CN112902855A - Shoe size automatic measuring device based on textile machinery processing - Google Patents

Abstract

The invention provides an automatic shoe size measuring device based on textile machinery processing, which relates to the technical field of textile machinery and solves the problems that the shoe size cannot be accurately measured in the actual application process and the placement direction of an insole cannot be adjusted when the insole swings, so that the use is inconvenient, the automatic shoe size measuring device comprises a guide mechanism, wherein the guide mechanism is arranged at the left side position of a bearing mechanism, an air cylinder is arranged at the inner side of a bracket in a waste screening mechanism, so that when an insole with a wrong placement is found, a suction head can be pushed downwards to contact the insole by starting the air cylinder, then air is pumped by a vacuum pump to suck the insole, laser detecting heads are arranged at the inner sides of two processors, so that the length of the insole can be measured by the laser detecting heads when the insole placed on a conveying belt is swung, thereby achieving the purpose of more practicality and achieving the purpose of more practicality.

Description

Shoe size automatic measuring device based on textile machinery processing

Technical Field

The invention belongs to the technical field of textile machinery, and particularly relates to an automatic shoe size measuring device based on textile machinery processing.

Background

The textile machine is a loom driven by manpower, the textile machine is a tool for processing raw materials such as threads, silk and hemp into silk threads and then weaving the silk threads into cloth, such as a spinning drop, a spinning carriage, a spindle and a pedal loom, and also a modern mechanical loom, a modern numerical control automatic loom and the like.

For example, application No.: the invention discloses a cutting device convenient for length measurement for textile machinery, which comprises a top plate, wherein the left end and the right end of the top plate are respectively welded with a first sliding block and a second sliding block, a pointing piece is fixed on the outer side of the first sliding block, the lower part of the top plate is mutually connected with a fixed sleeve through a second sliding groove, a cutting head is arranged inside the fixed sleeve, the front end and the rear end of the cutting head are mutually connected with a limiting plate, the right side of the fixed sleeve is rotatably connected with a movable shaft, meanwhile, a servo motor is arranged on the right side of the movable shaft, a connecting shaft is fixed below the servo motor, the lower part of the connecting shaft is slidably connected with a movable plate through a first sliding rail, and the lower part of the movable plate is slidably connected with a groove through a second sliding rail. This cutting equipment for textile machinery is with being convenient for measure length can carry out the measurement of length to the surface fabric, still can carry on spacingly to the motion trail of cutting head simultaneously, avoids it to take place the skew.

Based on the search of above-mentioned patent to and combine the equipment discovery among the prior art, above-mentioned equipment is when using, though can measure length, nevertheless there is in the practical application in-process because of can't carrying out accurate measurement work to the shoes sign indicating number, and can't adjust the orientation of putting of shoe-pad when swinging to the shoe-pad, and then can cause the use inconvenient.

Disclosure of Invention

In order to solve the technical problems, the invention provides an automatic shoe size measuring device based on textile machinery processing, which aims to solve the problems that the shoe size cannot be accurately measured in the existing practical application process, and the placement direction of an insole cannot be adjusted when the insole swings, so that the inconvenience in use is caused.

The invention relates to an automatic shoe size measuring device based on textile machinery processing, which has the purpose and the effect and is achieved by the following specific technical means:

an automatic shoe size measuring device based on textile machinery processing comprises a guide mechanism, a guide detection mechanism and a waste screening mechanism, wherein the guide mechanism is arranged at the left side position of a bearing mechanism and is in transmission connection with the bearing mechanism; the guide detection mechanisms are arranged at two positions, and the two guide detection mechanisms are respectively arranged at the front side and the rear side of the interior of the bearing mechanism and are connected with the guide mechanism; the waste screening mechanism is arranged at the center of the top end face of the bearing mechanism, and a stepping mechanism is further arranged on the inner side of the bearing mechanism; waste material screening mechanism is including support, cylinder, suction head and vacuum pump, the support is U-shaped structural design, and the cylinder is installed on the top of support, and the bottom of cylinder installs the gas pole to install the suction head through the gas pole, the vacuum pump is installed in the top position of suction head, and the support fixed connection of U-shaped is in the top face position of processing platform under the installation state.

Furthermore, the bearing mechanism comprises a processing table, a base and a motor, wherein the base is provided with two parts, the two parts of the base are respectively and fixedly connected to the left side and the right side of the bottom end face of the processing table, and the motor is screwed on the front end face of the base on the left side through bolts;

furthermore, the bearing mechanism also comprises two gears, a chain and a conveying belt, wherein the gears are arranged at two positions, the gear at the lower side is arranged at the rear side of the motor, the chains are meshed and driven at the outer sides of the two gears, the conveying belt is arranged at two positions, and the two conveying belts are respectively arranged at the front side and the rear side of the interior of the processing table and are in transmission connection with the motor;

furthermore, the guide mechanism comprises a guide gear, a connecting rod and a driven gear, the connecting rod is provided with two positions, the two connecting rods are rotatably connected, the guide gear is further arranged on the right side of the two connecting rods, the driven gear is provided with two positions, the driven gear positioned on the rear side is meshed with and driven at the rear side position of the guide gear, and the diameter of the driven gear is smaller than that of the guide gear;

furthermore, the guide mechanism also comprises a rack, a guide rod and a driving motor, wherein the rack is provided with two parts, the two racks are respectively meshed and driven at the upper side and the lower side of the driven gear positioned at the front side, the guide rod is designed in an L-shaped structure, the guide rod is fixedly connected at the right side position of the rack positioned at the lower side, the driving motor is arranged at the rear side position of the two connecting rods, and the guide rod is fixedly connected at the bottom end surface position of the guide plate positioned at the right side in the installation state;

furthermore, the guide detection mechanism comprises a guide plate, an extrusion roller, processors and laser detection heads, wherein the guide plate is provided with two positions, cavities are formed in the inner sides of the two positions, the bottom end surfaces of the two guide plates are fixedly connected with two sliding blocks with the same size in a transverse array mode, the extrusion roller is installed in the guide plate in a transverse array mode, the processors are provided with four positions, each two processors are in one group, the two groups of processors are installed at the inner side positions of the two guide plates respectively, the laser detection heads are installed on the inner sides of the two processors, and the two guide plates are connected with the inner side position of the processing table in a sliding mode through the sliding blocks fixedly connected with the bottoms of the two guide plates respectively in the installation state;

further, step mechanism is including drive block, baffle, synchronizing bar, the board and the limiting plate of lifting, the synchronizing bar is equipped with two places altogether, and the outside of two synchronizing bars all installs drive block and baffle to rotate through the baffle and be connected with the board of lifting, and the top of the board of lifting is the limiting plate of horizontal array fixedly connected with same size everywhere, lies in left synchronizing bar under the installation state and installs the rear side position at the motor.

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

in the invention, when in use, because the connecting rod is provided with two positions which are connected with each other in a rotating way, the right sides of the two connecting rods are also provided with the guide gear, the driven gear is provided with two positions, the driven gear positioned at the rear side is engaged and driven at the rear side position of the guide gear, and the diameter of the driven gear is smaller than that of the guide gear, when in use, the driven gear is driven by starting the driving motor, and simultaneously drives the two racks to synchronously move in opposite directions by the driven gear, so as to drive the two guide plates to approach to the inner sides, and because the guide plates are internally provided with the extrusion rollers in a transverse array, the processors are provided with four positions, wherein each two processors are in one group, and two groups of processors are respectively arranged at the inner sides of the two guide plates, and the inner sides of the two processors are both provided with the laser detecting heads, the length of the insole can be measured by the laser detecting heads when the insole placed on the conveying belt is swung, thereby achieving the purpose of more practicability.

On the other hand, the cylinder is arranged on the inner side of the support in the waste screening mechanism, so that when a wrong insole is found, the air can be sucked up by the vacuum pump after the suction head is pushed downwards to contact with the insole through the starting cylinder, and the purpose of being more practical is achieved.

Drawings

Fig. 1 is a schematic axial view of the present invention.

Fig. 2 is a right side view of the present invention.

Fig. 3 is a left side view of the present invention.

Fig. 4 is a right-view structural diagram of the present invention.

Fig. 5 is a schematic front view of the present invention.

Fig. 6 is a left side view of the present invention.

Fig. 7 is a schematic top view of the present invention.

Fig. 8 is an enlarged schematic view of the structure at a in fig. 3 according to 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 processing table; 102. a base; 103. a motor; 104. a gear; 105. a chain; 106. a conveyor belt; 2. a guiding mechanism; 201. a guide gear; 202. a connecting rod; 203. a driven gear; 204. a rack; 205. a guide bar; 206. a drive motor; 3. a guide detection mechanism; 301. a guide plate; 302. extruding the roller; 303. a processor; 304. a laser probe; 4. a waste screening mechanism; 401. a support; 402. a cylinder; 403. a suction head; 404. a vacuum pump; 5. a stepping mechanism; 501. a drive block; 502. a guide plate; 503. a synchronization lever; 504. a lifting plate; 505. and a limiting plate.

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 8:

the invention provides an automatic shoe size measuring device based on textile machinery processing, which comprises: the device comprises a guide mechanism 2, a guide detection mechanism 3 and a waste screening mechanism 4, wherein the guide mechanism 2 is arranged at the left side position of a bearing mechanism 1 and is in transmission connection with the bearing mechanism 1; the guide detection mechanisms 3 are arranged at two positions, and the two guide detection mechanisms 3 are respectively arranged at the front side and the rear side of the interior of the bearing mechanism 1 and are connected with the guide mechanism 2; the waste screening mechanism 4 is arranged at the center of the top end face of the bearing mechanism 1, and the stepping mechanism 5 is further arranged on the inner side of the bearing mechanism 1; the waste screening mechanism 4 comprises a support 401, an air cylinder 402, a suction head 403 and a vacuum pump 404, wherein the support 401 is designed to be in a U-shaped structure, the air cylinder 402 is installed at the top end of the support 401, an air rod is installed at the bottom end of the air cylinder 402, the suction head 403 is installed through the air rod, the vacuum pump 404 is installed at the top end position of the suction head 403, and the U-shaped support 401 is fixedly connected to the top end face position of the processing table 101 in the installation state.

The bearing mechanism 1 includes a processing table 101, a base 102 and a motor 103, the base 102 has two positions, the two positions of the base 102 are respectively and fixedly connected to the left and right sides of the bottom end face of the processing table 101, and the motor 103 is screwed to the front end face of the base 102 on the left side through bolts.

The carrying mechanism 1 further comprises a gear 104, a chain 105 and a conveying belt 106, the gear 104 is provided with two positions, the gear 104 located on the lower side is installed at the rear side of the motor 103, the chains 105 are meshed and driven at the outer sides of the two positions of the gear 104, the conveying belt 106 is provided with two positions, and the two conveying belts 106 are respectively installed at the front side and the rear side of the inside of the processing table 101 and are in transmission connection with the motor 103.

The guide mechanism 2 comprises a guide gear 201, a connecting rod 202 and a driven gear 203, the connecting rod 202 is provided with two positions, the two connecting rods 202 are connected in a rotating mode, the guide gear 201 is further mounted on the right sides of the two connecting rods 202, the driven gear 203 is provided with two positions, the driven gear 203 located on the rear side is meshed with and drives the rear side of the guide gear 201, and the diameter of the driven gear 203 is smaller than that of the guide gear 201.

The guide mechanism 2 further comprises a guide gear 201, a rack 204, a guide rod 205 and a driving motor 206, the rack 204 is provided with two positions, the two racks 204 are respectively engaged and driven at the upper side and the lower side of the driven gear 203 located at the front side, the guide rod 205 is designed to be an L-shaped structure, the guide rod 205 is fixedly connected to the right side face of the rack 204 located at the lower side, the driving motor 206 is installed at the rear side positions of the two connecting rods 202, and the guide rod 205 is fixedly connected to the bottom end face of the guide plate 301 located at the right side in the installation state.

Wherein, direction detection mechanism 3 is including deflector 301, squeeze roller 302, treater 303 and laser detecting head 304, deflector 301 is equipped with two altogether, and the cavity has all been seted up to the inboard of two places, and the bottom face of two places deflector 301 all is the slider of horizontal array fixedly connected with two equidimensions, squeeze roller 302 is installed to the inside of deflector 301 being horizontal array, treater 303 is equipped with four altogether, wherein per two treater 303 is a set of, and two sets of treater 303 are installed respectively in the inboard position of two places deflector 301, and laser detecting head 304 is all installed to the inboard of two treater 303, two place deflectors 301 are respectively through the inboard position of its bottom fixed connection's slider sliding connection processing platform 101 under the installation status.

Wherein, step mechanism 5 is including drive block 501, baffle 502, synchronizing bar 503, board 504 and the limiting plate 505 of lifting, and synchronizing bar 503 is equipped with two altogether, and drive block 501 and baffle 502 are all installed to the outside of two synchronizing bar 503, and rotate through baffle 502 and be connected with the board 504 of lifting, and the top of the board 504 of lifting is horizontal array fixedly connected with limiting plate 505 of same size everywhere, and the rear side position at motor 103 is installed to the synchronizing bar 503 that lies in the left under the installation state.

When in use: firstly, the device is fixed to a proper position through two bases 102 fixedly connected with the bottom end of a processing table 101 in a bearing mechanism 1, then the insole is placed on a conveying belt 106 arranged on the inner side of the processing table 101 and is conveyed through a motor 103, in the conveying process, the guide plate 301 is provided with two positions, cavities are formed in the inner sides of the two positions, the bottom end surfaces of the two guide plates 301 are transversely and fixedly connected with two sliders with the same size in an array mode, therefore, when the insole is used, the connecting rod 202 is provided with two positions, the two connecting rods 202 are rotatably connected with each other, the guide gear 201 is further arranged on the right side of the two connecting rods 202, the driven gear 203 is provided with two positions, the driven gear 203 on the rear side is meshed with and driven at the rear side of the guide gear 201, the diameter of the driven gear 203 is smaller than that of the guide gear 201, and therefore, when the insole is used, the insole can be driven through the driving motor 206 and simultaneously drive the two positions through the driven gear 203 The rack 204 carries out synchronous movement in opposite directions to further drive the two guide plates 301 to approach to the inner side, and because the extrusion rollers 302 are transversely arranged in the guide plates 301 in an array manner, the processors 303 are provided with four positions, wherein each two processors 303 are one group, the two groups of processors 303 are respectively arranged at the inner side positions of the two guide plates 301, and the inner sides of the two processors 303 are respectively provided with the laser detecting heads 304, the length of the insole can be measured through the laser detecting heads 304 when the insole placed on the conveying belt 106 is swung, and the purpose of being more practical is further achieved;

on the other hand, the cylinder 402 is arranged on the inner side of the bracket 401 in the waste screening mechanism 4, so when a wrong-placed insole is found, the air cylinder 402 can be started to push the suction head 403 downwards to contact with the insole, and then the vacuum pump 404 extracts air to suck the insole, thereby achieving the purpose of more practicability.

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 shoes sign indicating number automatic measuring device based on textile machinery processing which characterized in that: the waste screening device comprises a guide mechanism (2), a guide detection mechanism (3) and a waste screening mechanism (4), wherein the guide mechanism (2) is arranged at the left side position of a bearing mechanism (1) and is in transmission connection with the bearing mechanism (1); the guide detection mechanisms (3) are arranged at two positions, and the two guide detection mechanisms (3) are respectively arranged at the front side and the rear side of the interior of the bearing mechanism (1) and are connected with the guide mechanism (2); the waste screening mechanism (4) is arranged at the center of the top end face of the bearing mechanism (1), and the inner side of the bearing mechanism (1) is also provided with a stepping mechanism (5); waste screening mechanism (4) are including support (401), cylinder (402), suction head (403) and vacuum pump (404), support (401) are U-shaped structural design, and cylinder (402) are installed on the top of support (401), and the gas pole is installed to the bottom of cylinder (402) to suction head (403) are installed through the gas pole, the top position at suction head (403) is installed in vacuum pump (404), and U-shaped support (401) fixed connection is in the top terminal surface position of processing platform (101) under the installation state.

2. The automatic shoe size measuring device based on textile machining according to claim 1, characterized in that: the bearing mechanism (1) comprises a processing table (101), a base (102) and a motor (103), wherein the base (102) is provided with two positions, the two bases (102) are respectively and fixedly connected to the left side and the right side of the bottom end face of the processing table (101), and the motor (103) is screwed on the front end face of the base (102) on the left side through bolts.

3. The automatic shoe size measuring device based on textile machining according to claim 2, characterized in that: the bearing mechanism (1) further comprises a gear (104), a chain (105) and a conveying belt (106), the gear (104) is provided with two positions, the gear (104) located on the lower side is installed at the rear side position of the motor (103), the chains (105) are meshed and driven on the outer sides of the two gears (104), the conveying belt (106) is provided with two positions, and the two conveying belts (106) are installed at the front side position and the rear side position inside the processing table (101) respectively and are in transmission connection with the motor (103).

4. The automatic shoe size measuring device based on textile machining according to claim 1, characterized in that: the guide mechanism (2) comprises a guide gear (201), a connecting rod (202) and a driven gear (203), wherein the connecting rod (202) is provided with two positions, the two connecting rods (202) are connected in a rotating mode, the guide gear (201) is further installed on the right side of the two connecting rods (202), the driven gear (203) is provided with two positions, the driven gear (203) located on the rear side is meshed with and drives the rear side of the guide gear (201), and the diameter of the driven gear (203) is smaller than that of the guide gear (201).

5. The automatic shoe size measuring device based on textile machining according to claim 1, characterized in that: the guide mechanism (2) further comprises a rack (204), a guide rod (205) and a driving motor (206), wherein the rack (204) is provided with two positions, the two racks (204) are respectively meshed with and transmit the upper side position and the lower side position of a driven gear (203) positioned on the front side, the guide rod (205) is in an L-shaped structural design, the guide rod (205) is fixedly connected to the right side surface position of the rack (204) positioned on the lower side, the driving motor (206) is installed at the rear side positions of connecting rods (202) positioned on the two positions, and the guide rod (205) is fixedly connected to the bottom end surface position of a guide plate (301) positioned on the right side in the installation state.

6. The automatic shoe size measuring device based on textile machining according to claim 1, characterized in that: the guide detection mechanism (3) comprises a guide plate (301), an extrusion roller (302), a processor (303) and a laser probe (304), the guide plate (301) is provided with two positions, the inner sides of the two positions are both provided with a cavity, and the bottom end surfaces of the two guide plates (301) are fixedly connected with two sliding blocks with the same size in a transverse array manner, extrusion rollers (302) are transversely arranged in the guide plate (301), the processor (303) is provided with four positions, wherein every two processors (303) are in one group, and the two groups of processors (303) are respectively arranged at the inner side positions of the two guide plates (301), and the inner sides of the two processors (303) are respectively provided with a laser probe (304), and the two guide plates (301) are respectively connected with the inner side position of the processing table (101) in a sliding way through sliders fixedly connected with the bottoms of the guide plates in the installation state.

7. The automatic shoe size measuring device based on textile machining according to claim 1, characterized in that: step mechanism (5) are including drive block (501), baffle (502), synchronizing bar (503), board (504) and limiting plate (505) lift, synchronizing bar (503) are equipped with two places altogether, and drive block (501) and baffle (502) are all installed in the outside of two synchronizing bar (503) to rotate through baffle (502) and be connected with board (504) of lifting, and the top of board (504) of lifting is limiting plate (505) of the same size of horizontal array fixedly connected with everywhere, lie in left synchronizing bar (503) under the installation state and install the rear side position at motor (103).

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