A PVC fluid hose waste recovery device

Abstract

This utility model relates to the technical field of PVC fluid hoses, and in particular to a PVC fluid hose waste recycling device. It not only collects the dust generated during the crushing process, preventing dust from scattering and polluting the environment, but also separates waste particles of different diameters for collection, improving the device's operational flexibility. The device includes a screening mechanism, a sealing mechanism, a crushing mechanism, a pushing mechanism, a collecting mechanism, and a dust collection mechanism. The sealing mechanism is installed on the screening mechanism to prevent dust from scattering; the crushing mechanism is installed on the screening mechanism to crush the waste; the pushing mechanism is installed on the screening mechanism to transport the crushed waste; the collecting mechanism is installed on the screening mechanism to collect the crushed waste; and the dust collection mechanism is installed on the screening mechanism to collect the dust.

Description

Technical Field

[0001] This utility model relates to the technical field of PVC fluid hoses, and in particular to a PVC fluid hose waste recycling device. Background Technology

[0002] PVC fluid hoses are made of polyvinyl chloride, one of the world's most produced plastic products. They are inexpensive and widely used.

[0003] Existing PVC fluid hose waste recycling devices, such as the PVC pipe production waste recycling equipment disclosed in utility model patent application number 202021725434.5, mainly include a crushing box. This PVC pipe production waste recycling equipment, by means of a crushing box and a crushing device, involves placing the PVC pipe into the crushing box, starting the rotary motor, and causing the output shaft of the rotary motor to rotate, driving the movable shaft and the crushing device to rotate, thus beginning to crush the PVC pipe. The crushed PVC pipe falls from the gaps in the crushing device onto a filter screen. Then, a vibration motor is started, causing the vibration of the motor to drive the filter screen to vibrate, and the filter screen presses the movable rod and fixed block downwards.

[0004] However, the process of crushing the hose may generate a lot of dust, which pollutes the environment and reduces the recycling rate. Moreover, most existing recycling devices do not screen the crushed hose, resulting in waste particles of varying sizes, which affects subsequent use. Utility Model Content

[0005] To solve the above-mentioned technical problems, this utility model provides a PVC fluid hose waste recycling device that can not only collect the dust generated during the crushing process to prevent dust from spreading and polluting the environment, but also collect waste particles of different diameters separately, thus improving the flexibility of the device.

[0006] This utility model discloses a PVC fluid hose waste recycling device, including a screening mechanism; it also includes a sealing mechanism, a crushing mechanism, a pushing mechanism, a collecting mechanism, and a dust collection mechanism. The sealing mechanism is installed on the screening mechanism to prevent dust from scattering; the crushing mechanism is installed on the screening mechanism to crush the waste; the pushing mechanism is installed on the screening mechanism to transport the crushed waste; the collecting mechanism is installed on the screening mechanism to collect the crushed waste; and the dust collection mechanism is installed on the screening mechanism to collect dust. Workers feed the hose waste into the screening mechanism, the sealing mechanism covers the top of the screening mechanism to prevent dust from scattering during the crushing process, the crushing mechanism is activated to crush the waste, the screening mechanism screens the crushed waste, the pushing mechanism discharges large particles of waste, the collecting mechanism separates large particles of waste from small particles, and the dust collection mechanism collects the crushed dust.

[0007] Preferably, the screening mechanism includes a base, a processing box, an arc-shaped screen, and a support frame. The bottom end of the base is connected to the ground, and the bottom end of the processing box is connected to the top end of the base. The processing box has an internal cavity, and the arc-shaped screen is installed inside the cavity of the processing box. The support frame is installed on the base. The waste material from the hose is fed into the cavity of the processing box, and the crushed waste material falls onto the arc-shaped screen. The arc-shaped screen screens the waste material particles into large particles and small particles.

[0008] Preferably, the sealing mechanism includes two sets of hydraulic cylinders, two sets of connecting ends, a rotating shaft, a sealing cover, and a first handle. Both sets of hydraulic cylinders are mounted on the processing box. The bottom ends of the two sets of connecting ends are respectively connected to the top ends of the two sets of hydraulic cylinders. The rotating shaft is rotatably mounted between the two sets of connecting ends. The sealing cover is mounted on the rotating shaft, and the first handle is mounted on the sealing cover. The two sets of hydraulic cylinders push the two sets of connecting ends to lift, and the two sets of connecting ends drive the rotating shaft and the sealing cover to lift, making it convenient for workers to put large quantities of waste hoses into the cavity of the processing box. Then, the two sets of hydraulic cylinders drive the sealing cover to descend, sealing the top of the processing box to prevent dust from scattering during the crushing process. When it is necessary to add material during the crushing process, the worker pulls the first handle to rotate the sealing cover, making it convenient to add waste material.

[0009] Preferably, the crushing mechanism includes a control box, three sets of crushing rollers, and two sets of guide plates. The control box is mounted on the processing box, and the power output end of the control box is connected to the power input end of the three sets of crushing rollers. Both sets of guide plates are installed in the cavity of the processing box. The control box drives the three sets of crushing rollers to rotate, and the three sets of crushing rollers crush the waste material. The two sets of guide plates facilitate the crushing of the waste material in coordination with the three sets of guide plates.

[0010] Preferably, the pushing mechanism includes a motor, a reducer, a drive shaft, spiral blades, and a discharge pipe. The motor is mounted on the processing box, and the output end of the motor is connected to the input end of the reducer. The output end of the reducer is connected to the input end of the drive shaft. The spiral blades are mounted on the drive shaft, and the discharge pipe is mounted on the processing box and communicates with the interior of the processing box cavity. When the motor is started, the motor drives the drive shaft to rotate through the reducer. The drive shaft drives the spiral blades to rotate, and the spiral blades move the waste material above the arc-shaped screen. This not only accelerates the passage of waste material through the arc-shaped screen but also pushes large particles of waste material out through the discharge pipe.

[0011] Preferably, the collection mechanism includes two sets of guide rails, a movable box, a partition, and a second handle. Both sets of guide rails are mounted on the base, the movable box is slidably mounted on the two sets of guide rails, the partition is installed inside the movable box, and the second handle is mounted on the movable box. The operator operates the second handle to push the movable box to move on the two sets of guide rails. The rear end of the movable box receives small particles of waste, and the discharge pipe transports large particles of waste to the front end of the movable box. The partition separates the waste particles of different sizes.

[0012] Preferably, the dust collection mechanism includes two sets of dust collection hoods, two sets of air supply pipes, a filter box, a fan, and a cleaning cover. Both sets of dust collection hoods are installed on the processing box and communicate with the interior of the processing box cavity. The two sets of air supply pipes are respectively installed on the two sets of dust collection hoods and communicate with their interiors. The filter box is installed on the support frame and communicates with the interior of the two sets of air supply pipes. The fan is installed on the filter box, and the cleaning cover is rotatably installed on the filter box. When the fan is started, the dust in the cavity of the processing box enters the filter box through the two sets of dust collection hoods and the two sets of air supply pipes. After long-term absorption, the cleaning cover is opened to clean the filter box.

[0013] Compared with the prior art, the beneficial effects of this utility model are as follows: the worker puts the waste material into the screening mechanism, the sealing mechanism covers the top of the screening mechanism to prevent dust from scattering during the crushing process, the crushing mechanism is started to crush the waste material, the screening mechanism screens the crushed waste material, the pushing mechanism discharges the large particles of waste material, the collecting mechanism separates the large particles of fertilizer and the small particles of waste material for collection, and the dust collection mechanism collects the dust after crushing. Attached Figure Description

[0014] Figure 1 This is a front view structural diagram of the present invention;

[0015] Figure 2 This is a cross-sectional isometric structural diagram of the screening mechanism, sealing mechanism and crushing mechanism of this utility model;

[0016] Figure 3 This is an isometric structural diagram of the crushing mechanism, pushing mechanism, and dust collection mechanism of this utility model;

[0017] Figure 4 This is a partially enlarged cross-sectional isometric structural diagram of the pushing mechanism, collecting mechanism and dust suction mechanism of this utility model.

[0018] The attached diagram is labeled as follows: 01, screening mechanism; 11, base; 12, processing box; 13, arc-shaped screen; 14, support frame; 02, sealing mechanism; 21, hydraulic cylinder; 22, connecting end; 23, rotating shaft; 24, sealing cover; 25, first handle; 03, crushing mechanism; 31, control box; 32, crushing roller; 33, guide plate; 04, pushing mechanism; 41, electric motor; 42, reducer; 43, drive shaft; 44, spiral blade; 45, discharge pipe; 05, collecting mechanism; 51, guide rail; 52, moving box; 53, partition; 54, second handle; 06, dust collection mechanism; 61, dust collection hood; 62, air supply pipe; 63, filter box; 64, fan; 65, cleaning cover. Detailed Implementation

[0019] To facilitate understanding of this utility model, a more complete description will be given below with reference to the accompanying drawings. This utility model can be implemented in many different forms and is not limited to the embodiments described herein. Rather, these embodiments are provided to make the disclosure of this utility model more thorough and complete. Example

[0020] This utility model discloses a PVC fluid hose waste recycling device, including a screening mechanism 01; it also includes a sealing mechanism 02, a crushing mechanism 03, a pushing mechanism 04, a collecting mechanism 05, and a dust collection mechanism 06. The sealing mechanism 02 is installed on the screening mechanism 01 to prevent dust from scattering; the crushing mechanism 03 is installed on the screening mechanism 01 to crush the waste; the pushing mechanism 04 is installed on the screening mechanism 01 to transport the crushed waste; and the collecting mechanism 05 is installed on the screening mechanism 01 to collect the crushed waste. The dust collection mechanism 06 is installed on the screening mechanism 01 to collect dust. The screening mechanism 01 includes a base 11, a processing box 12, an arc-shaped screen 13, and a support frame 14. The bottom end of the base 11 is connected to the ground, and the bottom end of the processing box 12 is connected to the top end of the base 11. The processing box 12 has an internal cavity, and the arc-shaped screen 13 is installed in the cavity of the processing box 12. The support frame 14 is installed on the base 11. The sealing mechanism 02 includes two sets of hydraulic cylinders 21, two sets of connecting ends 22, a rotating shaft 23, and a sealing element. The cover 24 and the first handle 25, and two sets of hydraulic cylinders 21 are all installed on the processing box 12. The bottom ends of the two sets of connecting ends 22 are respectively connected to the top ends of the two sets of hydraulic cylinders 21. The rotating shaft 23 is rotatably installed between the two sets of connecting ends 22. The sealing cover 24 is installed on the rotating shaft 23, and the first handle 25 is installed on the sealing cover 24. The crushing mechanism 03 includes a control box 31, three sets of crushing rollers 32, and two sets of guide plates 33. The control box 31 is installed on the processing box 12. The power output end of the control box 31 is connected to the power output end of the three sets of crushing rollers 32. The force input end is connected, and both sets of guide plates 33 are installed in the cavity of the processing box 12; the pushing mechanism 04 includes a motor 41, a reducer 42, a transmission shaft 43, a spiral blade 44 and a discharge pipe 45. The motor 41 is installed on the processing box 12, the output end of the motor 41 is connected to the input end of the reducer 42, the output end of the reducer 42 is connected to the input end of the transmission shaft 43, the spiral blade 44 is installed on the transmission shaft 43, and the discharge pipe 45 is installed on the processing box 12 and communicates with the cavity of the processing box 12.During operation, firstly, two sets of hydraulic cylinders 21 push two sets of connecting ends 22 to lift, which in turn lifts the rotating shaft 23 and the sealing cover 24, facilitating the delivery of large quantities of waste hose material into the cavity of the processing box 12. Then, the two sets of hydraulic cylinders 21 lower the sealing cover 24, sealing the top of the processing box 12 to prevent dust from scattering during the crushing process. When material needs to be added during crushing, the operator pulls the first handle 25 to rotate the sealing cover 24, facilitating the delivery of waste material. The control box 31 drives three sets of crushing rollers 32 to rotate, and the three sets of crushing rollers 32... The waste material is crushed. Two sets of guide plates 33 are set up to facilitate the crushing of the waste material in conjunction with three sets of guide plates 33. The crushed waste material falls onto the arc-shaped screen 13, which screens the waste particles into large and small particles. The motor 41 is started, and the motor 41 drives the transmission shaft 43 to rotate through the reducer 42. The transmission shaft 43 drives the spiral blades 44 to rotate, and the spiral blades 44 move the waste material above the arc-shaped screen 13. This not only accelerates the passage of waste material through the arc-shaped screen 13, but also pushes large waste particles out through the discharge pipe 45. Example

[0021] like Figures 1 to 4As shown, this utility model discloses a PVC fluid hose waste recycling device, based on embodiment 1. The collection mechanism 05 includes two sets of guide rails 51, a movable box 52, a partition 53, and a second handle 54. Both sets of guide rails 51 are mounted on the base 11. The movable box 52 is slidably mounted on the two sets of guide rails 51. The partition 53 is installed inside the movable box 52, and the second handle 54 is installed on the movable box 52. The dust collection mechanism 06 includes two sets of dust collection hoods 61, two sets of air supply pipes 62, a filter box 63, a fan 64, and a cleaning cover 65. Both sets of dust collection hoods 61 are mounted on the processing box 12 and communicate with the interior of the cavity of the processing box 12. The air supply pipes 62 are respectively installed on the two sets of dust collection hoods 61 and connected to their interiors. The filter box 63 is installed on the support frame 14 and connected to the interiors of the two sets of air supply pipes 62. The fan 64 is installed on the filter box 63, and the cleaning cover 65 is rotatably installed on the filter box 63. During operation, firstly, the two sets of hydraulic cylinders 21 push the two sets of connecting ends 22 to lift. The two sets of connecting ends 22 drive the rotating shaft 23 and the sealing cover 24 to lift, making it convenient for workers to put large quantities of hose waste into the cavity of the processing box 12. Then, the two sets of hydraulic cylinders 21 drive the sealing cover 24 to descend, sealing the top of the processing box 12 and preventing dust from escaping during the crushing process. When additional material needs to be added during the crushing process, the operator pulls the first handle 25 to rotate the sealing cover 24, facilitating the feeding of waste material. The control box 31 drives the three sets of crushing rollers 32 to rotate, crushing the waste material. Two sets of guide plates 33 are provided to facilitate the crushing of the waste material. The crushed waste material falls onto the arc-shaped screen 13, which separates the waste particles into large and small particles. The motor 41 is started, and the motor 41 drives the transmission shaft 43 to rotate through the reducer 42. The transmission shaft 43 drives the spiral blades 44 to rotate, and the spiral blades 44 drive the arc-shaped screen. The movement of waste above 13 not only accelerates the passage of waste through the arc screen 13, but also pushes large particles of waste out through the discharge pipe 45. The operator operates the second handle 54 to push the moving box 52 to move on the two sets of guide rails 51. The rear end of the moving box 52 receives small particles of waste, and the discharge pipe 45 transports large particles of waste to the front end of the moving box 52. The partition 53 separates the large and small particles of waste. The fan 64 is started to extract air. The dust in the cavity of the treatment box 12 enters the filter box 63 through the two sets of dust collection hoods 61 and the two sets of air supply pipes 62. After long-term absorption, the cleaning cover 65 is opened to clean the filter box 63.

[0022] The electric motor 41, reducer 42, and fan 64 of this utility model are commercially available. Technical personnel in this industry only need to install and operate them according to the accompanying instruction manual, without requiring any creative work from those skilled in the art.

[0023] The above description is only a preferred embodiment of the present utility model. It should be noted that for those skilled in the art, several improvements and modifications can be made without departing from the technical principles of the present utility model, and these improvements and modifications should also be considered within the protection scope of the present utility model.

Claims

1. A PVC fluid hose waste recycling device, comprising a screening mechanism (01); characterized in that, It also includes a sealing mechanism (02), a crushing mechanism (03), a pushing mechanism (04), a collecting mechanism (05), and a dust collection mechanism (06). The sealing mechanism (02) is installed on the screening mechanism (01) to prevent dust from scattering. The crushing mechanism (03) is installed on the screening mechanism (01) to crush the waste. The pushing mechanism (04) is installed on the screening mechanism (01) to transport the crushed waste. The collecting mechanism (05) is installed on the screening mechanism (01) to collect the crushed waste. The dust collection mechanism (06) is installed on the screening mechanism (01) to collect the dust.

2. The PVC fluid hose waste recycling device as described in claim 1, characterized in that, The screening mechanism (01) includes a base (11), a processing box (12), an arc screen (13), and a support frame (14). The bottom end of the base (11) is connected to the ground, the bottom end of the processing box (12) is connected to the top end of the base (11), the processing box (12) has a cavity inside, the arc screen (13) is installed in the cavity of the processing box (12), and the support frame (14) is installed on the base (11).

3. The PVC fluid hose waste recycling device as described in claim 2, characterized in that, The sealing mechanism (02) includes two sets of hydraulic cylinders (21), two sets of connecting ends (22), a rotating shaft (23), a sealing cover (24), and a first handle (25). Both sets of hydraulic cylinders (21) are installed on the processing box (12). The bottom ends of the two sets of connecting ends (22) are respectively connected to the top ends of the two sets of hydraulic cylinders (21). The rotating shaft (23) is rotatably installed between the two sets of connecting ends (22). The sealing cover (24) is installed on the rotating shaft (23), and the first handle (25) is installed on the sealing cover (24).

4. A PVC fluid hose waste recycling device as described in claim 2, characterized in that, The crushing mechanism (03) includes a control box (31), three sets of crushing rollers (32) and two sets of guide plates (33). The control box (31) is installed on the processing box (12). The power output end of the control box (31) is connected to the power input end of the three sets of crushing rollers (32). The two sets of guide plates (33) are installed in the cavity of the processing box (12).

5. A PVC fluid hose waste recycling device as described in claim 2, characterized in that, The pushing mechanism (04) includes a motor (41), a reducer (42), a drive shaft (43), a spiral blade (44), and a discharge pipe (45). The motor (41) is mounted on the processing box (12). The output end of the motor (41) is connected to the input end of the reducer (42). The output end of the reducer (42) is connected to the input end of the drive shaft (43). The spiral blade (44) is mounted on the drive shaft (43). The discharge pipe (45) is mounted on the processing box (12) and communicates with the cavity inside the processing box (12).

6. A PVC fluid hose waste recycling device as described in claim 2, characterized in that, The collection mechanism (05) includes two sets of guide rails (51), a movable box (52), a partition (53), and a second handle (54). Both sets of guide rails (51) are mounted on the base (11). The movable box (52) is slidably mounted on the two sets of guide rails (51). The partition (53) is installed inside the movable box (52). The second handle (54) is installed on the movable box (52).

7. A PVC fluid hose waste recycling device as described in claim 2, characterized in that, The dust collection mechanism (06) includes two sets of dust collection hoods (61), two sets of air supply pipes (62), a filter box (63), a fan (64), and a cleaning cover (65). The two sets of dust collection hoods (61) are installed on the processing box (12) and communicate with the interior of the cavity of the processing box (12). The two sets of air supply pipes (62) are respectively installed on the two sets of dust collection hoods (61) and communicate with their interiors. The filter box (63) is installed on the support frame (14) and communicates with the interior of the two sets of air supply pipes (62). The fan (64) is installed on the filter box (63). The cleaning cover (65) is rotatably installed on the filter box (63).

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