A currency detection head assembly operation board and a currency detection machine production device

Abstract

This utility model discloses a banknote verification magnetic head assembly operation plate and a banknote verification machine production device. The banknote verification magnetic head assembly operation plate includes: a plate body with several parallel slide rails; a push plate slidably mounted on the slide rails, with a pushing component on one side of the push plate; and a base fixedly mounted on the plate body along the direction perpendicular to the slide rails. The base has a mounting groove on the side facing the pushing component, the shape of which is adapted to the shielding shell of the banknote verification magnetic head, and the pushing component corresponds to the position of the mounting groove. This utility model, by setting a directional sliding push plate and a base corresponding to the position of the pushing component on the push plate, allows the pre-assembled shielding shell and iron core to be placed in the mounting groove of the base during banknote verification magnetic head assembly. By moving the push plate, the pushing component presses the iron core into a predetermined position within the shielding shell. During this process, multiple iron cores are subjected to balanced forces, and the pushing distance is equal, effectively improving the assembly efficiency and accuracy of the banknote verification magnetic head.

Description

Technical Field

[0001] This utility model relates to the field of banknote verification magnetic head assembly technology, and in particular to a banknote verification magnetic head assembly operation panel and banknote verification machine production equipment. Background Technology

[0002] The magnetic head for banknote verification is a crucial component in banknote verification machines and other equipment used to detect the magnetic characteristics of banknotes. Its working principle involves detecting magnetic ink and converting and analyzing electrical signals. For example, during the printing process, banknotes use magnetic ink to create specific patterns. The magnetic characteristics of these patterns, such as magnetic field strength and magnetic distribution, follow certain patterns. The magnetic head can sense the magnetic signals on the banknote. When a banknote passes near the magnetic head, it can determine the authenticity of the banknote based on pre-set magnetic characteristic parameters. The structure of existing magnetic heads for banknote verification can be referenced in CN113393609B, which discloses a structure for a banknote verification magnetic head. This structure mainly consists of a shielding shell and several iron cores disposed within the shielding shell. The iron cores are fitted into predetermined positions within the shielding shell and then packaged together. The installation precision of the iron cores is a significant factor affecting the accuracy of the detection.

[0003] In existing technologies, the installation of the iron core into the shielding shell is mainly done manually. The installation accuracy is verified and further fixed by the screw hole structure on the side of the iron core corresponding to the shielding shell. Due to the large number of iron cores and the small installation space inside the shielding shell, the installation process is very laborious, has low accuracy, requires repeated adjustments, and has low production efficiency.

[0004] Therefore, existing technologies still need to be improved and developed. Utility Model Content

[0005] To address the problems in existing technologies where installing multiple iron cores into a shielding shell is laborious, inaccurate, and requires repeated adjustments leading to low production efficiency, this invention provides a banknote verification magnetic head assembly operation panel and banknote verification machine production equipment.

[0006] This utility model is achieved through the following technical solution:

[0007] A banknote verification magnetic head assembly operation panel, wherein the banknote verification magnetic head assembly operation panel includes:

[0008] The plate body is provided with several parallel slide rails;

[0009] A push plate, which is slidably mounted on a plurality of slide rails, and a pusher is provided on one side of the push plate;

[0010] A base is fixedly mounted on the plate along a direction perpendicular to the slide rail. A mounting groove is provided on the side of the base facing the pusher. The mounting groove is adapted to the shape of the shielding shell of the banknote verification magnetic head. The pusher is positioned corresponding to the mounting groove.

[0011] The banknote verification magnetic head assembly operation panel includes a pusher fixedly mounted on the pusher plate. Two contact plates are provided on the side of the pusher facing the base. The two contact plates are arranged in parallel at a predetermined distance, and the predetermined distance is adapted to the width of the mounting groove.

[0012] The banknote verification magnetic head assembly operation plate has a plurality of receiving slots evenly arranged on the contact plate. The receiving slots correspond to the positions of the iron core in the banknote verification magnetic head and are used to accommodate the leads on the iron core.

[0013] The banknote verification magnetic head assembly operation plate includes ear plates on both sides of the pusher, and a limit rod detachably mounted on the ear plate. The central axis of the limit rod is parallel to the slide rail.

[0014] A limiting plate is provided on the base corresponding to the position of the limiting rod. The limiting rod and the limiting plate are used to limit the movement range of the push plate.

[0015] The banknote verification magnetic head assembly operation plate includes a plurality of clearance grooves spaced apart on the base, which pass through the mounting groove and correspond to the screw holes on the shielding shell used for assembling the iron core.

[0016] The banknote verification magnetic head assembly operation panel, wherein the width of the upper side plate corresponding to the mounting groove on the base is smaller than the width of the lower side plate of the mounting groove, and a plurality of clearance grooves are provided on the upper side plate of the mounting groove.

[0017] The banknote verification magnetic head assembly operation plate has a sliding rod on the side of the push plate opposite to the pusher. One end of the sliding rod is fixedly connected to the push plate, and the other end is directionally slidably connected to the plate body.

[0018] The banknote verification magnetic head assembly operation panel includes a driver on the panel body, and the slide rod is an electric telescopic rod connected to the driver.

[0019] The banknote verification magnetic head assembly operation panel, wherein the slide rail includes a first track and a second track arranged in parallel, the first track and the second track being arranged in parallel at a certain distance;

[0020] The push plate is provided with a first slider and a second slider on one side. The first slider and the second slider each include a through groove. The groove is fitted and slidably connected to the first track and the second track.

[0021] A banknote detector manufacturing apparatus, wherein the banknote detector manufacturing apparatus includes the aforementioned banknote detector magnetic head assembly operation panel.

[0022] The beneficial effects of this utility model are as follows: By setting a directional sliding push plate and a base corresponding to the position of the pusher on the push plate, the pre-assembled shielding shell and iron core can be placed in the mounting groove of the base when assembling the banknote verification magnetic head. By moving the push plate, the pusher can squeeze the iron core into the predetermined position inside the shielding shell. During the process, the multiple iron cores are subjected to balanced forces and the pushing distance is equal, which can effectively improve the assembly efficiency and accuracy of the banknote verification magnetic head. Attached Figure Description

[0023] Figure 1 This is a three-dimensional structural diagram of the banknote verification magnetic head assembly operation panel of this utility model;

[0024] Figure 2 This is a schematic diagram of the installation and operation of the banknote verification magnetic head assembly operation panel of this utility model;

[0025] Figure 3 This is a top view of the banknote verification magnetic head assembly operation panel of this utility model;

[0026] Figure 4 This is a schematic diagram of the first usage state of the banknote verification magnetic head assembly operation panel of this utility model;

[0027] Figure 5 This is a schematic diagram of the second usage state of the banknote verification magnetic head assembly operation panel of this utility model.

[0028] exist Figures 1 to 5 In the middle: 100, plate; 110, slide rail; 111, first track; 112, second track; 120, slide rod; 130, driver; 200, push plate; 210, pusher; 211, contact plate; 212, receiving groove; 220, ear plate; 221, limit rod; 231, first slider; 232, second slider; 300, base; 310, mounting groove; 320, clearance groove; 330, limit plate; 400, shielding shell; 410, iron core. Detailed Implementation

[0029] To make the objectives, technical solutions, and effects of this utility model clearer and more explicit, the present utility model will be further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are only used to explain this utility model and are not intended to limit this utility model.

[0030] It should be noted that if the embodiments of this utility model involve directional indicators (such as up, down, left, right, front, back, etc.), the directional indicators are only used to explain the relative positional relationship and movement of each component in a certain specific posture (as shown in the figure). If the specific posture changes, the directional indicators will also change accordingly.

[0031] Furthermore, if the embodiments of this utility model involve descriptions such as "first" or "second," these descriptions are for descriptive purposes only and should not be construed as indicating or implying their relative importance or implicitly specifying the number of technical features indicated. Therefore, features defined with "first" or "second" may explicitly or implicitly include at least one of those features. Additionally, the technical solutions of the various embodiments can be combined with each other, but this must be based on the ability of those skilled in the art to implement them. If the combination of technical solutions is contradictory or impossible to implement, it should be considered that such a combination of technical solutions does not exist and is not within the scope of protection claimed by this utility model.

[0032] In existing technologies, the installation of the iron core into the shielding shell is mainly done manually. The installation accuracy is verified and further fixed by the screw hole structure on the side of the iron core corresponding to the shielding shell. Due to the large number of iron cores and the small installation space inside the shielding shell, the installation process is very laborious, has low accuracy, requires repeated adjustments, and has low production efficiency.

[0033] In view of the above-mentioned problems in the prior art, this utility model provides a banknote verification magnetic head assembly operation panel, such as... Figure 1 and Figure 2 As shown, the banknote verification magnetic head assembly operation plate includes: a plate body 100, on which a plurality of parallel slide rails 110 are provided; a push plate 200, which is slidably disposed on the plurality of slide rails 110, and a pusher 210 is provided on one side of the push plate 200; and a base 300, which is fixedly disposed on the plate body 100 along the direction perpendicular to the slide rails 110, and a mounting groove 310 is provided on the side of the base 300 facing the pusher 210. The mounting groove 310 is adapted to the shape of the shielding shell 400 of the banknote verification magnetic head, and the pusher 210 corresponds to the position of the mounting groove 310.

[0034] This invention, by setting a directional sliding push plate 200 and a base 300 corresponding to the position of the pusher 210 on the push plate 200, allows the pre-assembled shielding shell 400 and iron core 410 to be placed in the mounting groove 310 of the base 300 when assembling the banknote verification magnetic head. By moving the push plate 200, the pusher 210 is made to press the iron core 410 into a predetermined position inside the shielding shell 400. During the process, the multiple iron cores 410 are subjected to balanced forces and the pushing distance is equal, which can effectively improve the assembly efficiency and accuracy of the banknote verification magnetic head.

[0035] In the above embodiments, such as Figure 1 As shown, the main body of the banknote verification magnetic head assembly operation plate of this utility model consists of a plate body 100, a push plate 200, and a base 300. The plate body 100 is a planar plate structure that can be stably placed on a workbench, table, or other flat surface. Several slide rails 110 are arranged parallel to each other on the plate body 100. Correspondingly, the push plate 200 is slidably mounted on the slide rails 110 and can slide freely along the length of the slide rails 110. A pusher 210 is provided on one side of the push plate 200. This pusher 210 is used to abut against the iron core 410 of the banknote verification magnetic head, so that by moving the push plate 200, the several iron cores 410 can be... The core 410 is pushed synchronously to a predetermined position within the shielding shell 400, thereby improving installation efficiency. To ensure the shielding shell 400 in the banknote detector is fixed in position and to prevent misalignment due to movement of the shielding shell 400 when the pusher plate 200 pushes the core 410, a base 300 is also provided on the plate 100 in this embodiment. The base 300 is fixedly mounted on the plate 100 along the direction of the vertical slide rail 110. An installation groove 310 is provided on the side of the base 300 facing the pusher 210. The installation groove 310 is adapted to the shape of the shielding shell 400 of the banknote detector, and the pusher 210 corresponds to the installation groove 310.

[0036] In actual use, the installer can place the pre-installed (simply place the iron core 410 in the predetermined position inside the shielding shell 400) banknote verification head into the mounting slot 310, so that the banknote verification head engages with the mounting slot 310, and then move the push plate 200 towards the base 300. During this process, the pusher 210 abuts against the iron core 410 inside the shielding shell 400. Since the shielding shell 400 is limited by the mounting slot 310, several iron cores 410 are pushed synchronously to the predetermined position inside the shielding shell 400. During this operation, several iron cores 410 are subjected to equal and balanced forces, and the pushing distance is equal. Compared with the traditional manual operation method, the process of repeatedly adjusting the position of a single iron core 410 is avoided, thus effectively improving production efficiency.

[0037] In one possible embodiment of this utility model, such as Figure 3As shown, since the types of iron cores 410 in different models of banknote verification magnetic heads vary, and the ends of iron cores 410 may have functional structures such as leads, in order to avoid damage to the functional structures on iron cores 410 during the process of pushing iron cores 410, in this embodiment, the pushing member 210 is fixedly mounted on the pushing plate 200. Two contact plates 211 are provided on the side of the pushing member 210 facing the base 300. The contact plates 211 are the actual components used to contact iron cores 410. The two contact plates 211 are arranged parallel to each other at a predetermined distance, and the predetermined distance is adapted to the width of the mounting groove 310. Through the above structural arrangement, a cavity is formed between the two contact plates 211 to avoid the functional structures on iron cores 410. The two contact plates 211 make contact with the two opposite edge parts of iron cores 410, avoiding damage to the functional structures on iron cores 410 and improving the reliability and safety of banknote verification magnetic head assembly. In addition, the design of the contact plate 211 ensures the stability and accuracy of the iron core 410 during the pushing process, further improving assembly efficiency.

[0038] Furthermore, for some iron cores 410 with leads, in order to avoid damaging the leads, such as... Figure 3 As shown, in this embodiment, a plurality of receiving grooves 212 are evenly arranged on the contact plate 211. The location of the receiving grooves 212 corresponds to the lead wire structure of the iron core 410 in a specific model. When the contact plate 211 and the iron core 410 come into contact, the lead wire structure on the iron core 410 corresponds to the receiving groove 212, thereby avoiding and accommodating the lead wire structure, preventing damage to the lead wire structure during the pushing process, ensuring the integrity of the iron core 410 and its functional structure, and improving the assembly quality of the banknote verification magnetic head. In addition, the setting of the receiving grooves 212 also enhances the compatibility between the contact plate 211 and the iron core 410, making the pushing process smoother and further improving the assembly efficiency.

[0039] In another possible embodiment of this utility model, such as Figure 2 and Figure 3 As shown, in order to limit the movement range of the pusher 210 and prevent damage to the iron core 410 due to excessive force when the pusher 210 presses against the iron core 410, ear plates 220 are respectively provided on both sides of the pusher in this embodiment. Limiting rods 221 are detachably provided on the ear plates 220. The central axis of the limiting rods 221 is set along the direction parallel to the slide rail 110. Correspondingly, a limiting plate 330 is also provided on the base 300 at the position corresponding to the limiting rods 221. Figure 4 and Figure 5As shown, when the push plate 200 moves and the pusher 210 presses against the iron core 410, the limiting rod 221 moves synchronously towards the limiting plate 330, and at a predetermined position, the end of the limiting rod 221 abuts against the limiting plate 330. This restricts the movement range of the push plate 200 at that predetermined position, preventing excessive pressure on the iron core 410 by the pusher 210 and thus improving the safety and reliability of the banknote detector head assembly. Simultaneously, the setting of the limiting rod 221 and the limiting plate 330 facilitates the operator's observation and judgment of the movement distance of the push plate 200, further improving the accuracy and efficiency of the assembly. Furthermore, the detachable design of the limiting rod 221 allows for adjustment of its position according to different banknote detector head models, enhancing the versatility and flexibility of the banknote detector head assembly operation panel.

[0040] In another possible embodiment of this utility model, such as Figure 1 and Figure 2 As shown, a plurality of clearance grooves 320 are spaced apart on the base 300, and the clearance grooves 320 pass through the mounting groove 310. The positions of the clearance grooves 320 correspond to the screw holes on the shielding shell 400 used for assembling the iron core 410. After the push plate 200 moves to limit the assembly of the shielding shell 400 and the iron core 410, the assembly personnel can directly operate on the banknote verification magnetic head assembly operation panel to install screws at the screw hole positions used for assembling the iron core 410, thereby further completing the assembly steps of the shielding shell 400 and the iron core 410, simplifying the assembly process and improving assembly efficiency. In addition, the clearance grooves 320 also facilitate the observation and judgment of the screw installation progress during the assembly process, further improving the accuracy and reliability of the assembly.

[0041] Furthermore, such as Figure 1 and Figure 2 As shown, to facilitate the installation of the banknote verification magnetic head into or out of the mounting slot 310 by the assembly personnel, in this embodiment, the width of the upper side plate of the base 300 corresponding to the mounting slot 310 is preferably set to be smaller than the width of the lower side plate of the mounting slot 310. This creates a guide structure on the upper side plate of the mounting slot 310, which facilitates the assembly personnel in quickly and accurately placing and removing the banknote verification magnetic head, improving assembly efficiency. Simultaneously, in this embodiment, several clearance slots 320 are provided on the upper side plate of the mounting slot 310 to facilitate subsequent screw installation.

[0042] In actual use, the assembler can first place the pre-assembled shielding shell 400 and iron core 410 into the mounting groove 310, so that the shielding shell 400 and the mounting groove 310 are engaged. At this time, the iron core 410 is located in the mounting groove 310 and partially exposed at the opening of the mounting groove 310. Then, the assembler can push the push plate 200, so that the push plate 200 moves along the length direction of the slide rail 110 toward the base 300. During this process, the pusher 210 abuts against the iron core 410 and pushes the iron core 410 to the predetermined position in the shielding shell 400 until the iron core 410 is fully installed. During this process, the two contact plates 211 make contact with the two opposite edges of the iron core 410, avoiding damage to the functional structure on the iron core 410. At the same time, the design of the contact plates 211 also ensures the stability and accuracy of the iron core 410 during the pushing process. When the pusher plate 200 moves to the predetermined position, the end of the limiting rod 221 abuts against the limiting plate 330, thereby limiting the movement range of the pusher plate 200 at the predetermined position and preventing the pusher 210 from excessively squeezing the iron core 410 and causing damage. After the iron core 410 is pushed, the assembly personnel can directly install screws on the screw holes for assembling the iron core 410 on the banknote detector magnetic head assembly operation plate, thereby further completing the assembly steps of the shielding shell 400 and the iron core 410.

[0043] In another possible embodiment of this utility model, to further improve the accuracy of the movement of the push plate 200, such as... Figure 3 As shown, a slide bar 120 is also provided on the side of the push plate 200 opposite to the pusher 210. One end of the slide bar 120 is fixedly connected to the push plate 200, and the other end is directionally slidably connected to the plate body 100. The slide bar 120 can ensure the stability and accuracy of the push plate 200 during the movement process, and avoid the push plate 200 from deviating or shaking during the sliding process, thereby further improving the efficiency and accuracy of the banknote verification magnetic head assembly.

[0044] In one specific implementation method, such as Figure 3 As shown, the pushing structure of the pusher plate 200 can be electrically driven to further improve the ease of operation and ensure the accuracy and stability of the pusher plate 200's movement. Specifically, the slide rod 120 can be configured as an electric telescopic rod, with one end fixedly connected to the pusher plate 200 and the other end connected to a driver 130 mounted on the plate body 100. By controlling the extension and retraction of the electric telescopic rod through the driver 130, the directional movement of the pusher plate 200 can be achieved, making operation simple and highly automated.

[0045] The aforementioned driver 130 can extend and retract the slide bar 120 via a power device such as a motor. The slide bar 120 and the driver 130 can be securely connected via a connector or other structure to ensure effective power transmission. In this way, the assembly personnel only need to control the start and stop of the driver 130 to easily achieve the directional movement of the push plate 200, greatly improving the assembly efficiency of the banknote verification magnetic head.

[0046] In another possible embodiment of this utility model, such as Figure 4 and Figure 5 As shown, to ensure that the angle between the push plate 200 and the base 300 corresponds during the movement of the push plate 200 and to prevent inaccurate installation of the iron core 410 due to angular deviation, in this embodiment, two slide rails 110 are provided, namely a first track 111 and a second track 112 arranged parallel to each other, with a certain distance between them. Correspondingly, a first slider 231 and a second slider 232 are provided on one side of the push plate 200. The positions of the first slider 231 and the second slider 232 correspond to the positions of the first track 111 and the second track 112, respectively. At the same time, to achieve assembly, the first slider 231 and the second slider 232 are also provided with through-grooves. The grooves fit and slide with the first track 111 and the second track 112. Through the fitting of the first slider 231 and the second slider 232 with the first track 111 and the second track 112, the stability of the push plate 200 during the movement can be ensured, and angular deviation can be avoided, thereby further improving the accuracy and reliability of the iron core 410 installation. Meanwhile, the groove design also facilitates the smooth sliding of the push plate 200 on the slide rail 110, reduces frictional resistance during movement, and improves the ease of operation.

[0047] Based on the above embodiments, the actual usage process of the banknote verification magnetic head assembly operation panel of this utility model is as follows:

[0048] like Figure 4 and Figure 5 As shown, the assembler first places the pre-assembled shielding shell 400 and iron core 410 into the mounting groove 310. At this time, the shielding shell 400 engages with the mounting groove 310, and part of the iron core 410 protrudes from the opening of the mounting groove 310. Then, the assembler activates the driver 130, causing the electric telescopic rod to extend, thereby pushing the push plate 200 to move along the length of the slide rail 110 toward the base 300. During the movement of the push plate 200, the contact plate 211 of the pusher 210 abuts against the iron core 410 and pushes the iron core 410 to a predetermined position within the shielding shell 400. The two contact plates 211 make contact with the two opposite edges of the iron core 410, avoiding damage to the functional structures on the iron core 410. At the same time, the slide rod 120 ensures the stability and accuracy of the push plate 200 during movement.

[0049] When the pusher plate 200 moves to the predetermined position, the end of the limiting rod 221 abuts against the limiting plate 330 on the base 300, thereby limiting the movement range of the pusher plate 200 at that predetermined position and preventing the pusher 210 from excessively squeezing the iron core 410 and causing damage. After the iron core 410 is pushed, the assembly personnel can directly install screws on the screw holes for assembling the iron core 410 on the banknote detector magnetic head assembly operation plate, thereby further completing the assembly steps of the shielding shell 400 and the iron core 410. The entire assembly process is simple to operate and highly automated, greatly improving the assembly efficiency and accuracy of the banknote detector magnetic head.

[0050] Based on the above embodiments, this utility model also provides a banknote detector production apparatus, which includes the banknote detector magnetic head assembly operation plate of the above embodiments. The banknote detector magnetic head assembly operation plate includes: a plate body, on which a plurality of parallel slide rails are provided; a push plate, which is slidably disposed on the plurality of slide rails, and a pusher is disposed on one side of the push plate; and a base, which is fixedly disposed on the plate body along the direction perpendicular to the slide rails, and a mounting groove is disposed on the side of the base facing the pusher. The mounting groove is adapted to the shape of the shielding shell of the banknote detector magnetic head, and the pusher corresponds to the position of the mounting groove. By setting a push plate that slides in a specific direction and a base corresponding to the position of the pusher on the push plate, this utility model allows the pre-assembled shielding shell and iron core to be placed in the mounting groove of the base when assembling the banknote detector magnetic head. By moving the push plate, the pusher squeezes the iron core into a predetermined position inside the shielding shell. During the process, multiple iron cores are subjected to balanced forces and the pushing distance is equal, which can effectively improve the assembly efficiency and accuracy of the banknote detector magnetic head.

[0051] In summary, this utility model provides a banknote verification magnetic head assembly operation board and a banknote verification machine production device. The banknote verification magnetic head assembly operation board includes: a plate body with several parallel slide rails; a push plate slidably mounted on the slide rails, with a pushing component on one side of the push plate; and a base fixedly mounted on the plate body along the direction perpendicular to the slide rails. The base has an installation groove on the side facing the pushing component, the shape of which is adapted to the shielding shell of the banknote verification magnetic head, and the pushing component corresponds to the position of the installation groove. This utility model, by setting a directional sliding push plate and a base corresponding to the position of the pushing component on the push plate, allows the pre-assembled shielding shell and iron core to be placed in the installation groove of the base during banknote verification magnetic head assembly. By moving the push plate, the pushing component presses the iron core into a predetermined position within the shielding shell. During this process, multiple iron cores are subjected to balanced forces, and the pushing distance is equal, effectively improving the assembly efficiency and accuracy of the banknote verification magnetic head.

[0052] It should be understood that the application of this utility model is not limited to the examples above. Those skilled in the art can make improvements or modifications based on the above description, and all such improvements and modifications should fall within the protection scope of the appended claims.

Claims

1. A banknote verification magnetic head assembly operation panel, characterized in that, The banknote verification magnetic head assembly operation panel includes: The plate body is provided with several parallel slide rails; A push plate, which is slidably mounted on a plurality of slide rails, and a pusher is provided on one side of the push plate; A base is fixedly mounted on the plate along a direction perpendicular to the slide rail. A mounting groove is provided on the side of the base facing the pusher. The mounting groove is adapted to the shape of the shielding shell of the banknote verification magnetic head. The pusher is positioned corresponding to the mounting groove.

2. The banknote verification magnetic head assembly operation panel according to claim 1, characterized in that, The pusher is fixedly mounted on the push plate. Two contact plates are provided on the side of the pusher facing the base. The two contact plates are arranged in parallel at a predetermined distance, and the predetermined distance is adapted to the width of the mounting groove.

3. The banknote verification magnetic head assembly operation panel according to claim 2, characterized in that, The contact plate is evenly provided with a plurality of receiving slots, which correspond to the positions of the iron core in the banknote verification magnetic head, and are used to accommodate the leads on the iron core.

4. The banknote verification magnetic head assembly operation panel according to claim 2, characterized in that, The pusher is provided with ear plates on both sides, and a limit rod is detachably provided on the ear plate. The central axis of the limit rod is arranged parallel to the slide rail. A limiting plate is provided on the base corresponding to the position of the limiting rod. The limiting rod and the limiting plate are used to limit the movement range of the push plate.

5. The banknote verification magnetic head assembly operation panel according to claim 1, characterized in that, The base is provided with a plurality of clearance grooves at intervals, the clearance grooves are provided through the mounting grooves, and the clearance grooves correspond to the screw holes on the shield shell used for assembling the iron core.

6. The banknote verification magnetic head assembly operation panel according to claim 5, characterized in that, The width of the upper side plate corresponding to the mounting groove on the base is smaller than the width of the lower side plate of the mounting groove, and a plurality of clearance grooves are provided on the upper side plate of the mounting groove.

7. The banknote verification magnetic head assembly operation panel according to claim 1, characterized in that, A slide rod is provided on the side of the push plate opposite to the pusher. One end of the slide rod is fixedly connected to the push plate, and the other end is directionally slidably connected to the plate body.

8. The banknote verification magnetic head assembly operation panel according to claim 7, characterized in that, The plate is equipped with a driver, and the slide rod is an electric telescopic rod connected to the driver.

9. The banknote verification magnetic head assembly operation panel according to claim 1, characterized in that, The slide rail includes a first track and a second track arranged in parallel, with the first track and the second track arranged in parallel at a certain distance; The push plate is provided with a first slider and a second slider on one side. The first slider and the second slider each include a through groove. The groove is fitted and slidably connected to the first track and the second track.

10. A banknote verification machine production apparatus, characterized in that, The banknote verification machine manufacturing equipment includes the banknote verification magnetic head assembly operation panel as described in any one of claims 1-9.

Images