CN210884159U - Transverse moving control system applied to ink box - Google Patents

Abstract

The utility model provides a be applied to sideslip control system of ink horn, it includes: the device comprises a base, a bracket, a frame, a control mechanism and a moving mechanism; the lower end of the bracket is connected with the base, and the frame is connected with the bracket; the moving mechanism is arranged on the bracket; a carrier for containing the ink cartridges is arranged at the base, and a plurality of ink cartridges are placed in the carrier; the moving mechanism is used for taking the ink box out and placing the ink box on the frame under the control of the control mechanism. The utility model discloses automatic place the ink horn at the frame, promote ink horn production efficiency, reduce the cost of labor.

Description

Transverse moving control system applied to ink box

Technical Field

The utility model relates to an ink horn processing field indicates a sideslip control system who is applied to ink horn especially.

Background

Modern ink cartridges refer primarily to the components of an ink jet printer that store printing ink and ultimately complete printing. Modern ink box mainly comprises casing, lid and inside sponge, and after the sponge was packed into the casing, the automation line need cover the lid on the casing, accomplishes the equipment of ink box.

After the ink box is assembled, the dispensing process needs to be carried out on the assembled ink box, the ink box is fixed, the ink box needs to be kept still after the dispensing of the ink box is completed, namely the ink box is placed on a frame for keeping the ink box still, according to the traditional method, after the dispensing of the ink box is completed, the ink box product can only be taken out manually and kept still, time and labor are consumed, the production period is greatly prolonged, the efficiency is low, the labor intensity is high, and workers are easy to fatigue.

Therefore, how to provide an automatic ink box, improve ink box production efficiency, reduce the cost of labor is the problem that continues to solve.

Disclosure of Invention

The utility model aims at providing a be applied to sideslip control system of ink horn realizes automaticly placing the ink horn at the frame, promotes ink horn production efficiency, reduces the cost of labor.

The utility model provides a technical scheme as follows:

the utility model provides a be applied to sideslip control system of ink horn, include:

the device comprises a base, a bracket, a frame, a control mechanism and a moving mechanism;

the lower end of the bracket is connected with the base, and the frame is connected with the bracket;

the moving mechanism is arranged on the bracket;

a carrier for containing ink cartridges is arranged at the base, and a plurality of ink cartridges are placed in the carrier;

the moving mechanism is used for taking the ink box away and placing the ink box on the frame under the control of the control mechanism.

Further, the method also comprises the following steps: a power supply mechanism; the power supply mechanism is connected with the control mechanism to supply power;

the power supply mechanism comprises a leakage circuit breaker, a two-pole power supply change-over switch, a normally open contact switch, a first alternating current contactor, a rectifier, a fuse, a frequency converter, a first motor and a socket;

the second port of the electric leakage circuit breaker is connected with a live wire, the fourth port of the electric leakage circuit breaker is connected with a zero line, the first port of the electric leakage circuit breaker is respectively connected with the fourth port of the normally open contact switch and the first port of the two-pole power supply change-over switch, and the third port of the electric leakage circuit breaker is respectively connected with the second port of the normally open contact switch and the third port of the two-pole power supply change-over switch;

the second port of the two-pole power supply change-over switch is connected with one end of the first alternating current contactor, and the fourth port of the two-pole power supply change-over switch is connected with the other end of the first alternating current contactor;

the third port of the normally open contact switch is respectively connected with the first input port of the rectifier, the first port of the socket and one end of the first fuse, the first port of the normally open contact switch is respectively connected with the first input port of the rectifier, the second port of the socket and one end of the second fuse, and the third port of the socket is grounded;

the other end of the first fuse is connected with a first port of the frequency converter, and the other end of the second fuse is connected with a second port of the frequency converter;

a third port and a fourth port of the frequency converter are connected through a first switch, and a first communication port and a second communication port of the frequency converter are respectively accessed into a first communication signal and a second communication signal output by the control mechanism;

a U-phase port of the frequency converter is connected with a U-phase port of the first motor, a V-phase port of the frequency converter is connected with a V-phase port of the first motor, a W-phase port of the frequency converter is connected with a W-phase port of the first motor, and a second ground port of the frequency converter is connected with a ground wire interface of the first motor;

a fifth port of the frequency converter is connected with a first voltage, and a sixth port of the frequency converter is connected with a control signal output by the control mechanism;

the first output end of the rectifier outputs a first voltage, and the second output end of the rectifier outputs a second voltage.

Further, the control mechanism includes: the system comprises a touch screen, a PLC controller and a first controller;

a first voltage input interface of the touch screen is connected with a first voltage provided by the power supply mechanism, and a second voltage input interface of the touch screen is connected with a second voltage provided by the power supply mechanism;

the first equipment connecting point of the touch screen is connected with the first communication interface of the PLC, and the second equipment connecting point of the touch screen is connected with the second communication interface of the PLC;

a first voltage input interface of the PLC controller is connected to a first voltage provided by the power supply mechanism, and a second voltage input interface of the PLC controller is connected to a second voltage provided by the power supply mechanism;

a current driving input interface and a first control interface of the PLC are respectively connected to a second voltage provided by the power supply mechanism, and a second control interface of the PLC is connected to a first voltage provided by the power supply mechanism;

a first signal output interface of the PLC controller outputs the first communication signal, and a second signal output interface of the PLC controller outputs the second communication signal;

the first controller is connected with the PLC;

the current driving input interface of the first controller is connected with a second voltage provided by the power supply mechanism;

and the extended control interface of the first controller is connected with a first voltage provided by the power supply mechanism.

Further, the moving mechanism comprises a manipulator, and the manipulator is connected with the PLC; the control mechanism further includes: a push button switch and a proximity switch;

a first interface, a second interface, a third interface, a fourth interface, a fifth interface and a sixth interface of the PLC are respectively connected with a first button switch, a second button switch, a third button switch, a fourth button switch, a fifth button switch and a sixth button switch and then connected with a first voltage provided by the power supply mechanism;

a seventh interface of the PLC is connected with a first port of a first proximity switch, a second port of the first proximity switch is connected with a second voltage provided by the power supply mechanism, and a third port of the first proximity switch is connected with a first voltage provided by the power supply mechanism;

and an eighth interface of the PLC outputs the control signal to the frequency converter.

Further, the method also comprises the following steps: an LED indicator light;

a ninth interface of the PLC controller is unloaded;

and a tenth interface, an eleventh interface and a thirteenth interface of the PLC are respectively connected with the first port, the second port and the third port of the LED indicator lamp in a one-to-one correspondence manner, and the fourth port of the LED indicator lamp is connected with a second voltage provided by the power supply mechanism.

Further, the control mechanism further includes: an emergency stop button;

a first interface of the first controller is connected with the emergency stop button and then is connected with a first voltage provided by a power supply mechanism;

the second interface and the third interface of the first controller are connected with the seventh button switch and the ninth button switch respectively and then are connected with the first voltage provided by the power supply mechanism;

the fourth interface of the first controller is connected with the first port of a second proximity switch, the second port of the second proximity switch (B2) is connected with the second voltage provided by the power supply mechanism, and the third port of the second proximity switch is connected with the first voltage provided by the power supply mechanism;

and the fourth interface, the fifth interface, the sixth interface, the seventh interface and the eighth interface of the first controller are idle.

Further, the method also comprises the following steps: a one-way valve;

a ninth interface, a tenth interface, an eleventh interface, a twelfth interface, a thirteenth interface and a fourteenth interface of the first controller are respectively connected with the first one-way valve, the second one-way valve, the third one-way valve, the fourth one-way valve, the fifth one-way valve and the sixth one-way valve and then are connected with a second voltage provided by the power supply mechanism;

and a fifteenth interface of the first controller is connected with the second alternating current contactor and then is connected with a second voltage provided by the power supply mechanism, and a sixteenth interface of the first controller is unloaded.

Through the utility model provides a pair of be applied to sideslip control system of ink horn can automize and place the ink horn at the frame, promotes ink horn production efficiency, reduces the cost of labor.

Drawings

The foregoing features, aspects and advantages of a traverse control system for an ink cartridge, and an implementation thereof will be further described in the following detailed description of preferred embodiments in conjunction with the accompanying drawings in a clearly understood manner.

FIG. 1 is a schematic view of an embodiment of a traverse control system for an ink cartridge according to the present invention;

FIG. 2 is a schematic view of another embodiment of a traverse control system for an ink cartridge according to the present invention;

FIG. 3 is a schematic view of another embodiment of a traverse control system for an ink cartridge according to the present invention;

FIG. 4 is a schematic view of another embodiment of a traverse control system for an ink cartridge according to the present invention;

FIG. 5 is a schematic view of another embodiment of a traverse control system for an ink cartridge according to the present invention;

FIG. 6 is a schematic view of another embodiment of a traverse control system for an ink cartridge according to the present invention;

fig. 7 is a schematic structural view of another embodiment of a traverse control system applied to an ink cartridge according to the present invention.

Detailed Description

In order to more clearly illustrate embodiments of the present invention or technical solutions in the prior art, specific embodiments of the present invention will be described below with reference to the accompanying drawings. It is obvious that the drawings in the following description are only examples of the invention, and that for a person skilled in the art, other drawings and embodiments can be obtained from these drawings without inventive effort.

For the sake of simplicity, only the parts relevant to the present invention are schematically shown in the drawings, and they do not represent the actual structure as a product. In addition, in order to make the drawings concise and understandable, components having the same structure or function in some of the drawings are only schematically illustrated or only labeled. In this document, "one" means not only "only one" but also a case of "more than one".

One embodiment of the present invention, as shown in fig. 1 to 7, is a traverse control system applied to an ink cartridge, comprising: a base, a bracket 30, a frame 40, a control mechanism 10 and a moving mechanism 20;

the lower end of the bracket 30 is connected with the base, and the frame 40 is connected with the bracket 30;

the moving mechanism 20 is arranged on the bracket 30;

a carrier for containing ink cartridges is arranged at the base, and a plurality of ink cartridges are placed in the carrier;

the moving mechanism 20 is used to take out and place the ink cartridge on the frame 40 under the control of the control mechanism 10.

Based on the foregoing embodiment, further comprising: a power supply mechanism; the power supply mechanism is connected with the control mechanism 10 to supply power;

the power supply mechanism comprises a leakage circuit breaker (Q1), a two-pole power supply change-over switch (SK1), a normally open contact switch (KM1), a first alternating current contactor (KM01), a rectifier (V1), a fuse, a frequency converter (U1), a first motor (M1) and a socket (U4);

the second port of the residual current circuit breaker (Q1) is connected with a live wire, the fourth port of the residual current circuit breaker (Q1) is connected with a zero wire, the first port of the residual current circuit breaker (Q1) is respectively connected with the fourth port of the normally-open contact switch (KM1) and the first port of the two-pole power supply change-over switch (SK1), and the third port of the residual current circuit breaker (Q1) is respectively connected with the second port of the normally-open contact switch (KM1) and the third port of the two-pole power supply change-over switch (SK 1);

a second port of the two-pole power supply changeover switch (SK1) is connected with one end of the first alternating current contactor (KM01), and a fourth port of the two-pole power supply changeover switch (SK1) is connected with the other end of the first alternating current contactor (KM 01);

the third port of the normally open contact switch (KM1) is respectively connected with the first input port of the rectifier (V1), the first port of the socket (U4) and one end of a first fuse (F3), the first port of the normally open contact switch (KM1) is respectively connected with the first input port of the rectifier (V1), the second port of the socket (U4) and one end of a second fuse (F4), and the third port of the socket (U4) is grounded;

the other end of the first fuse (F3) is connected with a first port (R (L1)) of the frequency converter (U1), and the other end of the second fuse (F4) is connected with a second port (S (L2)) of the frequency converter (U1);

a first ground port of the frequency converter (U1) is connected with a ground wire, a third port (DCM) and a fourth port (MT1) of the frequency converter (U1) are connected through a first switch, and a first communication port and a second communication port of the frequency converter (U1) are respectively connected with a first communication signal (485-), a second communication signal (485+), which are output by the control mechanism 10;

a U-phase port of the frequency converter (U1) is connected with a U-phase interface of the first motor (M1), a V-phase port of the frequency converter (U1) is connected with a V-phase interface of the first motor (M1), a W-phase port of the frequency converter (U1) is connected with a W-phase interface of the first motor (M1), and a second ground port of the frequency converter (U1) is connected with a ground interface of the first motor (M1);

a fifth port (RC) of the frequency converter (U1) is connected to the first voltage (0V), and a sixth port (RA) of the frequency converter (U1) is connected to a control signal (RA) output by the control mechanism 10;

the first output terminal of the rectifier (V1) outputs a first voltage (0V), and the second output terminal of the rectifier (V1) outputs a second voltage (+ 24V).

Based on the foregoing embodiment, the control mechanism 10 includes: a touch screen (HMI1), a PLC controller (A2), a first controller (A3);

a first voltage (0V) input interface of the touch screen (HMI1) is connected with a first voltage (0V) provided by the power supply mechanism, and a second voltage (+24V) input interface of the touch screen (HMI1) is connected with a second voltage (+24V) provided by the power supply mechanism;

a first device connection point of the touch screen (HMI1) is connected with a first communication interface (2-485-) of the PLC controller (A2), and a second device connection point of the touch screen (HMI1) is connected with a second communication interface of the PLC controller (A2);

a first voltage (0V) input interface of the PLC controller (A2) is connected with a first voltage (0V) provided by the power supply mechanism, and a second voltage (+24V) input interface of the PLC controller (A2) is connected with a second voltage (+24V) provided by the power supply mechanism;

a current driving input interface (S/S) and a first control interface of the PLC (A2) are respectively connected to a second voltage (+24V) provided by the power supply mechanism, and a second control interface of the PLC (A2) is connected to a first voltage (0V) provided by the power supply mechanism;

a first signal output interface (1-485-) of the PLC controller (A2) outputs the first communication signal, and a second signal output interface (1-485+) of the PLC controller (A2) outputs the second communication signal;

the first controller (A3) is connected with the PLC controller (A2);

the current driving input interface (S/S) of the first controller (A3) is connected with a second voltage (+24V) provided by the power supply mechanism;

an extended control interface (C0) of the first controller (A3) accesses a first voltage (0V) provided by the power supply mechanism.

Based on the foregoing embodiment, the moving mechanism 20 includes a manipulator connected to the PLC controller (a 2); the control mechanism 10 further includes: a push button switch and a proximity switch;

a first interface (X0), a second interface (X1), a third interface (X2), a fourth interface (X3), a fifth interface (X4) and a sixth interface (X5) of the PLC (A2) are connected with a first button switch (S2), a second button switch (S3), a third button switch (S4), a fourth button switch (S5), a fifth button switch (S6) and a sixth button switch (S7) respectively and then connected with a first voltage (0V) provided by the power supply mechanism;

a seventh interface (X6) of the PLC (A2) is connected with a first port of a first proximity switch (B1), a second port of the first proximity switch (B1) is connected with a second voltage (+24V) provided by the power supply mechanism, and a third port of the first proximity switch (B1) is connected with a first voltage (0V) provided by the power supply mechanism;

an eighth interface (X7) of the PLC controller (A2) outputs the control signal (RA) to the frequency converter (U1).

Based on the foregoing embodiment, further comprising: an LED indicator light (LED 1);

-a ninth interface (Y0) of the PLC controller (a2) is unloaded;

a tenth interface (Y1), an eleventh interface (Y2) and a thirteenth interface (Y3) of the PLC controller (a2) are respectively connected with the first port, the second port and the third port of the LED indicator light (LED1) in a one-to-one correspondence, and the fourth port of the LED indicator light (LED1) is connected to a second voltage (+24V) provided by a power supply mechanism.

Based on the foregoing embodiment, the control mechanism 10 further includes: an emergency stop button;

a first interface (X20) of the first controller (A3) is connected with the emergency stop button (S1) and then is connected with a first voltage (0V) provided by a power supply mechanism;

the second interface (X21) and the third interface (X22) of the first controller (A3) are connected with a seventh button switch (S8) and a ninth button switch (S9) respectively and then are connected with a first voltage (0V) provided by a power supply mechanism;

a fourth interface (X23) of the first controller (A3) is connected with a first port of a second proximity switch (B2), a second port of the second proximity switch (B2) is connected with a second voltage (+24V) provided by the power supply mechanism, and a third port of the second proximity switch (B2) is connected with a first voltage (0V) provided by the power supply mechanism;

the fourth interface (X20), the fifth interface (X23), the sixth interface (X23), the seventh interface (X23) and the eighth interface (X27) of the first controller (A3) are unloaded.

Based on the foregoing embodiment, further comprising: a one-way valve;

a ninth interface (Y20), a tenth interface (Y21), an eleventh interface (Y22), a twelfth interface (Y23), a thirteenth interface (Y24) and a fourteenth interface (Y25) of the first controller (A3) are respectively connected with a first one-way valve (Y1), a second one-way valve (Y2), a third one-way valve (Y3), a fourth one-way valve (Y4), a fifth one-way valve (Y5) and a sixth one-way valve (Y6) and then connected with a second voltage (+24V) provided by a power supply mechanism;

and a fifteenth interface (Y26) of the first controller (A3) is connected with the second AC contactor (K2) and then is connected with a second voltage (+24V) provided by a power supply mechanism, and a sixteenth interface (Y27) of the first controller (A3) is unloaded.

Specifically, the ink cartridge can be taken out through the moving mechanism 20 without manual operation, and the ink cartridge is taken out and placed on the frame 40, so that the ink cartridge stands still at the frame 40 to wait for the next process of the ink cartridge processing production line. The ink box is automatically placed on the frame 40, the production efficiency of the ink box is improved, and the labor cost and the ink box generation cost are reduced.

It should be noted that the above embodiments can be freely combined as necessary. The foregoing is only a preferred embodiment of the present invention, and it should be noted that, for those skilled in the art, a plurality of modifications and decorations can be made without departing from the principle of the present invention, and these modifications and decorations should also be regarded as the protection scope of the present invention.

Claims (7)

1. A traverse control system for an ink cartridge, comprising:

the device comprises a base, a bracket, a frame, a control mechanism and a moving mechanism;

the lower end of the bracket is connected with the base, and the frame is connected with the bracket;

the moving mechanism is arranged on the bracket;

a carrier for containing ink cartridges is arranged at the base, and a plurality of ink cartridges are placed in the carrier;

the moving mechanism is used for taking the ink box away and placing the ink box on the frame under the control of the control mechanism.

2. A traverse control system applied to an ink cartridge as recited in claim 1, further comprising: a power supply mechanism; the power supply mechanism is connected with the control mechanism to supply power;

the power supply mechanism comprises a leakage circuit breaker, a two-pole power supply change-over switch, a normally open contact switch, a first alternating current contactor, a rectifier, a fuse, a frequency converter, a first motor and a socket;

the second port of the electric leakage circuit breaker is connected with a live wire, the fourth port of the electric leakage circuit breaker is connected with a zero line, the first port of the electric leakage circuit breaker is respectively connected with the fourth port of the normally open contact switch and the first port of the two-pole power supply change-over switch, and the third port of the electric leakage circuit breaker is respectively connected with the second port of the normally open contact switch and the third port of the two-pole power supply change-over switch;

the second port of the two-pole power supply change-over switch is connected with one end of the first alternating current contactor, and the fourth port of the two-pole power supply change-over switch is connected with the other end of the first alternating current contactor;

the third port of the normally open contact switch is respectively connected with the first input port of the rectifier, the first port of the socket and one end of the first fuse, the first port of the normally open contact switch is respectively connected with the first input port of the rectifier, the second port of the socket and one end of the second fuse, and the third port of the socket is grounded;

the other end of the first fuse is connected with a first port of the frequency converter, and the other end of the second fuse is connected with a second port of the frequency converter;

a third port and a fourth port of the frequency converter are connected through a first switch, and a first communication port and a second communication port of the frequency converter are respectively accessed into a first communication signal and a second communication signal output by the control mechanism;

a U-phase port of the frequency converter is connected with a U-phase port of the first motor, a V-phase port of the frequency converter is connected with a V-phase port of the first motor, a W-phase port of the frequency converter is connected with a W-phase port of the first motor, and a second ground port of the frequency converter is connected with a ground wire interface of the first motor;

a fifth port of the frequency converter is connected with a first voltage, and a sixth port of the frequency converter is connected with a control signal output by the control mechanism;

the first output end of the rectifier outputs a first voltage, and the second output end of the rectifier outputs a second voltage.

3. A traverse control system as applied to an ink cartridge as recited in claim 2, wherein the control mechanism comprises: the system comprises a touch screen, a PLC controller and a first controller;

a first voltage input interface of the touch screen is connected with a first voltage provided by the power supply mechanism, and a second voltage input interface of the touch screen is connected with a second voltage provided by the power supply mechanism;

the first equipment connecting point of the touch screen is connected with the first communication interface of the PLC, and the second equipment connecting point of the touch screen is connected with the second communication interface of the PLC;

a first voltage input interface of the PLC controller is connected to a first voltage provided by the power supply mechanism, and a second voltage input interface of the PLC controller is connected to a second voltage provided by the power supply mechanism;

a current driving input interface and a first control interface of the PLC are respectively connected to a second voltage provided by the power supply mechanism, and a second control interface of the PLC is connected to a first voltage provided by the power supply mechanism;

a first signal output interface of the PLC controller outputs the first communication signal, and a second signal output interface of the PLC controller outputs the second communication signal;

the first controller is connected with the PLC;

the current driving input interface of the first controller is connected with a second voltage provided by the power supply mechanism;

and the extended control interface of the first controller is connected with a first voltage provided by the power supply mechanism.

4. A traverse control system as applied to an ink cartridge as recited in claim 3, wherein the movement mechanism comprises a robot arm, the robot arm being connected to the PLC controller; the control mechanism further includes: a push button switch and a proximity switch;

a first interface, a second interface, a third interface, a fourth interface, a fifth interface and a sixth interface of the PLC are respectively connected with a first button switch, a second button switch, a third button switch, a fourth button switch, a fifth button switch and a sixth button switch and then connected with a first voltage provided by the power supply mechanism;

a seventh interface of the PLC is connected with a first port of a first proximity switch, a second port of the first proximity switch is connected with a second voltage provided by the power supply mechanism, and a third port of the first proximity switch is connected with a first voltage provided by the power supply mechanism;

and an eighth interface of the PLC outputs the control signal to the frequency converter.

5. A traverse control system as applied to an ink cartridge as recited in claim 4, further comprising: an LED indicator light;

a ninth interface of the PLC controller is unloaded;

and a tenth interface, an eleventh interface and a thirteenth interface of the PLC are respectively connected with the first port, the second port and the third port of the LED indicator lamp in a one-to-one correspondence manner, and the fourth port of the LED indicator lamp is connected with a second voltage provided by the power supply mechanism.

6. A traverse control system as applied to an ink cartridge as recited in claim 5, wherein the control mechanism further comprises: an emergency stop button;

a first interface of the first controller is connected with the emergency stop button and then is connected with a first voltage provided by a power supply mechanism;

the second interface and the third interface of the first controller are connected with the seventh button switch and the ninth button switch respectively and then are connected with the first voltage provided by the power supply mechanism;

the fourth interface of the first controller is connected with the first port of a second proximity switch, the second port of the second proximity switch (B2) is connected with the second voltage provided by the power supply mechanism, and the third port of the second proximity switch is connected with the first voltage provided by the power supply mechanism;

and the fourth interface, the fifth interface, the sixth interface, the seventh interface and the eighth interface of the first controller are idle.

7. A traverse control system applied to an ink cartridge as recited in claim 6, further comprising: a one-way valve;

a ninth interface, a tenth interface, an eleventh interface, a twelfth interface, a thirteenth interface and a fourteenth interface of the first controller are respectively connected with the first one-way valve, the second one-way valve, the third one-way valve, the fourth one-way valve, the fifth one-way valve and the sixth one-way valve and then are connected with a second voltage provided by the power supply mechanism;

and a fifteenth interface of the first controller is connected with the second alternating current contactor and then is connected with a second voltage provided by the power supply mechanism, and a sixteenth interface of the first controller is unloaded.

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