CN108813765B - Glove turn-over machine - Google Patents

Abstract

The invention provides a glove turn-over machine, which relates to the field of glove equipment and comprises a turn-over mechanism and an electrical control system, wherein the turn-over mechanism comprises a table top, a first upper rotating seat, a first lower rotating seat, a second upper rotating seat, a second lower rotating seat, a rotating body, a hand mould, a plurality of photoelectric switches and the like, and the electrical control system comprises a PLC, a relay, an electromagnetic valve, a pneumatic ball valve, a suction-blowing dual-purpose vortex air pump, a counting screen and the like, wherein the first upper rotating seat, the first lower rotating seat, the second upper rotating seat, the second lower rotating seat, the rotating body, the hand mould and the like are respectively arranged correspondingly in front and back along a table top panel; the electrical control system can be matched with the turn-over mechanism by controlling the on/off state of each electrical device to realize a quick, simple and efficient glove turn-over process; compared with the existing turn-over machine, the invention has simple structure and can reduce cost and energy consumption.

Description

Glove turn-over machine

Technical Field

The invention belongs to the field of glove equipment, and particularly relates to a glove turn-over machine.

Background

The knitting glove adopts the sewing technology in the processing and manufacturing process, the joint parts are sewn together, the glove is sewn from the back surface for the attractive appearance of the glove, after the sewing is finished, the glove is turned over, the surface with a flat appearance is used as the front surface, and the sewing parts are hidden in the front surface, so that the glove needs to be turned over manually or semi-manually.

The purely manual mode has low efficiency, so that the mode of mainly taking machinery and manually as auxiliary is mainly adopted. The conventional glove turn-over machine is provided with a main hand mould, a glove is sleeved on the main hand mould manually, the turn-over machine controls the main hand mould to rotate to the other side, fingertips of the main hand mould are abutted against the auxiliary hand mould or other abutting pieces to be fixed, and the glove is reversely pulled from the edge to be sleeved on the auxiliary hand mould or reversely pulled to be directly pulled out. Or the main hand mould is not rotated to the other side, and is directly propped against the auxiliary hand mould or other propping pieces in situ to turn over.

The turnover machine has the advantages of complicated parts, complex structure, large volume and high price, and the turnover process needs to be rotated or reversely pulled, and the operation process needs a certain time, so that the improvement of the working efficiency is limited in practice. In addition, existing turn-over machines can only be used for single worker turn-over operations.

Based on this, the present application is presented.

Disclosure of Invention

In order to solve the problems of complex structure and high cost of the turn-over machine in the prior art, the invention provides the glove turn-over machine which has the advantages of simple structure, convenient use and higher efficiency, so as to reduce the cost and occupy the space.

In order to achieve the above purpose, the invention adopts the following scheme: the glove turn-over machine comprises an electric control system, a hand mould structure body, a table top, an air pump and a sensor, wherein the hand mould structure body comprises a main body and a hand mould, and the hand mould is fixed on the main body. The sensor is arranged relative to the hand mould according to its detection mode. The hand mould structure body is fixed or rotatably fixed on the table top at a certain angle by intersecting the hand mould and the table top. The hand model comprises a plurality of finger tubes corresponding to the glove index number, wherein the finger tubes are tubular objects with openings/open holes at two ends, and the finger tubes are communicated with the air pump in a sealing way through an air pipe. The electric control system comprises a controller and a valve arranged on the air pipe, the sensor is electrically connected with the input end of the controller, and the controller drives the valve to open/close.

The sensor is used for detecting the state of the glove and generating corresponding signals to the controller.

The invention is further provided as follows: in order to realize the installation of the finger tubes, the main body is provided with connecting holes not less than the number of the finger tubes, and the finger tubes are fixed on the main body through the connecting holes and are communicated with the air pump.

Preferably, the main body is provided with a duct connecting body with a plurality of connecting holes and an air duct connecting body for fixing and connecting the air duct, and the air duct connecting body is communicated with the duct connecting body in the main body. Through the dactylotheca connector, the dactylotheca can be more conveniently fixed in on the main part, can also be convenient for simultaneously to the arrangement of dactylotheca, the degree of depth of inserting design to accord with actual glove's shape, the sleeve of being convenient for more put gloves. Through the tuber pipe connector, make the tuber pipe can be fixed in on the tuber pipe connector, realize with the airtight intercommunication of dactylotheca.

The invention is further provided as follows: the valve includes a first pneumatic ball valve and at least one secondary pneumatic ball valve. The electric control system also comprises a first control electromagnetic valve, a secondary control electromagnetic valve, a main relay and a secondary relay, wherein the secondary control electromagnetic valve is corresponding to the secondary pneumatic ball valve in number, and the main relay and the secondary relay are respectively and electrically connected with the input ends of the first control electromagnetic valve and the secondary control electromagnetic valve. The main relay is provided with another output contact which is electrically connected with the input end of the controller. The secondary relay is electrically connected with the output end of the controller. The output ends of the first control electromagnetic valve and the secondary control electromagnetic valve are respectively and correspondingly electrically connected with the first pneumatic ball valve and the secondary pneumatic ball valve. The secondary pneumatic ball valve is arranged on a loop connected with the air pipe, and the first pneumatic ball valve is arranged on a loop connected with the air pump.

The pipe fitting is a pipeline which is arranged for enabling the air pump to be communicated with each pneumatic ball valve, when the secondary pneumatic ball valves are closed at the same time, the first pneumatic ball valve is opened, so that the air pump can suck air from the outside to keep balance inside the air pump when the air inside is insufficient.

The secondary pneumatic ball valve combines the sensor signal and the controller to control whether to suck the air in the hand mould or not so as to adapt to the requirement of the turning process. That is, the number of secondary pneumatic ball valves corresponds to the number of hand dies in the turn-over mechanism/the number of circuits that need to be pumped down, which is increased or decreased according to specific needs.

The first control solenoid valve and the secondary control solenoid valve are used for auxiliary control of the first pneumatic ball valve and the secondary pneumatic ball valve respectively. The main relay and the secondary relay are respectively used for controlling the power-on state of the electromagnetic valve so as to control whether the electromagnetic valve works or not.

The controller controls the secondary pneumatic ball valve to be opened/closed according to the signal transmitted by the sensor so as to meet the process requirement of glove turn-over.

The invention is further provided as follows: the normally closed contact of the secondary relay is connected in series with the normally open contact of the main relay.

The normally closed contact of the secondary relay is connected with the normally open contact of the main relay in series, so that when any secondary relay is electrified or is electrified to work at the same time, the first control electromagnetic valve is not electrified, and the first pneumatic ball valve is in a closed state; therefore, the influence on the working efficiency and the effect of the secondary pneumatic ball valve caused by the opening of the first pneumatic ball valve can be avoided, and the energy waste is reduced.

The invention is further provided as follows: the sensor is at least one of an infrared sensor, a proximity switch and a photoelectric switch.

The invention is further provided as follows: the air pump is at least one of an air extracting device, an air pump and a vortex air pump for sucking and blowing.

The invention is further provided as follows: the sensor comprises a first photoelectric switch and a second photoelectric switch which are close to the finger tube, wherein one end of the finger tube, which is connected with the main body, is the rear end, the second photoelectric switch is positioned above the end part of the front end of the finger tube and the vicinity thereof, and the first photoelectric switch is positioned above the rear end edge of the finger tube and the vicinity thereof when the glove is positioned on the finger tube.

The invention is further provided as follows: the first photoelectric switch and the second photoelectric switch are detachably fixed on a mounting plate, the mounting plate is provided with at least two long-eye through grooves along the axial direction of the finger tube, and the first photoelectric switch and the second photoelectric switch are detachably fixed in the corresponding long-eye through grooves; the mounting plate is fixed on the mounting plate fixing block; the mounting panel fixed block sets firmly in a plurality of dactylotheca, and is close dactylotheca rear end.

The invention is further provided as follows: the first relay is electrically connected with a change-over switch in front, and the output end of the change-over switch is electrically connected with the air pump.

The invention is further provided as follows: in order to simultaneously provide two workers with turning actions, the number of the hand mould structures is 2, and the hand mould structures are oppositely arranged on two sides of the table top.

The invention is further provided as follows: in order to realize rapid counting of the glove, a display screen for displaying counting is further arranged above the table top, and the display screen is electrically connected with the output end of the controller.

The invention has the following technical effects: the invention adopts a suction mode to suck the finger tips of the glove to assist the manual turning action of the glove, and designs a turning mechanism which skillfully utilizes two operation steps of putting the glove into a hand mould and taking the glove out of the hand mould, and realizes the rapid turning of the glove by combining the reverse pulling of the glove and the finger tip adsorption of the glove; the invention further designs an electrical control system according to the turn-over mechanism, so that the electrical control system and the turn-over mechanism have higher suitability, and the electrical control system can be matched with the turn-over mechanism by controlling the on/off states of all electrical devices to realize a quick, simple and efficient glove turn-over process.

Drawings

Fig. 1 is a perspective assembly view of a glove turn-up machine of the present invention.

Fig. 2 is an exploded perspective view of the turn-over mechanism of the glove turn-over machine of the present invention.

Fig. 3 is a perspective assembly view of a turn-over mechanism of the glove turn-over machine of the present invention.

Fig. 4 is a schematic diagram of an electrical control system of the glove turn-over machine of the present invention.

In the figure: 1. a turn-over mechanism; 2. an electrical control system; 11. a rotating body; 11a, vial connectors; 11b, an air duct connector; 11c, shaft heads; 11d, a main body; 12. thumb tube; 13. a forefinger tube; 14. middle finger tube; 15. a ring finger tube; 16. a little finger tube; 17. a mounting plate; 17a, a second long-eye through groove; 17b, a first long-eye through groove; 18. a first upper rotating seat; 19. a mounting plate fixing block; 110. a second upper rotating seat; 111. a table top; 111a, a panel; 111a1, a square through groove of the panel; 111b, a first panel support beam; 111c, a panel second support longeron; 112. a housing; 113. a first lower rotating seat; 114. a second lower rotating seat; 115. a first photoelectric switch; 116. and a second photoelectric switch.

Detailed Description

The invention is further described in connection with the following detailed description, in order to make the technical means, the creation characteristics, the achievement of the purpose and the effect of the invention easy to understand.

As shown in fig. 1, 2 and 3, the invention provides a glove turn-over machine, which comprises an electric control system, a hand mould structure body, a sensor, a table top 111 and a suction-blowing dual-purpose vortex air pump, wherein the hand mould structure body comprises a rotating body 11 and a hand mould.

The hand model consists of five finger tubes, namely a thumb tube 1212, an index finger tube 13, a middle finger tube 14, a ring finger tube 15 and a little finger tube 16, and the finger tubes are tubular materials with openings at two ends. The sensor is arranged in relation to the hand mould in accordance with its detection means for detecting a specific state of the glove (here state means whether there is a glove in the correct position on the hand mould, whether the glove has been or is about to be released from the hand mould).

The rotator 11 is composed of a main body 11d, a finger pipe connector 11a, an air pipe connector 11b and a shaft head 11 c; the duct connecting body 11a is provided with a plurality of through holes for inserting the duct, the through holes are positioned on the upward side of the main body 11d, the duct connecting body 11b is a connecting piece communicated with the duct connecting body 11a in a sealing way, the duct connecting body is positioned on the downward side of the main body 11d, two ends of the main body 11d are respectively provided with a shaft head 11c, and the shaft heads 11c are provided with shaft stops. The vial is inserted and fixed in the vial connector 11a side by side through a through hole formed in the housing 112. The loop between the air pipe connector 11b and the suction and blowing dual-purpose vortex air pump is communicated through an air pipe.

The table top 111 is composed of a panel 111a, a first supporting beam and a second supporting beam, wherein the first supporting beam and the second supporting beam are respectively positioned at two sides of the bottom of the panel 111a and used for supporting the panel 111a and the hand model structure body, the square through groove 111a1 is formed in the panel 111a of the table top 111, and the square through groove is correspondingly arranged in the front and the back along the panel 111a of the table top 111, and the square through groove 111a1 is used for placing the hand model structure body.

The table top 111 is provided with a first lower rotating seat 113 and a second lower rotating seat 114, the first lower rotating seat 113 and the second lower rotating seat 114 are respectively and fixedly arranged on a second supporting longitudinal beam 111c of the panel 111a and a first supporting longitudinal beam 111b of the panel 111a, the left side and the right side of the first lower rotating seat 113 and the second lower rotating seat 114 are corresponding to each other, the cover shell 112 is covered on the rotating body 11, the rotating body 11 is respectively arranged on semicircular placing holes of the first lower rotating seat 113 and the second lower rotating seat 114 through shaft heads 11c at two ends of the rotating body, and the angles of the hand molds relative to the table top 111 are adjusted according to requirements, so that after shaft blocks arranged on the shaft heads 11c are matched with the first lower rotating seat 113 and the second lower rotating seat 114, the first upper rotating seat 18 and the second upper rotating seat 110 are respectively matched with the first lower rotating seat 113 and the second lower rotating seat 114 to fix the shaft heads 11c therein.

In this embodiment, the number of the hand mold structures is 2, namely a first hand mold structure and a second hand mold structure, the first hand mold structure and the second hand mold structure are identical in structure and are arranged on two opposite sides of the table top 111 in a back-to-back manner, and the first hand mold structure is located on the front side of the table top 111.

As shown in fig. 4, the electrical control system includes a valve, a first control solenoid valve, a plurality of secondary control solenoid valves, a main relay, and a secondary relay. The valve is divided into a first pneumatic ball valve and a plurality of secondary pneumatic ball valves. In this embodiment, the controller is a PLC, the first relay is a main relay, and the second pneumatic ball valve and the third pneumatic ball valve are secondary pneumatic ball valves. The second control electromagnetic valve and the third control electromagnetic valve are secondary control electromagnetic valves, and the output ends of the secondary control electromagnetic valve and the third control electromagnetic valve are respectively and correspondingly electrically connected with the input ends of the second pneumatic ball valve and the third pneumatic ball valve. The second relay and the third relay are secondary relays, the output ends of the secondary relays are respectively and electrically connected with the second control electromagnetic valve and the third control electromagnetic valve, and the input ends of the secondary relays are electrically connected with the output ends of the PLC.

The front of the first relay is electrically connected with a change-over switch, and the suction and blowing dual-purpose vortex air pump is electrically connected with the change-over switch; and the air switch is electrically connected before the change-over switch and the stabilized voltage supply.

The normally closed contacts of the second relay and the third relay are connected in series with the normally open contact of the first relay; meanwhile, the output contact of the first relay is electrically connected with the input end of the PLC and the input end of the first control electromagnetic valve, and the output end of the first control electromagnetic valve is electrically connected with the input end of the first pneumatic ball valve. When any one of the second relay and the third relay works or works simultaneously, the first pneumatic ball valve is correspondingly closed, so that the influence on the normal work of the second pneumatic ball valve and the third pneumatic ball valve caused by the working of the first pneumatic ball valve is avoided.

The signal output end of the sensor is electrically connected with the input end of the PLC, the sensor comprises a first photoelectric switch 115, a second photoelectric switch 116, a third photoelectric switch and a fourth photoelectric switch, the first photoelectric switch 115 and the second photoelectric switch 116 are matched with a first hand model structure body, and the third photoelectric switch and the fourth photoelectric switch are matched with a second hand model structure body. Taking the first hand model structure as an example, the second photoelectric switch 116 is located above and near the end of the front end of the vial (in this embodiment, the end of the vial connected with the vial connector 11a is the rear end, and the other end is the front end), and the first photoelectric switch 115 is located above and near the rear edge of the glove when the glove is located on the vial; the second photoelectric switch 116 and the first photoelectric switch 115 are respectively arranged corresponding to the second long-eye through groove 17a and the first long-eye through groove 17b which are arranged on the mounting plate fixing block 1917, and specific positions are that the first photoelectric switch 115, the second photoelectric switch 116 and the hand mould are close enough to detect the dynamic state of the glove on the hand mould, and the positions are adjusted adaptively according to the field condition. The mounting plate fixed block 1917 is combined with a mounting plate fixed block 1917 and is in a vertical position, and the mounting plate fixed block 1917 is fixedly arranged on the thumb tube 1212 and the index finger tube 13 and is close to the rear end of the thumb tube.

A display screen for displaying the count is also arranged above the table top 111, and the display screen is electrically connected with the output end of the PLC.

The first pneumatic ball valve, the second pneumatic ball valve and the third pneumatic ball valve are arranged between the suction and blowing dual-purpose vortex air pump and the pipe fitting, the suction and blowing dual-purpose vortex air pump is communicated with the first pneumatic ball valve, the second pneumatic ball valve and the third pneumatic ball valve through the pipe fitting, when the second pneumatic ball valve and the third pneumatic ball valve are closed at the same time, the first pneumatic ball valve is opened and communicated with the pipe fitting and the suction and blowing dual-purpose vortex air pump, so that the suction and blowing dual-purpose vortex air pump can suck air from the outside to keep internal balance when the internal air is insufficient; the second pneumatic ball valve and the third pneumatic ball valve are used for controlling whether the finger tube is communicated with the suction and blowing dual-purpose vortex air pump or not.

The working process of the invention is as follows: taking the first hand mould structure as an example, after the power supply is switched on, an air switch is closed, a voltage-stabilized power supply acts, a change-over switch is closed again, a suction and blowing dual-purpose vortex air pump is started and works all the time, and a first relay is switched on with the PLC; the worker is sleeved on the hand mould, when the rear end edge of the glove is detected by the first photoelectric switch 115, the first photoelectric switch 115 generates a signal and transmits the signal to the PLC, the PLC transmits a signal to the second relay, then the second relay is attracted, the second control electromagnetic valve is connected with the second pneumatic ball valve and provides attraction force, then the fingertips of the glove are sucked into the fingertips, then the worker performs glove turning action, the glove edge is pulled reversely, after the second photoelectric switch 116 detects that the glove is peeled off, the second photoelectric switch 116 generates a signal and transmits the signal to the PLC, then the PLC transmits a signal to the second relay, then the second relay is not attracted, then the second control electromagnetic valve closes the second pneumatic ball valve, then the attraction force in the hand mould disappears, and then the PLC outputs the count after adding 1 to the count screen for display. The third photoelectric switch, the fourth photoelectric switch, the third relay, the third electromagnetic valve, the third pneumatic ball valve, the counting screen and the PLC are matched with a hand model structural body and the like arranged at the rear part of the table top 111, the working principle is identical with that of the hand model structural body and the like arranged at the front part correspondingly, and the working principle is mutually independent and non-interfering, and is not repeated; the above procedure is then repeated.

Based on the above, the invention provides a glove turn-over machine which adopts a suction mode to suck the fingertips of the glove and assist the manual turn-over action of the glove, which skillfully utilizes two operation steps of putting the glove into a hand mould and taking the glove out of the hand mould, and combines an electric control system to adsorb the fingertips of the glove when the glove is pulled reversely after the glove is put into the hand mould, and then combines the eversion action of the glove to realize the rapid turn-over of the glove. The turn-over mechanism 1 (sensor, hand mold structure, table top 111, etc.) has simple structure, low cost and convenient maintenance and use, and the electric control system can realize a rapid, simple and efficient glove turn-over process by controlling the on/off state of each electric device and matching with the turn-over mechanism 1, thereby being applicable to turn-over of similar knitted gloves, non-knitted gloves, etc.

It will be appreciated by those skilled in the art that the present invention can be carried out in other embodiments without departing from the spirit or essential characteristics thereof. Accordingly, the above disclosed embodiments are illustrative in all respects, and not exclusive. All changes that come within the scope of the invention or equivalents thereto are intended to be embraced therein.

Claims (9)

1. Glove turn-over machine, its characterized in that: the hand mould structure comprises a rotating body and a hand mould, wherein the rotating body consists of a main body, a finger pipe connecting body, an air pipe connecting body and shaft heads arranged at two ends of the main body, the shaft heads are provided with shaft stops, the hand mould is fixed on the main body, and the sensor is arranged opposite to the hand mould according to the use mode of the sensor; the hand model comprises a plurality of finger tubes corresponding to the glove index number, the finger tubes are tubular objects with openings/open holes at two ends, a plurality of through holes for inserting the finger tubes are arranged on the finger tube connecting body and are positioned at the upward side of the main body, the air pipe connecting body is a connecting piece which is hermetically communicated with the finger tube connecting body and is positioned at the downward side of the main body, and the air pipe connecting body is hermetically communicated with the air pump through an air pipe; the electric control system comprises a controller and a valve arranged on the air pipe, the sensor is electrically connected with the input end of the controller, and the controller drives the valve to open/close;

the table top is provided with a lower rotating seat below the shaft head, an upper rotating seat is arranged above the shaft head, semicircular holes are formed in the faces, close to the shaft heads, of the upper rotating seat and the lower rotating seat, the shaft heads at two ends of the rotating body are respectively placed on the semicircular holes of the corresponding lower rotating seat, the angle of the hand die relative to the table top is adjusted according to the requirement, and after the angle is adjusted to a proper angle, the upper rotating seat is connected with the lower rotating seat to fix the shaft heads.

2. The glove turn-up machine according to claim 1, wherein: the valve comprises a first pneumatic ball valve, at least one secondary pneumatic ball valve, a first control electromagnetic valve, secondary control electromagnetic valves, a main relay and a secondary relay, wherein the number of the secondary control electromagnetic valves corresponds to that of the secondary pneumatic ball valves, and the main relay and the secondary relay are respectively and electrically connected with the input ends of the first control electromagnetic valve and the secondary control electromagnetic valves; the main relay is provided with another output contact which is electrically connected with the input end of the controller; the secondary relay is electrically connected with the output end of the controller; the output ends of the first control electromagnetic valve and the secondary control electromagnetic valve are respectively and correspondingly electrically connected with the first pneumatic ball valve and the secondary pneumatic ball valve, the secondary pneumatic ball valve is arranged on a loop connected with an air pipe, and the first pneumatic ball valve is arranged on a loop connected with an air pump.

3. The glove turn-up machine according to claim 2, wherein: the normally closed contact of the secondary relay is connected in series with the normally open contact of the main relay.

4. A glove inversion machine as claimed in any one of claims 1 to 3, wherein: the sensor is at least one of an infrared sensor, a proximity switch and a photoelectric switch; the air pump is at least one of an air extracting device, an air pump and a vortex air pump for sucking and blowing.

5. A glove inversion machine as claimed in any one of claims 1 to 3, wherein: the sensor comprises a first photoelectric switch and a second photoelectric switch which are close to the finger tube, wherein one end of the finger tube, which is connected with the connecting hole, is the rear end, the second photoelectric switch is positioned above the end part of the front end of the finger tube and the vicinity thereof, and the first photoelectric switch is positioned above the rear end edge of the finger tube and the vicinity thereof when the glove is positioned on the finger tube.

6. The glove turn-up machine according to claim 5, wherein: the first photoelectric switch and the second photoelectric switch are detachably fixed on a mounting plate, the mounting plate is provided with at least two long-eye through grooves along the axial direction of the finger tube, and the first photoelectric switch and the second photoelectric switch are detachably fixed in the corresponding long-eye through grooves; the mounting plate is fixed on the mounting plate fixing block; the mounting panel fixed block sets firmly in a plurality of dactylotheca, and is close dactylotheca rear end.

7. The glove turn-up machine according to claim 2, wherein: the first relay is electrically connected with a change-over switch in front, and the output end of the change-over switch is electrically connected with the air pump.

8. The glove turn-up machine according to claim 1, wherein: the number of the hand mould structures is 2, and the hand mould structures are oppositely arranged at two sides of the table top.

9. The glove turn-up machine according to claim 1, wherein: a display screen for displaying the count is arranged above the table top, and the display screen is electrically connected with the output end of the controller.