmitted to the next procedure.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the invention, and any modifications, equivalents and improvements made within the spirit and principle of the present invention are intended to be included within the scope of the present invention.

Claims (10)

1. A continuous bottle inverting extrusion leakage detection system comprises an inverted bottle conveying chain mechanism (3) for guiding and conveying filled bottles (10), an extrusion mechanism (1) and a detection mechanism (2) which are arranged on a conveying path of the bottles (10), it is characterized in that the bottle inverting and conveying chain mechanism (3) is sequentially provided with a bottle inverting section (100), a detecting section (200) and a bottle erecting section (300) along the conveying direction, the extrusion mechanism (1) and the detection mechanism (2) are arranged on the detection section (200), and the detection mechanism (2) is arranged right opposite to the bottle mouth of the bottle (10) in the lying state, the bottle (10) which is upright is guided to the lying state by the bottle reversing conveying chain mechanism (3), and is extruded by the extrusion mechanism (1) and matched with the detection mechanism (2) to detect the leakage condition of the bottle mouth, and then the bottle is guided to the upright state by the bottle reversing conveying chain mechanism (3) to be output.

2. The continuous bottle inverting extrusion leak detection system according to claim 1, wherein the extrusion mechanism (1) comprises an extrusion pulley (11), the extrusion pulley (11) is arranged along the transmission direction of the bottle inverting conveying chain mechanism (3) and is used for rolling and extruding the bottle bodies of the bottles (10) in a lying state.

3. The continuous inverted bottle extrusion leak detection system according to claim 1, wherein the inverted bottle conveying chain mechanism (3) comprises a conveying chain assembly (31) and a rotary supporting chain plate assembly (32) which run at the same speed, a plurality of groups of turning guide assemblies (33) are correspondingly clamped on the conveying chain assembly (31) and the rotary supporting chain plate assembly (32) between the inverted bottle section (100) and the bottle erecting section (300), the conveying chain assembly (31) and the rotary supporting chain plate assembly (32) are kept in a relatively vertical state, and are driven by the turning guide assemblies (33) to twist, so as to sequentially tilt, lay, convey and tilt the bottles (10).

4. The continuous inverted bottle squeezing leak detection system according to claim 3, wherein the inversion guide assembly (33) is vertically disposed at the beginning of the inverted bottle section (100), the junction of the inverted bottle section (100) and the detection section (200), the junction of the detection section (200) and the bottle erecting section (300), and the end of the bottle erecting section (300), and the inversion guide assembly (33) connected to the transmission chain assembly (31) is horizontally disposed at the beginning of the inverted bottle section (100) and the end of the bottle erecting section (300), and the inversion guide assembly (33) connected to the chain transmission assembly (31) is vertically disposed at the junction of the inverted bottle section (100) and the detection section (200) and the junction of the detection section (200) and the bottle erecting section (300).

5. A continuous inverted bottle squeeze leak detection system as claimed in claim 3 wherein the width of the individual chains of the conveyor chain assembly (31) and the individual links of the pivoting support link assembly (32) are each adapted to the body width of the bottles (10).

6. The continuous bottle inverting extrusion leakage detection system according to claim 1, wherein the input front end and the output rear end of the bottle inverting conveying chain mechanism (3) are respectively provided with an auxiliary conveying chain mechanism (4), and the auxiliary conveying chain mechanism (4) and the input front end and the output rear end of the bottle inverting conveying chain mechanism (3) are respectively transitionally provided with an introducing rail mechanism (5) and an exiting rail mechanism (6).

7. The continuous inverted bottle extrusion leakage detection system according to claim 6, wherein the inverted bottle conveying chain mechanism (3) is further provided with a rejecting mechanism (20) at the rear output end.

8. The continuous bottle inverting extrusion leakage detection system according to claim 1, further comprising a frame (7), wherein the bottle inverting conveying chain mechanism (3) is installed on the frame (7), a detection door frame (8) is arranged outside the frame (7) and located at the detection section (200), and the extrusion mechanism (1) is arranged inside the detection door frame (8) in a lifting mode.

9. The continuous bottle inverting extrusion leak detection system according to claim 8, wherein the detection mechanism (2) is installed on the frame (7) in a lifting manner and comprises a light source and a camera.

10. The continuous bottle inverting extrusion leakage detection system according to claim 9, wherein a control host (9) is installed outside the detection portal (8), and the control host (9) is connected with the extrusion mechanism (1) and the detection mechanism (2) and controls the operation of the extrusion mechanism and the detection mechanism.

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