CN216501760U - Pressure device and pressure production line - Google Patents

Abstract

The application discloses a pressurizing device, which comprises a reciprocating conveying mechanism, a bearing table and a pressurizing mechanism, wherein the reciprocating conveying mechanism is in driving connection with the bearing table, the pressurizing mechanism is arranged on one side of the reciprocating conveying mechanism, the reciprocating conveying mechanism can drive the bearing table to move in a reciprocating mode between a first transferring position and a pressurizing position and between a second transferring position and the pressurizing position, and when the bearing table is switched to the pressurizing position, the pressurizing mechanism can pressurize a part on the bearing table, so that the part on the station of the previous process can be transferred to the pressurizing position through the first transferring position and/or the second transferring position after entering the pressurizing station, and the pressurizing process is completed; and the part accessible that accomplishes the pressurization process is transported to next process station through first transfer position and/or second transfer position, and to sum up, this kind of setting makes the pressurization process need not to arrange the operation personnel specially and carry out the transportation between operation and the process to effectively reduce manufacturing cost, this application still discloses a pressurization production line.

Description

Pressure device and pressure production line

Technical Field

The application relates to the field of pressure equipment, in particular to a pressurizing device and a pressurizing production line.

Background

Parts that require forming by pressing such as punching, blanking and hot heading are generally mass-produced in a production line. In the related art production line, a special operator must be arranged for the part pressing process, for example, the operator in the pressing process needs to obtain the parts transferred from the previous process, operate the pressing device to press, and send the parts completing the pressing process to the next process, which is cumbersome and increases the cost.

SUMMERY OF THE UTILITY MODEL

The application discloses pressure device and pressurization production line to solve part pressurization process complex operation, will increase cost's problem.

In order to solve the above problems, the following technical solutions are adopted in the present application:

the application provides a pressure device, including reciprocal transport mechanism, plummer and loading mechanism, the plummer is connected in the drive of reciprocal transport mechanism, loading mechanism locates reciprocal transport mechanism one side, reciprocal transport mechanism can drive the plummer and carry out reciprocating motion between first transport position and pressurization position and between second transport position and pressurization position, when the plummer removes to the circumstances of pressurization position along with reciprocal transport mechanism, loading mechanism can pressurize the part that is located on the plummer.

Further, the pressurizing device further comprises a control unit, a first position controller and a second position controller; the first position controller is arranged at the first transfer position, and the second position controller is arranged at the second transfer position; the control unit is respectively and electrically connected with the first position controller, the second position controller and the reciprocating transmission mechanism; under the condition that the bearing table moves to a first transfer position along with the reciprocating conveying mechanism, the first position controller outputs a first position signal to the control unit, and the control unit controls the reciprocating conveying mechanism to stop moving according to the first position signal; and under the condition that the bearing table moves to the second transfer position along with the reciprocating conveying mechanism, the second position controller outputs a second position signal to the control unit, and the control unit controls the reciprocating conveying mechanism to stop moving according to the second position signal.

Further, the pressurizing device further comprises a third position controller; the third position controller is arranged at the pressurizing position, and the control unit is electrically connected with the third position controller and the pressurizing mechanism respectively; under the condition that the bearing table moves to the pressurizing position along with the reciprocating conveying mechanism, the third position controller outputs a pressurizing signal to the control unit, and the control unit controls the reciprocating conveying mechanism to stop moving according to the pressurizing signal and controls the pressurizing mechanism to pressurize the parts on the bearing table.

Further, the pressurizing device also comprises a first safety grating and a second safety grating; the first safety grating is arranged at the first transfer position, and the second safety grating is arranged at the second transfer position; the control unit is respectively and electrically connected with the first safety grating and the second safety grating.

Further, the pressurizing device further comprises a first starting button and a second starting button; the first starting button is arranged at the first transferring position, and the second starting button is arranged at the second transferring position; the first starting button and the second starting button are respectively and electrically connected with the control unit; when the bearing table reaches a first transferring position along with the reciprocating conveying mechanism and the first starting button is pressed down, the first starting button outputs a first starting signal to the control unit, and the control unit starts the reciprocating conveying mechanism to move to the pressurizing position according to the first starting signal; when the bearing table reaches the second transfer position along with the reciprocating conveying mechanism and the second starting button is pressed down, the second starting button outputs a second starting signal to the control unit, and the control unit starts the reciprocating conveying mechanism to move to the pressurizing position according to the second starting signal.

Furthermore, the number of the first starting buttons is two, and the number of the second starting buttons is two; under the condition that the two first starting buttons are pressed, the control unit acquires a first starting signal; in case both second activation buttons are pressed, the control unit acquires a second activation signal.

Further, reciprocating transport mechanism includes motor and lead screw, and the motor drive connects the lead screw, and the plummer cover is located the lead screw, and with lead screw fit, and under the condition of starter motor, the lead screw drives the plummer and removes along with the motor.

Further, the pressurizing device also comprises an emergency stop starting button; the emergency stop starting button is electrically connected with the control unit; under the condition that the scram starting button is pressed, the scram starting button outputs a scram signal to the control unit, and the control unit stops the current work of the pressurizing device according to the scram signal.

Further, the reciprocating conveying mechanism can drive the bearing platform to reciprocate among the first transferring position, the pressurizing position and the second transferring position in sequence.

A part pressurization production line comprises a part transmission line and a pressurization device; a picking station, a pressurizing station and a detecting station are sequentially arranged on one side of the part transmission line; the pressurizing device is arranged at the pressurizing station, the first transferring position faces the picking station, and the second transferring position faces the detecting station; the picking station is used for picking the parts on the part conveying line to the first transferring position, and the detecting station is used for picking the parts conveyed from the pressurizing position to the second transferring position.

The other part pressurizing production line comprises a part conveying line and a pressurizing device; a first picking station, a pressurizing station and a second picking station are sequentially arranged on one side of the part conveying line; the pressurizing device is arranged at the pressurizing station, the first transferring position faces the first picking station, and the second transferring position faces the second picking station; the first picking station is used for picking the parts on the part conveying line to the first transferring position and picking the parts conveyed to the first transferring position from the pressurizing position; the second picking station is used for picking the parts on the part transmission line to the second transfer position and picking the parts transmitted to the second transfer position from the pressurizing position.

The technical scheme adopted by the application can achieve the following beneficial effects:

this through carrying out optimal design to pressure device, specifically for setting up pressure device including reciprocal transport mechanism, plummer and pressurization mechanism, reciprocal transport mechanism drive connection plummer, pressurization mechanism locates reciprocal transport mechanism one side, reciprocal transport mechanism can drive the plummer between first transfer position and pressurization position and carry out reciprocating motion between second transfer position and pressurization position, under the circumstances that the plummer switches to the pressurization position, pressurization mechanism can pressurize the part that is located on the plummer.

Therefore, after the part at the previous working position enters the pressurizing working position, the part can be transferred to the pressurizing position through the first transferring position and/or the second transferring position so as to complete the pressurizing working process; and the parts completing the pressing process can be transferred to the next process station through the first transfer position and/or the second transfer position.

In conclusion, the arrangement enables the pressurizing process to be free from specially arranging operators to carry out operation and transfer among the processes, thereby effectively reducing the manufacturing cost.

Drawings

FIG. 1 is a first state diagram of a compression device in an embodiment disclosed herein;

FIG. 2 is a second state diagram of a pressurizing device in an embodiment disclosed herein;

FIG. 3 is a third state diagram of a pressurizing device in an embodiment disclosed herein;

FIG. 4 is a fourth state diagram of a pressurizing device in an embodiment disclosed herein;

FIG. 5 is a fifth state diagram of a pressurizing device in an embodiment disclosed herein;

FIG. 6 is a diagram of a second shuttle mechanism for a compression device in accordance with an embodiment of the present disclosure;

FIG. 7 is a diagram of a fixture structure according to an embodiment of the disclosure;

FIG. 8 is a first layout of a pressurized production line in an embodiment disclosed herein;

FIG. 9 is a second layout of a pressurized production line in an embodiment disclosed herein.

Description of reference numerals:

100-reciprocating transmission mechanism,

110-motor, 120-lead screw,

200-bearing table, 300-pressurizing mechanism,

410-the first safety grating, 420-the second safety grating,

510-a first start button, 520-a second start button,

600-sudden stop start button,

710-part transmission line,

720-picking station, 730-pressurizing station, 740-detecting station,

721-a first picking station, 722-a second picking station,

800-parts, 900-tools.

Detailed Description

In order to make the objects, technical solutions and advantages of the present application more apparent, the technical solutions of the present application will be described in detail and completely with reference to the following specific embodiments of the present application and the accompanying drawings. It is to be understood that the embodiments described are only a few embodiments of the present application and not all embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present application.

Technical solutions disclosed in the embodiments of the present application are described in detail below with reference to the accompanying drawings.

The application discloses pressure device, this pressure device can be hot mound, punching press, die-cut etc. realize pressure forming's device to the part. The pressurizing means may include a shuttle mechanism 100, a carrier 200, and a pressurizing mechanism 300. The bearing table 200 is used for placing parts to be pressurized; the pressing mechanism 300 is used for pressing the part, for example, the pressing mechanism 300 is a moving punch, a hot heading, or the like; the reciprocating conveying mechanism 100 is used for driving the part to be pressurized to move to the position of the pressurizing mechanism 300 along with the bearing platform 200 so as to complete the pressure forming of the part, for example, the reciprocating conveying mechanism 100 is a track conveying mechanism, a cylinder conveying mechanism, a rack and pinion conveying mechanism, etc.

Specifically, the shuttle mechanism 100 is drivingly connected to the carrier 200, the pressing mechanism 300 is disposed at one side of the shuttle mechanism 100, and the shuttle mechanism 100 is configured to drive the carrier 200 to reciprocate between a first transfer position and a pressing position, and between a second transfer position and a pressing position. The pressing positions are the positions where the pressing mechanism 300 performs the press forming on the part, such as the first transferring position, the pressing position and the second transferring position, and the setting direction is along the conveying direction of the reciprocating conveying mechanism 100, and the pressing mechanism 300 and the pressing position are sequentially set along the pressing direction, and the conveying direction and the pressing direction intersect, and the conveying direction and the pressing direction may be set to be perpendicular to each other in this application.

When the carrier 200 moves to the pressing position with the shuttle 100, the pressing mechanism 300 can press the parts 800 on the carrier 200, thereby completing the pressing of the parts without arranging a special person to operate the pressing device. The following describes the implementation of the apparatus of the present application by way of an operational example:

the shuttle mechanism 100 is configured as described above, and the shuttle mechanism 100 may drive the carrier stage 200 to reciprocate between the first transfer position, the pressing position, and the second transfer position in sequence.

As shown in fig. 1, in a state where the pressurization is not performed, the pressurization mechanism 300 may be kept at a certain distance from the pressurization position, that is, the pressurization mechanism 300 may be raised to a certain height, for example, a first height, with respect to the pressurization position in this state.

When pressurization is required, as shown in fig. 2 and fig. 3, when the carrier 200 moves to the first transfer position along with the shuttle 100, the component 800 may be placed on the carrier 200, that is, the operator may transfer the component 800 to the carrier 200 at the first transfer position.

When the carrier 200 moves to the pressing position with the shuttle 100, the pressing mechanism 300 may press the part 800 on the carrier 200, specifically, the carrier 200 moves to the pressing position with the shuttle 100, and then the pressing mechanism 300 descends towards the pressing position until reaching the second height to complete the pressing of the part 800 on the carrier 200.

Then, as shown in fig. 4 and 5, when the carrier 200 moves to the second transfer position with the shuttle 100, the parts 800 on the carrier 200 can be picked up. Specifically, after the pressurization is completed, the pressurization mechanism 300 is lifted up to the first height again, and at the same time, the carrier table 200 moves to the second transfer position along with the reciprocating transfer mechanism 100, and the operator at the second transfer position picks up the part 800, thereby completing the pressurization work on the part 800.

In the above-described operation example, the operator at the first transfer position may be understood as performing the part feeding process, the pressing device may be understood as performing the pressing process, and the operator at the second transfer position may be understood as performing the part blanking and inspection process. It can be seen that in this operation mode, the pressing process is not performed by a special operator, and the part 800 is automatically pressed and molded after reaching the pressing position, so that the labor cost is saved, and the injury risk of the operator when operating the pressing device can be reduced.

It should be noted that the press forming of the part 800 may be performed from the second transfer position to the first transfer position, and the operator may be replaced with a pick-up mechanism of a robot, which will not be described in detail herein.

In other alternative embodiments, the specific manner of feeding and picking the parts 800 may be as follows:

an operator puts the part 800 into a first transfer position, and after the part is sent into a pressurizing position through the reciprocating conveying mechanism 100 to be pressurized, the part is sent out from the first transfer position through the reciprocating conveying mechanism 100; alternatively, the operator puts the part 800 in the second transfer position, and after the part is pressurized by the shuttle mechanism 100 at the pressurizing position, the part is sent out from the second transfer position by the shuttle mechanism 100. That is, the single side carries out the pay-off and gets material detection, and here no longer details.

Further, to enhance the intelligent control of the pressurizing device, the pressurizing device may further comprise a control unit, a first position controller and a second position controller. The first position controller and the second position controller may be photoelectric sensors, mechanical limit switches, etc. to control the position of the plummer 200. In particular. The first position controller may be located at a first transfer location and the second position controller may be located at a second transfer location. The control unit is electrically connected to the first position controller, the second position controller and the reciprocating conveying mechanism 100, for example, the control unit is a single chip microcomputer, a PLC programmable controller, etc., so as to realize signal transmission with the first position controller and the second position controller and control of the reciprocating conveying mechanism 100.

Specifically, when the carrier 200 moves to the first transfer position along with the reciprocating conveying mechanism 100, the first position controller outputs a first position signal to the control unit, and the control unit controls the reciprocating conveying mechanism 100 to stop moving according to the first position signal, so that an operator in the first transfer position can complete feeding or picking detection of the part 800.

And under the condition that the bearing platform 200 moves to the second transfer position along with the reciprocating conveying mechanism 100, the second position controller outputs a second position signal to the control unit, the control unit controls the reciprocating conveying mechanism 100 to stop moving according to the second position signal, and at the moment, an operator at the second transfer position can complete the feeding or taking detection work of the part 800.

It can be seen that, through the installation of the control unit, the first position controller and the second position controller, the reciprocating conveying mechanism 100 can automatically stop after driving the bearing platform 200 to reach the designated position, manual control is not needed, and the device tends to be more intelligent.

Similarly, the pressurizing device may further include a third position controller. The third position controller can also be a photoelectric sensor, a mechanical limit switch and the like to realize position control. And the third position controller is arranged at the pressurizing position, and the control unit is respectively and electrically connected with the third position controller and the pressurizing mechanism 300, so that the control unit can realize signal interaction with the third position controller and control over the pressurizing mechanism 300.

Specifically, in the case that the carrier 200 moves to the pressurizing position with the shuttle 100, the third position controller outputs a pressurizing signal to the control unit, and the control unit controls the shuttle 100 to stop moving according to the pressurizing signal and controls the pressurizing mechanism 300 to pressurize the part 800 on the carrier 200.

It can be seen that, by arranging the control unit and the third position controller, when the part 800 is sent to the pressurizing position, the pressurizing mechanism 300 automatically pressurizes the part 800 without manual control, so that the device tends to be more intelligent.

In a more specific embodiment, a time delay controller may also be provided in the pressurizing device. The delay controller may set a preset pressurization time, which is a pressurization time required by the component 800, and different preset pressurization times may be set according to different components. The delay controller is electrically connected with the control unit so as to perform signal interaction with the control unit.

When the pressing mechanism 300 starts pressing the part 800, the control unit controls the delay controller to start timing. And under the condition that the pressurizing time reaches the preset pressurizing time, the time delay controller outputs a time signal to the control unit, and the control unit controls the pressurizing mechanism 300 to ascend to the second height according to the time signal and controls the reciprocating conveying mechanism 100 to move so as to enable the part 800 to leave the pressurizing position along with the bearing table 200. Therefore, the arrangement of the time delay controller can further enhance the intelligent control of the pressurizing device.

Further, the pressurizing device may further include a first safety light barrier 410 and a second safety light barrier 420. The first safety barrier 410 is disposed at a first transfer location and the second safety barrier 420 is disposed at a second transfer location. The control unit is electrically connected with the first safety grating 410 and the second safety grating 420 respectively, so that the control unit performs signal interaction with the first safety grating 410 and the second safety grating 420 respectively.

This arrangement can further improve the safety performance of the device of the present application, specifically, during the normal operation of the pressurizing device, the transmitting terminal of the first safety grating 410 will continuously transmit the safety signal to the receiving terminal to the control unit, and the transmitting terminal of the second safety grating 420 will also continuously transmit the safety signal to the receiving terminal to the control unit, so that in the state that the control unit receives the safety signal, the control unit receives the safety signal and thus determines that the pressurizing device operates normally and normally, where the normal operation refers to the operation of the pressurizing device in the current state, such as the movement of the reciprocating transmission mechanism 100, the pressurizing mechanism 300, and the like.

When the operator does not perform the operation according to the operation standard, for example, the operator inserts a hand into the pressurizing device from the first transferring position or the second transferring position, at this time, the safety signal reception of the first safety light barrier 410 or the second safety light barrier 420 is interrupted, so that the control unit cannot acquire the safety signal, and in the case that the control unit does not receive the safety signal, the pressurizing device stops working, where the stopping working refers to stopping all the working in the current state, such as stopping the movement of the reciprocating transport mechanism 100 and the pressurizing mechanism 300, so as to ensure the working safety of the operator. And after the abnormal state is relieved, the pressurizing device can also return to normal operation.

Further, the pressurizing means may further include a first actuating button 510 and a second actuating button 520. The first actuator button 510 is disposed at a first transfer position and the second actuator button 520 is disposed at a second transfer position. The first and second actuating buttons 510 and 520, respectively, are electrically connected to the control unit to control the pressurizing means through the control unit.

Specifically, when the carrier 200 reaches the first transfer position along with the reciprocating conveying mechanism 100 and the first start button 510 is pressed, the first start button 510 outputs a first start signal to the control unit, and the control unit starts the reciprocating conveying mechanism 100 to move to the pressurizing position according to the first start signal, so that an operator in the first transfer position can start the pressurizing device after completing operations such as material taking detection, material feeding and the like of parts.

When the carrier 200 reaches the second transfer position along with the reciprocating conveying mechanism 100 and the second start button 520 is pressed, the second start button 520 outputs a second start signal to the control unit, and the control unit starts the reciprocating conveying mechanism 100 to move to the pressurizing position according to the second start signal, so that an operator at the second transfer position can start the pressurizing device after completing operations such as material taking detection, material feeding and the like of parts.

It can be seen that the first and second activation buttons 510 and 520 can improve the handling of the pressurizing means.

In a more specific embodiment, the first activation buttons 510 are two in number and the second activation buttons 520 are two in number. In the case where both the first start buttons 510 are pressed, the control unit acquires a first start signal; in case both second start buttons 520 are pressed, the control unit acquires a second start signal.

Under this arrangement, after the operator at the first transfer position finishes the operations of the parts, such as material taking detection and feeding, the operator must operate the first start button 510 with both hands respectively to start the pressurizing device again. Similarly, the pressurizing means can be activated again only by operating a second activation button 520 with both hands. Therefore, when the pressurizing device is started again, the hands of the operator are positioned outside the pressurizing device, and the safety performance of the operation of the equipment is further improved.

Further, the reciprocating transfer mechanism 100 provided in the present application includes a motor 110 and a lead screw 120 as shown in fig. 6. The motor 110 is connected to the lead screw 120 in a driving manner, and the plummer 200 is sleeved on the lead screw 120 and is in screw fit with the lead screw 120. Under the condition of starting the motor 110, the lead screw 120 drives the bearing table 200 to move along with the motor 110, and the motion precision can be ensured by the screw propulsion mode of the lead screw. It should be noted that the forward and reverse rotation of the motor 110 can be controlled by adjusting the voltage direction, and then the movement direction of the plummer 200 is adjusted, so as to achieve the reciprocating movement, and the detailed description is omitted here.

The pressurizing device further comprises an emergency stop start button 600, and the emergency stop start button 600 is electrically connected with the control unit. In the case where the scram start button 600 is pressed, the scram start button 600 outputs a scram signal to the control unit, and the control unit stops the current operation of the pressurizing means according to the scram signal, and similarly, the current operation here includes the movement of the reciprocating transfer mechanism 100, the pressurizing movement of the pressurizing mechanism 300, and the like, thereby further securing the personal safety of the operator.

As shown in fig. 8, the present application further provides a part pressing line including the pressing device and the part transfer line 710. A pickup station 720, a pressing station 730, and an inspection station 740 are sequentially provided at one side of the parts transfer line 710. The pressurizing device is disposed at the pressurizing station 730, the first transfer position faces the picking station 720, and the second transfer position faces the detecting station 740. Both the pick station 720 and the inspection station 740 are configured with operators.

Wherein the picking station 720 is used for an operator to pick up the parts 800 on the parts transporting line 710 to a first transfer position. Inspection station 740 is used for an operator to pick up parts 800 that are transferred from the pressing position to the second transfer position. Specifically, the following steps can be followed:

the operator at the picking station 720 picks up a plurality of parts 800 on the part conveying line 710 and places the picked parts into the jig 900 shown in fig. 7, and then places the jig 900 together with the plurality of parts 800 onto the carrier 200 at the first transfer position.

After the material is taken, the first start button 510 is pressed to start the reciprocating conveying mechanism 100, so as to drive the bearing platform 200 to move to the pressurizing position.

After the carrier 200 reaches the pressing position, the pressing mechanism 300 presses and forms the part 800.

After the pressure forming is completed, the reciprocating transfer mechanism 100 drives the carrier 200 to move to the second transfer position.

After the carrier 200 reaches the second transfer position, the operator at the inspection station 740 takes out the part 800 together with the jig 900.

After the part 800 is taken out, the jig 900 is placed back to the carrier 200, and the second start button 520 is pressed to start the reciprocating transmission mechanism 100, so as to drive the carrier 200 and the jig 900 to return to the first transfer position. While at inspection station 740 the operator performs a quality inspection of the removed part 800.

The process is continuously circulated, and it can be seen that in the operation process, no special personnel is configured for operating the pressurizing device at the pressurizing station, so that the personnel cost is saved. The jig 900 can ensure the efficiency of mass production of parts.

It should be noted here that, the picking station 720 and the detecting station 740 may also be provided with a picking mechanism such as a manipulator to replace an operator to perform the loading and unloading detection work on the part 800, so that the pressing production line tends to be more intelligent and the production efficiency is improved, which is not described in detail here.

As shown in fig. 9, the present application also provides another part press line, and in particular, the part press line may include a part transfer line 710 and a press apparatus as described above.

A first picking station 721, a pressing station 730, and a second picking station 722 are sequentially disposed at one side of the parts transfer line 710. The pressurizing device is provided at a pressurizing station 730, the first transfer position facing the first picking station 721 and the second transfer position facing the second picking station 722. The first picking station 721 and the second picking station 722 are each provided with an operator.

The first picking station 721 is for an operator to pick the parts 800 on the parts transporting line 710 to the first transfer position and for the operator to pick the parts 800 transported from the pressing position to the first transfer position. The second picking station 722 is used for an operator to pick the parts 800 on the part conveying line 710 to the second transfer position, and for the operator to pick the parts 800 conveyed from the pressing position to the second transfer position, which can further improve the production efficiency, and is described as follows:

in this arrangement, the operator at the first picking station 721 is responsible for picking the parts 800 from the parts transporting line 710, feeding the parts into the pressing device, pressing the parts in the pressing device, and feeding the parts into the second picking station 722 to complete the feeding process. Meanwhile, the operator of the first picking station 721 is also responsible for receiving and detecting the parts 800 transmitted from the second picking station 722 to complete the material taking and detecting process.

Similarly, the operator at the second picking station 722 is responsible for picking the part 800 from the part transporting line 710, feeding the part into the pressing device, pressing the part in the pressing device, and feeding the part into the first picking station 721 to complete the feeding process. Meanwhile, the operator of the first picking station 721 is also responsible for receiving and detecting the parts 800 transmitted from the second picking station 722 to complete the material taking and detecting process.

In this way, the first picking station 721 and the second picking station 722 are both responsible for the part picking and detecting and feeding operations, which is helpful to improve the part production efficiency.

Similarly, the first picking station 721 and the second picking station 722 can also be provided with a picking mechanism such as a manipulator to replace an operator to perform the loading and unloading detection work of the part 800, so that the pressurization production line is more intelligent, and the production efficiency is improved, which is not described in detail herein.

In the embodiments of the present application, the difference between the embodiments is described in detail, and different optimization features between the embodiments can be combined to form a better embodiment as long as the differences are not contradictory, and further description is omitted here in view of brevity of the text.

The above are merely examples of the present application and are not intended to limit the present application. Various modifications and changes may occur to those skilled in the art. Any modification, equivalent replacement, improvement, etc. made within the spirit and principle of the present application should be included in the scope of the claims of the present application.

Claims (10)

1. A compression device characterized by: comprises a reciprocating conveying mechanism (100), a bearing platform (200) and a pressurizing mechanism (300), wherein the reciprocating conveying mechanism (100) is in driving connection with the bearing platform (200), the pressurizing mechanism (300) is arranged on one side of the reciprocating conveying mechanism (100), the reciprocating conveying mechanism (100) can drive the bearing platform (200) to move in a reciprocating manner between a first transferring position and a pressurizing position and between a second transferring position and a pressurizing position,

when the bearing table (200) moves to the pressurizing position along with the reciprocating conveying mechanism (100), the pressurizing mechanism (300) can pressurize the parts (800) on the bearing table (200).

2. The compression device of claim 1, wherein: the pressurizing device further comprises a control unit, a first position controller and a second position controller;

the first position controller is arranged at the first transfer position, and the second position controller is arranged at the second transfer position; the control unit is electrically connected with the first position controller, the second position controller and the reciprocating transmission mechanism (100) respectively;

under the condition that the bearing table (200) moves to the first transferring position along with the reciprocating conveying mechanism (100), the first position controller outputs a first position signal, and the control unit controls the reciprocating conveying mechanism (100) to stop moving according to the first position signal;

under the condition that the bearing table (200) moves to the second transfer position along with the reciprocating conveying mechanism (100), the second position controller outputs a second position signal, and the control unit controls the reciprocating conveying mechanism (100) to stop moving according to the second position signal.

3. The compression device of claim 2, wherein: the pressurizing device further comprises a third position controller;

the third position controller is arranged at the pressurizing position, and the control unit is respectively and electrically connected with the third position controller and the pressurizing mechanism (300);

under the condition that the bearing platform (200) moves to the pressurizing position along with the reciprocating conveying mechanism (100), the third position controller outputs a pressurizing signal, and the control unit controls the reciprocating conveying mechanism (100) to stop moving according to the pressurizing signal and controls the pressurizing mechanism (300) to pressurize the part (800) on the bearing platform (200).

4. The pressurization device according to claim 2, characterized in that: the pressurizing device further comprises a first safety light barrier (410) and a second safety light barrier (420); the first safety light barrier (410) is arranged at the first transfer position, and the second safety light barrier (420) is arranged at the second transfer position;

the control unit is electrically connected with the first safety grating (410) and the second safety grating (420) respectively.

5. The pressurization device according to claim 2, characterized in that: the pressurizing device further comprises a first activation button (510); the first activation button (510) is disposed in the first transfer position; the first start button (510) is electrically connected with the control unit;

when the bearing table (200) reaches the first transferring position along with the reciprocating conveying mechanism (100) and the first starting button (510) is pressed, the first starting button (510) outputs a first starting signal, and the control unit starts the reciprocating conveying mechanism (100) to move to the pressurizing position according to the first starting signal.

6. The pressurization device according to claim 5, characterized in that: the number of the first start buttons (510) is two;

the control unit acquires the first activation signal in case both of the two first activation buttons (510) are pressed.

7. The compression device of claim 1, wherein: the reciprocating transmission mechanism (100) comprises a motor (110) and a lead screw (120), the motor (110) is in driving connection with the lead screw (120), the bearing table (200) is sleeved on the lead screw (120) and is in screw fit with the lead screw (120),

under the condition that the motor (110) is in a driving state, the lead screw (120) drives the bearing table (200) to move along with the motor (110).

8. The compression device of claim 1, wherein: the reciprocating conveying mechanism (100) can drive the bearing platform (200) to move back and forth among the first transferring position, the pressurizing position and the second transferring position in sequence.

9. A pressurized production line is characterized in that: comprising a part transfer line (710) and a pressurizing device according to any one of claims 1 to 8;

a picking station (720), a pressurizing station (730) and a detecting station (740) are sequentially arranged on one side of the part conveying line (710); the pressurizing device is arranged at the pressurizing station (730), the first transferring position faces the picking station (720), and the second transferring position faces the detecting station (740);

the picking station (720) for picking up a part (800) on the part transfer line (710) to the first transfer position,

the inspection station (740) is for picking up parts (800) transferred from the pressing location to the second transfer location.

10. A pressurized production line is characterized in that: comprising a component transport line (710) and a pressurizing device according to any one of claims 1 to 8;

a first picking station (721), a pressurizing station (730) and a second picking station (722) are sequentially arranged on one side of the part conveying line (710); the pressurizing device is arranged at the pressurizing station (730), the first transferring position faces the first picking station (721), and the second transferring position faces the second picking station (722);

the first picking station (721) is used for picking up the parts (800) on the part conveying line (710) to the first transfer position and picking up the parts (800) conveyed to the first transfer position by the pressing position;

the second picking station (722) is for picking parts (800) on the part transfer line (710) to the second transfer location and picking the parts (800) transferred from the pressing location to the second transfer location.

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