CN112720036A - Water pump multistation processing is progressively feeding device for water treatment - Google Patents

Abstract

The invention provides a multi-station processing step-by-step feeding device of a water pump for water treatment, relates to the technical field of water pump processing, and solves the problems that when a pump body of the existing water pump is processed, a single pump body is independently clamped and processed, and when one pump body is processed, the other pump body is replaced by a worker to clamp again and process, step-by-step feeding processing cannot be realized, and the processing efficiency is too low. The utility model provides a water pump multistation processing is progressively feeding device for water treatment, is including bearing the mechanism, be provided with bearing mechanism directly over bearing the mechanism. The water pump body is placed at the concave convex concave end, the water pump body is limited through the concave end, when the water pump is processed, the motor drives the round block B and the disc to rotate, the round block B is in tangential sliding fit with the arc notch A, a limiting effect is achieved on the bearing mechanism, the toggle column is in toggle fit with the U-shaped notch, and when the disc rotates for a circle, the round block A feeds one bit, so that the multi-station step-by-step feeding processing of the water pump body is achieved.

Description

Water pump multistation processing is progressively feeding device for water treatment

Technical Field

The invention belongs to the technical field of water pump processing, and particularly relates to a multi-station processing gradual feeding device of a water pump for water treatment.

Background

The water treatment is generally realized by means of various tools, and the common water treatment equipment comprises a water pump, a water conveying pipeline and other matched equipment, wherein the water pump is one of the most common equipment in the water treatment, is mainly used for extracting, transferring and clearing the water to be treated, and is subdivided into different types according to the structure according to different specific places for use.

For example, application No.: CN201911229882.8 the invention discloses a fixture for processing and fixing a centrifugal pump body, which comprises a support seat, wherein the support seat comprises a base, support plates and a rotary ring, the support plates are fixedly connected with two ends of the upper surface of the base, the base and the support plates are rotatably connected with the rotary ring through a rotating mechanism, the rotary ring is driven to rotate through a driving mechanism, the two support plates are used for fixing the rotary ring through a fixing mechanism, the inner wall of the rotary ring is fixedly connected with two clamping mechanisms which are symmetrically arranged, the two first clamping plates are driven to clamp the centrifugal pump body through the arranged clamping mechanisms, the second clamping plates are driven to rotate through hinges through a second air cylinder, so as to fix the centrifugal pump body, the distance between the two first clamping plates and the rotating angle between the four second clamping plates and the first clamping plates can be adjusted according to the size of the centrifugal pump body, so that a fixture for processing and fixing the centrifugal pump bodies with different sizes can be fixedly clamped, the production cost of the centrifugal pump body is reduced.

Based on the search of above-mentioned patent to and the equipment discovery among the combination prior art, present water pump body is adding the independent centre gripping processing of the independent pump body of time when man-hour, and after one pump body processing finished, through the staff change another pump body centre gripping again and process, can not realize step-by-step feeding processing, make machining efficiency too low.

Disclosure of Invention

In order to solve the technical problems, the invention provides a multi-station processing step-by-step feeding device for a water pump for water treatment, which aims to solve the problems that when a pump body of the existing water pump is processed, a single pump body is independently clamped and processed, and when one pump body is processed, the other pump body is replaced by a worker to clamp again and process, step-by-step feeding processing cannot be realized, and the processing efficiency is too low.

The invention relates to a multi-station processing gradual feeding device of a water pump for water treatment, which is achieved by the following specific technical means:

a multi-station processing step-by-step feeding device of a water pump for water treatment comprises a bearing mechanism, wherein a bearing mechanism is arranged right above the bearing mechanism, and a driving mechanism fixedly connected with the bearing mechanism is arranged at the axle center part of the bottom end surface of the bearing mechanism; the bearing mechanism comprises an annular ring, connecting columns and gear teeth, wherein the annular ring is arranged right above the circular tray, the outer diameter of the annular ring is consistent with the diameter of the circular tray, the circular tray and the annular ring are in the same axis state, the bottom end surface of the annular ring is fixedly connected with the top end surface of the circular tray through six connecting columns distributed in an annular array shape, two groups of meshing transmission groups formed by the gear teeth are symmetrically arranged on the inner peripheral surface of the annular ring, and the number of the gear teeth of each group of meshing transmission groups is one half of the number of the gear teeth of the gear; six groups of intermittent driving mechanisms are mounted on the bearing mechanism in an annular array shape in a co-rotating mode, and the intermittent driving mechanisms are meshed and matched with the bearing mechanism.

Further, bear the mechanism including circular tray, rectangle support frame, bearing A and bearing B, the symmetry form is personally submitted to circular tray bottom and two sets of rectangle support frames are welded altogether, and circular tray axle center position is embedded to be installed a set of bearing A, and the circular tray is gone up adjacent bearing A one side position and is embedded to be installed a set of bearing B.

Further, the bearing mechanism comprises a circular working disc, bearings C and concave bulges, six groups of bearings C are embedded and installed in the position of the adjacent peripheral surface of the top end face of the circular working disc in an annular array shape, six concave bulges are arranged in the annular array shape at the top end face of the circular working disc, the six concave bulges correspond to the six groups of bearings C respectively, and the opening end positions of the concave bulges face towards the bearings C.

Furthermore, the bearing mechanism comprises a rectangular pressing block, a rectangular rubber block, a trapezoidal sliding groove, a limiting column and a return spring, the top end surface of the circular working disc is provided with one trapezoidal sliding groove relative to the concave end parts of the six concave bulges, the inner end surface of the trapezoidal sliding groove is fixedly connected with one limiting column, a return spring is sleeved on the limiting column and is provided with six rectangular pressing blocks, the bottom end faces of the rectangular pressing blocks are provided with trapezoidal sliding blocks, the trapezoidal sliding blocks are connected in the trapezoidal sliding grooves in a sliding manner, and the trapezoidal sliding block is connected with the limit column in a sliding way, one end of the reset spring is contacted with the inner end face of one side end of the trapezoidal sliding chute, the other end of the elastic piece is contacted with the trapezoidal sliding block, the trapezoidal sliding block is contacted with the inner end face of the other side end of the trapezoidal sliding groove under the ordinary extension state of the reset spring, and the rectangular pressing block is bonded with a rectangular rubber block towards the concave convex part.

Further, bearing mechanism lacks groove and arc and lacks groove A including pivot A, disk A, U shape, and circular workstation bottom end face axle center position is provided with a pivot A, and fixed mounting has a disk A with the axle center on the pivot A, and disk A periphery is personally submitted annular array form and has seted up six U-shaped and six arc and lack groove A altogether, and the U-shaped lacks the groove and lacks groove A with the arc and be interval distribution, under the installation status, pivot A bottom and bearing A are fixed to be connected.

Further, actuating mechanism is including the motor, pivot B, disk B, arc lacks groove B, the disc with stir the post, the motor is through a disk B of pivot B fixedly connected with, and a arc lacks groove B has been seted up to disk B outer peripheral face, disk B installs a disc rather than with the axle center on the top face, the welding of disk bottom face has a stir post, and stir the post and be located arc and lack groove B position, under the installation status, pivot B is fixed with bearing B and is connected, motor fixed mounting lacks inslot A terminal surface at circular tray, disk B lacks inslot A with the arc and cuts sliding fit, stir post and U-shaped lack the groove contact and stir the cooperation, whenever the disc rotates a week, disk A feeds one bit.

Furthermore, intermittent type actuating mechanism is including pivot C, gear and cam, and pivot C top end face fixedly connected with cam, and pivot C bottom key installs a gear, and under the installation state, pivot C is fixed with bearing C and is connected, and the cam contacts with the outer tangent of rectangular briquetting, and gear and annular ring are in same horizontal position, and gear and the meshing of teeth of a cogwheel are coordinated.

Compared with the prior art, the invention has the following beneficial effects:

the water pump body is placed at the concave convex concave end, the water pump body is limited through the concave end, when the water pump is processed, the motor drives the round block B and the disc to rotate, the round block B is in tangential sliding fit with the arc notch A, a limiting effect is achieved on the bearing mechanism, the toggle column is in toggle fit with the U-shaped notch, and when the disc rotates for a circle, the round block A feeds one bit, so that the multi-station step-by-step feeding processing of the water pump body is achieved.

The inner peripheral surface of the annular ring is symmetrically provided with two groups of meshing transmission groups consisting of gear teeth, pump body processing equipment is arranged above a gap part between the two groups of meshing transmission groups, when the intermittent driving mechanism is driven by the feeding of the bearing mechanism, a gear in the intermittent driving mechanism is meshed with the meshing transmission groups, the cam slides along the rectangular pressing block when rotating, and the trapezoidal sliding block slides along the trapezoidal sliding groove and the limiting column in the process of rotating the cam by one hundred eighty degrees, so that the rectangular rubber block is tightly attached to the water pump body placed at the concave end of the concave bulge, the water pump body is limited, the water pump body is fed to the pump body processing equipment part, and when the pump body processing equipment processes the water pump body, the water pump body cannot shake, and the processing quality is ensured.

Drawings

Fig. 1 is a schematic structural diagram in a split state of the present invention.

Fig. 2 is a schematic structural diagram of the bearing mechanism of the invention.

Figure 3 is a schematic top axial view of the support mechanism of the present invention.

Figure 4 is a bottom axial view of the support mechanism of the present invention.

FIG. 5 is a schematic cross-sectional view of the concavely curved convex portion of the present invention.

Fig. 6 is a schematic view of the driving mechanism of the present invention.

Fig. 7 is a schematic view of the intermittent drive mechanism of the present invention.

Fig. 8 is a schematic top end axial view of the present invention.

Fig. 9 is a bottom end axial view of the present invention.

Fig. 10 is a schematic top view of the present invention.

In the drawings, the corresponding relationship between the component names and the reference numbers is as follows:

1. a carrying mechanism; 101. a circular tray; 102. a rectangular support frame; 103. a bearing A; 104. a bearing B; 105. an annular ring; 106. connecting columns; 107. gear teeth; 2. a support mechanism; 201. a circular working disc; 202. a bearing C; 203. a concave bulge; 204. rectangular pressing blocks; 205. a rectangular rubber block; 206. a rotating shaft A; 207. a round block A; 208. a U-shaped notch; 209. an arc notch A; 2010. a trapezoidal slider; 2011. a trapezoidal chute; 2012. a limiting column; 2013. a return spring; 3. a drive mechanism; 301. a motor; 302. a rotating shaft B; 303. a round block B; 304. an arc notch B; 305. a disc; 306. shifting the column; 4. an intermittent drive mechanism; 401. a rotating shaft C; 402. a gear; 403. a cam.

Detailed Description

The embodiments of the present invention will be described in further detail with reference to the drawings and examples. The following examples are intended to illustrate the invention but are not intended to limit the scope of the invention.

In the description of the present invention, "a plurality" means two or more unless otherwise specified; the terms "upper", "lower", "left", "right", "inner", "outer", "front", "rear", "head", "tail", and the like, indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, are only for convenience in describing and simplifying the description, and do not indicate or imply that the device or element referred to must have a particular orientation, be constructed in a particular orientation, and be operated, and thus, should not be construed as limiting the invention. Furthermore, the terms "first," "second," "third," and the like are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it is to be noted that, unless otherwise explicitly specified or limited, the terms "connected" and "connected" are to be interpreted broadly, e.g., as being fixed or detachable or integrally connected; can be mechanically or electrically connected; may be directly connected or indirectly connected through an intermediate. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

Example (b):

as shown in figures 1 to 10:

the invention provides a water pump multi-station processing gradual feeding device for water treatment, which comprises: the bearing mechanism 1 is provided with a bearing mechanism 2 right above the bearing mechanism 1, and a driving mechanism 3 fixedly connected with the bearing mechanism 2 is arranged at the axle center part of the bottom end surface of the bearing mechanism 1; the bearing mechanism 1 comprises an annular ring 105, connecting columns 106 and gear teeth 107, wherein the annular ring 105 is arranged right above the circular tray 101, the outer diameter of the annular ring 105 is consistent with the diameter of the circular tray 101, the circular tray 101 and the annular ring 105 are in the same axis state, the bottom end face of the annular ring 105 is fixedly connected with the top end face of the circular tray 101 through six connecting columns 106 which are distributed in an annular array shape, two meshing transmission groups which are composed of the gear teeth 107 are symmetrically arranged on the inner circumferential surface of the annular ring 105, and the number of the gear teeth 107 of each meshing transmission group is one half of the number of the gear teeth of the gear 402; six groups of intermittent driving mechanisms 4 are arranged on the bearing mechanism 2 in an annular array shape and rotate together, and the intermittent driving mechanisms 4 are meshed and matched with the bearing mechanism 1; the bearing mechanism 2 comprises a circular working disc 201, bearings C202 and concave bulges 203, six groups of bearings C202 are embedded into the adjacent peripheral surface part of the top end surface of the circular working disc 201 in an annular array shape, six concave bulges 203 are arranged on the top end surface of the circular working disc 201 in an annular array shape, the six concave bulges 203 correspond to the six groups of bearings C202 respectively, and the open end parts of the concave bulges 203 face the bearings C202; the supporting mechanism 2 comprises a rectangular pressing block 204, a rectangular rubber block 205, a trapezoidal sliding block 2010, a trapezoidal sliding groove 2011, a limiting column 2012 and a return spring 2013, the top end face of the circular working disc 201 is provided with a trapezoidal sliding groove 2011 relative to the concave end positions of the six concave bulges 203, the inner end face of the trapezoidal sliding groove 2011 is fixedly connected with the limiting column 2012, and a return spring 2013 is sleeved on the limit column 2012 and is provided with six rectangular press blocks 204, the bottom end face of the rectangular pressing block 204 is provided with a trapezoidal sliding block 2010, the trapezoidal sliding block 2010 is connected in a trapezoidal sliding groove 2011 in a sliding manner, the trapezoidal sliding block 2010 is connected with the limit column 2012 in a sliding way, one end of the return spring 2013 is contacted with the inner end face of one side end of the trapezoidal sliding groove 2011, the other end of the rectangular pressing block 204 is in contact with the trapezoidal sliding block 2010, the trapezoidal sliding block 2010 is in contact with the inner end face of the other side end of the trapezoidal sliding groove 2011 under the ordinary extension state of the return spring 2013, and the rectangular rubber block 205 is bonded to the concave convex 203; the supporting mechanism 2 comprises a rotating shaft A206, a round block A207, a U-shaped notch 208 and an arc notch A209, the axis part of the bottom end face of the circular working disc 201 is provided with the rotating shaft A206, the rotating shaft A206 is fixedly provided with the round block A207 with the same axis, the periphery of the round block A207 is in an annular array shape, and the six U-shaped notches 208 and the six arc notches A209 are arranged, the U-shaped notches 208 and the arc notches A209 are distributed at intervals, and in the installation state, the bottom end of the rotating shaft A206 is fixedly connected with the bearing A103.

The bearing mechanism 1 comprises a circular tray 101, rectangular support frames 102, bearings A103 and bearings B104, wherein the two groups of rectangular support frames 102 are welded at the bottom end face of the circular tray 101 in a symmetrical mode, a group of bearings A103 is embedded in the axis position of the circular tray 101, and a group of bearings B104 is embedded in one side position of the circular tray 101, which is adjacent to the bearings A103.

Wherein, actuating mechanism 3 is including motor 301, pivot B302, disk B303, arc scarce groove B304, disc 305 and toggle column 306, motor 301 is through pivot B302 fixedly connected with disk B303, and disk B303 peripheral face has seted up one and has lacked groove B304 in the arc, disk 305 rather than the coaxial axle is installed to disk B303 top end face, disk 305 bottom end face welding has a toggle column 306, and toggle column 306 is located arc scarce groove B304 position, under the installation state, pivot B302 is connected with bearing B104 is fixed, motor 301 fixed mounting is in circular tray 101 bottom end face, disk B303 and arc lack inslot A209 tangent sliding fit, toggle column 306 and U-shaped scarce groove 208 contact toggle fit, whenever disk 305 rotates a week, disk A207 feeds one bit.

The intermittent driving mechanism 4 comprises a rotating shaft C401, a gear 402 and a cam 403, the top end face of the rotating shaft C401 is fixedly connected with the cam 403, the gear 402 is mounted at the bottom end key of the rotating shaft C401, the rotating shaft C401 is fixedly connected with the bearing C202 in a mounting state, the cam 403 is in contact with the outer portion of the rectangular pressing block 204 in an tangent mode, the gear 402 and the annular ring 105 are located at the same horizontal position, and the gear 402 is in meshing fit with the gear teeth 107.

When in use:

the water pump body is placed at the concave end of the concave protrusion 203, the water pump body is limited through the concave end, when the water pump is machined, the motor 301 drives the round block B303 and the disc 305 to rotate, the round block B303 is in tangential sliding fit with the arc notch A209, the limiting effect is achieved on the supporting mechanism 2, the toggle column 306 is in contact toggle fit with the U-shaped notch 208, and when the disc 305 rotates for a circle, the round block A207 feeds for one bit, so that the multi-station gradual feeding machining of the water pump body is achieved;

the inner peripheral surface of the annular ring 105 of the invention is symmetrically provided with two groups of meshing transmission groups which are composed of gear teeth 107, the number of the gear teeth 107 of each group of meshing transmission groups is one half of the number of the gear teeth of the gear 402, pump body processing equipment is arranged above the gap part between the two groups of meshing transmission groups, six groups of intermittent driving mechanisms 4 are arranged on the supporting mechanism 2 in an annular array shape in a rotating way, when the intermittent driving mechanisms 4 are driven by the feeding of the supporting mechanism 2 and the gear 402 in the intermittent driving mechanism 4 is contacted with the meshing transmission groups, the gear 402 is meshed with the gear teeth 107, the cam 403 is synchronously driven to rotate by matching with the bearing C202 through a rotating shaft C401 and the gear 402 to rotate by one hundred eighty degrees, the cam 403 slides along the rectangular pressing block 204 when rotating, the trapezoidal sliding block 2010 slides along the trapezoidal sliding groove 403 and the limiting column 2012 during the rotation of the cam 403 by one hundred eighty degrees, the, at this time, under the extrusion of the cam 403, the rectangular rubber block 205 is tightly attached to the water pump body placed at the concave end of the concave protrusion 203, the water pump body is limited, it is guaranteed that the water pump body is fed to the position of the pump body processing equipment, the pump body processing equipment processes the water pump body, the water pump body does not shake, the processing quality is guaranteed, when the processing is finished and one position is fed continuously, the gear 402 is meshed with the gear teeth 107 of the other meshing transmission group, so that the meshing transmission gear 402 rotates by one hundred eighty degrees, at this time, the convex end of the cam 403 is not contacted with the rectangular pressing block 204, at this time, under the reset action of the reset spring 2013, the trapezoidal sliding block 2010 slides along the trapezoidal sliding groove 2011 and the limiting column 2012 to reset, and the water pump body after the processing is convenient to take up without hindrance subsequently.

The embodiments of the present invention have been presented for purposes of illustration and description, and are not intended to be exhaustive or limited to the invention in the form disclosed. Many modifications and variations will be apparent to those of ordinary skill in the art. The embodiment was chosen and described in order to best explain the principles of the invention and the practical application, and to enable others of ordinary skill in the art to understand the invention for various embodiments with various modifications as are suited to the particular use contemplated.

Claims (7)

1. The utility model provides a water pump multistation processing progressively feeds device for water treatment which characterized in that: the device comprises a bearing mechanism (1), wherein a bearing mechanism (2) is arranged right above the bearing mechanism (1), and a driving mechanism (3) fixedly connected with the bearing mechanism (2) is arranged at the axis part of the bottom end surface of the bearing mechanism (1); the bearing mechanism (1) comprises an annular ring (105), connecting columns (106) and gear teeth (107), wherein the annular ring (105) is arranged right above the circular tray (101), the outer diameter of the annular ring (105) is consistent with the diameter of the circular tray (101), the circular tray (101) and the annular ring (105) are in the same axis state, the bottom end face of the annular ring (105) is fixedly connected with the top end face of the circular tray (101) through six connecting columns (106) distributed in an annular array shape, two meshing transmission groups formed by the gear teeth (107) are symmetrically arranged on the inner circumferential surface of the annular ring (105), and the number of the gear teeth (107) of each meshing transmission group is one half of the number of the gear teeth of the gear (402); six groups of intermittent driving mechanisms (4) are mounted on the bearing mechanism (2) in an annular array shape in a co-rotating mode, and the intermittent driving mechanisms (4) are meshed and matched with the bearing mechanism (1).

2. A water pump multistation processing progressive feed device for water treatment as claimed in claim 1, characterized in that: the bearing mechanism (1) comprises a circular tray (101), a rectangular support frame (102), a bearing A (103) and a bearing B (104), wherein the bottom end surface of the circular tray (101) is symmetrically welded with two groups of rectangular support frames (102), a group of bearings A (103) are embedded in the axis position of the circular tray (101), and a group of bearings B (104) are embedded in the side position of the adjacent bearing A (103) on the circular tray (101).

3. A water pump multistation processing progressive feed device for water treatment as claimed in claim 1, characterized in that: the bearing mechanism (2) comprises a circular working disc (201), bearings C (202) and concave protrusions (203), six groups of bearings C (202) are embedded and mounted in an annular array mode at the position of the adjacent peripheral face of the top end face of the circular working disc (201), six concave protrusions (203) are arranged at the top end face of the circular working disc (201) in an annular array mode, the six concave protrusions (203) correspond to the six groups of bearings C (202) respectively, and the opening end of each concave protrusion (203) faces towards the corresponding bearing C (202).

4. A water pump multistation processing progressive feed device for water treatment as claimed in claim 1, characterized in that: the supporting mechanism (2) comprises a rectangular pressing block (204), a rectangular rubber block (205), a trapezoidal sliding block (2010), a trapezoidal sliding groove (2011), a limiting column (2012) and a return spring (2013), wherein one trapezoidal sliding groove (2011) is formed in the top end face of the circular working disc (201) relative to the concave end parts of the six concave bulges (203), the inner end face of the trapezoidal sliding groove (2011) is fixedly connected with one limiting column (2012), the return spring (2013) is sleeved on the limiting column (2012), the six rectangular pressing blocks (204) are arranged, the trapezoidal sliding block (2010) is arranged on the bottom end face of the rectangular pressing block (204), the trapezoidal sliding block (2010) is connected in the trapezoidal sliding groove (2011) in a sliding mode, the trapezoidal sliding block (2010) is connected with the limiting column (2012) in a sliding mode, one end of the return spring (2013) is in contact with the inner end face of one side of the trapezoidal sliding groove (2011), and the other end, under the ordinary extension state of the return spring (2013), the trapezoidal sliding block (2010) is in contact with the inner end face of the other side end of the trapezoidal sliding groove (2011), and the rectangular pressing block (204) is bonded with a rectangular rubber block (205) towards the concave bulge (203).

5. A water pump multistation processing progressive feed device for water treatment as claimed in claim 1, characterized in that: bearing mechanism (2) is including pivot A (206), disk A (207), U-shaped lacks groove (208) and arc and lacks groove A (209), circular working disc (201) bottom end face axle center position is provided with a pivot A (206), and fixed mounting has disk A (207) of one with the axle center on pivot A (206), six U-shaped lack groove (208) and six arc lack groove A (209) have been seted up altogether to disk A (207) periphery personally submitting annular array form, and U-shaped lack groove (208) and arc lack groove A (209) and are interval distribution, under the installation status, pivot A (206) bottom is connected with bearing A (103) fixed.

6. A water pump multistation processing progressive feed device for water treatment as claimed in claim 1, characterized in that: the driving mechanism (3) comprises a motor (301), a rotating shaft B (302), a round block B (303), an arc-shaped notch B (304), a disc (305) and a toggle column (306), wherein the motor (301) is fixedly connected with the round block B (303) through the rotating shaft B (302), the outer peripheral surface of the round block B (303) is provided with the arc-shaped notch B (304), the top end surface of the round block B (303) is provided with the disc (305) which is coaxial with the round block B, the bottom end surface of the disc (305) is welded with the toggle column (306), the toggle column (306) is positioned at the arc-shaped notch B (304), in the installation state, the rotating shaft B (302) is fixedly connected with a bearing B (104), the motor (301) is fixedly arranged at the bottom end surface of the round tray (101), the round block B (303) is in tangential sliding fit with the arc-shaped notch A (209), and the toggle column (306) is in contact with the U-shaped notch A (208, the round block A (207) is fed one bit each time the disc (305) rotates one revolution.

7. A water pump multistation processing progressive feed device for water treatment as claimed in claim 1, characterized in that: the intermittent driving mechanism (4) comprises a rotating shaft C (401), a gear (402) and a cam (403), the top end face of the rotating shaft C (401) is fixedly connected with the cam (403), the gear (402) is installed at the bottom end of the rotating shaft C (401), in the installation state, the rotating shaft C (401) is fixedly connected with the bearing C (202), the cam (403) is in external tangent contact with the rectangular pressing block (204), the gear (402) and the annular ring (105) are located at the same horizontal position, and the gear (402) is in meshing fit with the gear teeth (107).

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