CN111923124A - Diagonal device for optical filter production and use method thereof - Google Patents

Abstract

The invention discloses a diagonal device for optical filter production and a using method thereof, and the diagonal device comprises a first diagonal mechanism, a material plate, an optical filter weight body, a placing box and a second diagonal mechanism for positioning the transverse position, wherein the first diagonal mechanism is arranged in the placing box, the first diagonal mechanism comprises a bottom plate, support legs, handles, a slide rail, a push plate, a ruler scale and an angle adjusting unit, the support legs are arranged at four corners of the bottom plate, the handles and the slide rail are connected to two sides above the bottom plate through bolts, and the handles are positioned on the outer side of the slide rail. The arrangement of the placing box can better store the first diagonal mechanism and the second diagonal mechanism, the first diagonal mechanism and the second diagonal mechanism are prevented from being damaged when the placing box is not used, and the arrangement of the second diagonal mechanism increases the positioning of the transverse position, so that the positioning of the optical filter weight body is more accurate, and further the production efficiency and the product quality are improved.

Description

Diagonal device for optical filter production and use method thereof

Technical Field

The invention relates to the technical field of optical filter processing, in particular to a diagonal device for optical filter production and a using method thereof.

Background

After the optical filter weight adhering process is completed, the optical filter weight body needs to be sliced according to the required size. The traditional method is to measure on a flitch by using a ruler, cut a knife gap on a preset position of the flitch according to the size to be cut, and then align the knife gap and stick an optical filter weight body.

Chinese patent publication No. CN202656229U discloses an optical filter right angle aligner used in the slicing process of the optical filter production process. The utility model comprises an operation table, a guide rail, a screw rod nut, a reference backer, a pushing plate, a reference plate, a scale and an angle regulator; the guide rail is fixed on the operating platform, and the push plate is connected with the guide rail in a sliding manner; the screw rod nut is fixed on the pushing plate, and the screw rod is connected with the screw rod nut; the reference backer is fixed on the operating platform; the scale comprises a graduated scale and a vernier, the vernier is fixed with the push plate, and the graduated scale is fixed on the operating platform; the angle regulator comprises a body and a regulating shaft, and the body is fixed on the pushing plate; one end of the reference plate is rotatably connected with the pushing plate, and the other end of the reference plate is contacted with an adjusting shaft of the angle adjuster. However, the device is inconvenient to store when not in use, and causes poor dimensional accuracy in the lateral direction, reducing production efficiency and product quality.

Disclosure of Invention

The present invention aims to solve the above problems and to provide a diagonal connector for producing an optical filter and a method for using the same.

The invention realizes the purpose through the following technical scheme:

a diagonal device for producing an optical filter comprises a first diagonal mechanism, a material plate, an optical filter weight body, a placing box and a second diagonal mechanism for positioning the transverse position, wherein the first diagonal mechanism is arranged in the placing box, the first diagonal mechanism comprises a bottom plate, support legs, a handle, a slide rail, a push plate, a ruler mark and an angle adjusting unit, the support legs are arranged at four corners of the bottom plate, the handle and the slide rail are connected to two sides above the bottom plate through bolts, the handle is positioned on the outer side of the slide rail, the push plate is connected to the upper side of the slide rail in a sliding manner, the ruler mark is arranged on one side of the push plate, the angle adjusting unit is rotatably connected to the front of the push plate, the second diagonal mechanism is arranged in front of the angle adjusting unit, the groove is also formed above the bottom plate, and the material plate is clamped in the groove, the optical filter weight body is arranged above the material plate.

Preferably, it includes box, handle, upper cover to place case and bag, there is the handle box the place ahead of lower box through bolted connection, there is the upper cover lower box top rear side through hinge connection, the upper cover front end with the lower box passes through the buckle and connects, the lower box with the upper cover inboard bonds and has the cystosepiment.

Preferably, the stabilizer blade includes lead screw, butterfly turn hand, fills up the foot, lead screw threaded connection be in four edges of bottom plate, the welding of lead screw top has the butterfly turn hand, the lead screw below is rotated and is connected with fill up the foot, it has the rubber layer to bond to fill up the foot below.

Preferably, the yardstick mark includes fixed block, scale, vernier, the fixed block passes through bolted connection and is in the bottom plate top, there is the scale through bolted connection between the fixed block the scale, scale outside sliding connection has the vernier, the vernier passes through bolted connection and is in push pedal one side.

Preferably, the angle adjusting unit comprises a blocking rod and an angle scale, one end of the blocking rod is rotatably connected to the front of the push plate, the rear of the other end of the blocking rod is connected with the angle scale through a screw, the angle scale penetrates through the push plate and is in sliding connection with the push plate, and the second diagonal mechanism is arranged in front of the blocking rod.

Preferably, a plurality of sliding grooves are formed in front of the stop lever, and the inner sides of the sliding grooves are connected with the second diagonal mechanism in a sliding mode.

Preferably, the second diagonal mechanism comprises a positioning unit, a connecting plate and a pushing handle, wherein the positioning unit is arranged below the connecting plate and is connected to the inner side of a sliding groove in the stop rod in a sliding manner, and the pushing handle is welded to the center of the upper portion of the connecting plate.

Preferably, the positioning unit includes locating plate, guide post, first rotation seat, dwang, second rotation seat, first spring, the guide post welds the spout on the shelves pole is inboard, guide post outside sliding connection has the locating plate, locating plate rear end still sliding connection be in spout on the shelves pole is inboard, there is first rotation seat through bolted connection between the locating plate, first rotation seat one side is rotated and is connected with the dwang, the dwang other end is rotated and is connected the second rotates seat the place ahead, the welding of second rotation seat rear has first spring, the welding of first spring rear end is in the inboard central authorities of spout on the shelves pole.

Preferably, the positioning unit includes locating plate, guide post, first rotation seat, dwang, second rotation seat, second spring, the guide post welds the spout on the shelves pole is inboard, guide post outside sliding connection has the locating plate, locating plate rear end still sliding connection be in spout on the shelves pole is inboard, there is first rotation seat through bolted connection between the locating plate, first rotation seat one side is rotated and is connected with the dwang, the dwang other end is rotated and is connected the second rotates seat the place ahead, the second spring housing is established in the guide post outside, and is located between the locating plate.

The invention also provides a using method of the diagonal device for producing the optical filter, which comprises the following steps:

the method comprises the following steps: opening a buckle on the lower box body, then opening the upper cover to take the first diagonal mechanism out of the lower box body, and placing the first diagonal mechanism at a proper position;

step two: the butterfly rotating hand is rotated to drive the screw rod to rotate, so that the bottom plate is driven to ascend, and the bottom plate is in a horizontal state;

step three: and placing the flitch in the groove on the bottom plate, and attaching the rear end face of the flitch to the inner wall of the groove.

Step three: after the gear lever is rotated to enable the gear lever to be at a proper angle, the position of the angle scale is fixed through the screw, and then the position of the gear lever is fixed.

Step four: and moving the push plate, wherein the push plate slides outside the sliding rail, and simultaneously the push plate drives the vernier to slide outside the scale, so that the push plate reaches a proper position.

Step five: and placing the optical filter weight body above the material plate, enabling the side end face of the optical filter weight body to abut against the outer end face of the positioning plate, and enabling the rear end face of the optical filter weight body to abut against the front end face of the stop lever.

Step six: the pushing handle is pushed, the pushing handle drives the connecting plate to move backwards, the connecting plate drives the second rotating seat to move backwards, the second rotating seat drives the rotating rod to rotate, and the rotating rod enables the distance between the positioning plates to be reduced, so that the positioning plates are separated from the optical filter weight body.

Step seven: the push plate is pushed, so that the push plate moves backwards to a proper position, the push handle is loosened, and the positioning plate is reset under the action of the first spring or the second spring.

Step eight: and continuing to place the filter weight according to the fifth step.

Step nine: and placing a proper number of optical filter weight bodies on the material plate according to the steps, and then placing the material plate into a slicing machine.

Has the advantages that: place the setting of case can be better preserve first diagonal mechanism and second diagonal mechanism, prevent when not using, first diagonal mechanism and second diagonal mechanism are damaged, and the setting of second diagonal mechanism has increased the location of horizontal position for it is more accurate to the location of the optical filter mound body, and then has improved production efficiency and product quality.

Additional features of the invention and advantages thereof will be set forth in the description which follows, and in part will be obvious from the description, or may be learned by practice of the invention.

Drawings

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the principles of the invention and not to limit the invention. In the drawings:

FIG. 1 is a schematic diagram of a first structure of a diagonal device for producing an optical filter according to the present invention;

fig. 2 is a second structural diagram of a diagonal device for producing the optical filter according to the present invention;

FIG. 3 is a schematic diagram of a first diagonal mechanism of a diagonal device for producing an optical filter according to the present invention;

FIG. 4 is a top view of a first diagonal mechanism of a diagonal filter for producing an optical filter according to the present invention;

FIG. 5 is a right side view of a first diagonal mechanism of a diagonal filter for production of an optical filter according to the present invention;

FIG. 6 is a schematic diagram of a second diagonal mechanism of a diagonal device for producing an optical filter according to the present invention;

FIG. 7 is a schematic structural diagram of a first embodiment of a diagonal positioning unit for optical filter production according to the present invention;

fig. 8 is a schematic structural diagram of a second embodiment of a diagonal positioning unit for optical filter production according to the present invention.

The reference numerals are explained below:

1. placing a box; 2. a first diagonal mechanism; 3. a second diagonal mechanism; 4. a material plate; 5. a filter weight body; 101. a lower box body; 102. a handle; 103. an upper cover; 201. a base plate; 202. a support leg; 203. a handle; 204. a slide rail; 205. pushing the plate; 206. measuring a scale; 207. an angle adjusting unit; 2021. a screw rod; 2022. turning a butterfly; 2023. a foot pad; 2061. a fixed block; 2062. a scale; 2063. a cursor; 2071. a gear lever; 2072. an angle scale; 301. a positioning unit; 302. a connecting plate; 303. a pushing handle; 3011. positioning a plate; 3012. a guide post; 3013. a first rotating base; 3014. rotating the rod; 3015. a second rotating base; 3016. a first spring; 30101. a second spring.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments.

In the description of the present invention, it is to be understood that the terms "upper", "lower", "front", "rear", "left", "right", "top", "bottom", "inner", "outer", and the like, indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, are merely for convenience in describing the present invention and simplifying the description, and do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be construed as limiting the present invention.

Example 1

As shown in fig. 1-7, a diagonal device for optical filter production comprises a first diagonal mechanism 2, a material plate 4, an optical filter weight body 5, a placing box 1 and a second diagonal mechanism 3 for positioning a transverse position, the first diagonal mechanism 2 is arranged inside the placing box 1, the first diagonal mechanism 2 comprises a bottom plate 201, a support leg 202, a handle 203, a slide rail 204, a push plate 205, a scale mark 206 and an angle adjusting unit 207, the support leg 202 is arranged at four corners of the bottom plate 201, the handle 203 and the slide rail 204 are connected at two sides above the bottom plate 201 through bolts, the handle 203 is positioned at the outer side of the slide rail 204, the push plate 205 is connected above the slide rail 204 in a sliding manner, the scale mark 206 is arranged at one side of the push plate 205, the angle adjusting unit 207 is rotatably connected in front of the push plate 205, the second diagonal mechanism 3 is arranged in front of the angle adjusting unit 207, a groove is further formed above the bottom plate, the optical filter weight body 5 is placed above the material plate 4, the levelness of the bottom plate 201 can be adjusted through the support legs 202, the sliding rail 204 is arranged to support the push plate 205, the push plate 205 can move more stably, the handle 203 is arranged to facilitate the movement of the whole first diagonal mechanism 2, the scale mark 206 is arranged to identify the position of the push plate 205, the angle adjusting unit 207 is arranged to adjust the angle of the optical filter weight body 5, the placing box 1 comprises a lower box body 101, a handle 102 and an upper cover 103, the front of the lower box body 101 is connected with the handle 102 through bolts, the rear side above the lower box body 101 is connected with the upper cover 103 through hinges, the front end of the upper cover 103 is connected with the lower box body 101 through a buckle, foam plates are bonded on the inner sides of the lower box body 101 and the upper cover 103, the first diagonal mechanism 2 can be placed in the lower box body 101 through the arrangement, the upper cover 103 is closed and used for storing the first diagonal mechanism 2, the arrangement of the foam plates reduces the collision of the first diagonal mechanism 2, the arrangement of the handle 102 facilitates the movement of the whole placing box 1, the support legs 202 comprise screw rods 2021, butterfly turners 2022 and cushion feet 2023, the screw rods 2021 are in threaded connection with four corners of the bottom plate 201, the butterfly turners 2022 are welded above the screw rods 2021, the cushion feet 2023 are rotatably connected below the screw rods 2021, rubber layers are bonded below the cushion feet 2023, the butterfly turners 2022 can be rotated, the screw rods 2021 are driven to rotate by the butterfly turners 2022, the bottom plate 201 is driven to lift, the bottom plate 201 is in a horizontal state, the scale 206 comprises fixing blocks 2061, scales 2062 and cursors 2063, the fixing blocks 2061 are connected above the bottom plate 201 through bolts, graduated scales 2062 are connected between the fixing blocks 2061 through bolts, cursors 2063 are slidably connected outside the scales 2062, the push plates 2063 are connected to one side of the fixing blocks 205 through bolts, so that the scales 2062 can be fixed, the ruler 2062 is used for reading the position of the cursor 2063 and realizing the function of controlling the position of the push plate 205, the angle adjusting unit 207 comprises a stop rod 2071 and an angle ruler 2072, one end of the stop rod 2071 is rotatably connected in front of the push plate 205, the other end of the stop rod 2071 is connected with the angle ruler 2072 through a screw, the angle ruler 2072 penetrates through the push plate 205 and is in sliding connection with the push plate 205, the second diagonal mechanism 3 is arranged in front of the stop rod 2071 and can realize the function of adjusting the placing angle of the optical filter body 5 by rotating the stop rod 2071, the angle ruler 2072 is used for reading the angle of the stop rod 2071, a plurality of sliding grooves are arranged in front of the stop rod 2071, the inner side of each sliding groove is in sliding connection with the second diagonal mechanism 3, the second diagonal mechanism 3 comprises a positioning unit 301, a connecting plate 302 and a pushing handle 303, a plurality of positioning units 301 are arranged below the connecting plate 302, the positioning units 301, a pushing handle 303 is welded at the center above the connecting plate 302, so that the pushing handle 303 can be used, the pushing handle 303 drives the connecting plate 302 to move, the connecting plate 302 drives the second rotary seat 3015 in the positioning unit 301 to move, the positioning unit 301 comprises a positioning plate 3011, a guide post 3012, a first rotary seat 3013, a rotary rod 3014, a second rotary seat 3015 and a first spring 3016, the guide post 3012 is welded at the inner side of a chute on the stop rod 2071, the outer side of the guide post 3012 is slidably connected with the positioning plate 3011, the rear end of the positioning plate 3011 is also slidably connected at the inner side of the chute on the stop rod 2071, the first rotary seat 3013 is connected between the positioning plates 3011 through bolts, the rotary rod 3014 is rotatably connected at one side of the first rotary seat 3013, the other end of the rotary rod 3014 is rotatably connected in front of the second rotary seat 3015, the first spring 3016 is welded at the rear end of the second rotary seat 3015, the rear end of the first rotary rod 3016 is welded at the center, rotating the rod 3014 reduces the distance between the positioning plates 3011, so that the positioning plates 3011 are separated from the filter weight body 5.

A method for using diagonal device for producing optical filter, comprising the following steps:

the method comprises the following steps: the buckle on the lower box body 101 is opened, then the upper cover 103 is opened to take the first diagonal mechanism 2 out of the lower box body 101 and place the first diagonal mechanism at a proper position;

step two: the butterfly rotating hand 2022 is rotated, and the butterfly rotating hand 2022 drives the screw rod 2021 to rotate, so as to drive the bottom plate 201 to ascend, so that the bottom plate 201 is in a horizontal state;

step three: the flitch 4 is placed in the groove on the bottom plate 201, and the rear end surface of the flitch 4 is attached to the inner wall of the groove.

Step three: after the gear lever 2071 is rotated to make the gear lever 2071 be at a proper angle, the position of the angle scale 2072 is fixed by a screw, and the position of the gear lever 2071 is fixed.

Step four: moving the push plate 205, the push plate 205 slides outside the slide rail 204, and at the same time, the push plate 205 drives the cursor 2063 to slide outside the scale 2062, so that the push plate 205 reaches the proper position.

Step five: the filter weight 5 is placed above the material plate 4, the side end face of the filter weight 5 abuts against the outer end face of the positioning plate 3011, and the rear end face of the filter weight 5 abuts against the front end face of the stop lever 2071.

Step six: pushing the pushing handle 303, the pushing handle 303 drives the connecting plate 302 to move backward, the connecting plate 302 drives the second rotating seat 3015 to move backward, the second rotating seat 3015 drives the rotating rod 3014 to rotate, the rotating rod 3014 reduces the distance between the positioning plates 3011, and the positioning plate 3011 is separated from the optical filter weight body 5.

Step seven: after the push plate 205 is pushed to move the push plate 205 backward to a proper position and the push handle 303 is released, the positioning plate 3011 is reset under the action of the first spring 3016.

Step eight: and continuing to place the filter weight 5 according to the fifth step.

Step nine: placing a proper number of optical filter weight bodies 5 on the material plate 4 according to the steps, and then placing the material plate 4 into a slicing machine

Example 2

As shown in fig. 8, embodiment 2 differs from embodiment 1 in that: the positioning unit 301 includes a positioning plate 3011, a guide post 3012, a first rotating seat 3013, a rotating rod 3014, a second rotating seat 3015, and a second spring 30101, the guide post 3012 is welded inside a chute on the stop lever 2071, the outer side of the guide post 3012 is connected to the positioning plate 3011 in a sliding manner, the rear end of the positioning plate 3011 is further connected to the inner side of the chute on the stop lever 2071 in a sliding manner, the first rotating seat 3013 is connected between the positioning plates 3011 through bolts, one side of the first rotating seat 3013 is connected to the rotating rod 3014 in a rotating manner, the other end of the rotating rod 3014 is connected in front of the second rotating seat 3015 in a rotating manner, the second spring 30101 is sleeved outside the guide post 3012 and is located between the positioning plates 3011, the rotating rod 3014 can be driven to rotate by the movement of the second rotating seat 3015, the rotating rod 3014 reduces the.

A method for using diagonal device for producing optical filter, comprising the following steps:

the method comprises the following steps: the buckle on the lower box body 101 is opened, then the upper cover 103 is opened to take the first diagonal mechanism 2 out of the lower box body 101 and place the first diagonal mechanism at a proper position;

step two: the butterfly rotating hand 2022 is rotated, and the butterfly rotating hand 2022 drives the screw rod 2021 to rotate, so as to drive the bottom plate 201 to ascend, so that the bottom plate 201 is in a horizontal state;

step three: the flitch 4 is placed in the groove on the bottom plate 201, and the rear end surface of the flitch 4 is attached to the inner wall of the groove.

Step three: after the gear lever 2071 is rotated to make the gear lever 2071 be at a proper angle, the position of the angle scale 2072 is fixed by a screw, and the position of the gear lever 2071 is fixed.

Step four: moving the push plate 205, the push plate 205 slides outside the slide rail 204, and at the same time, the push plate 205 drives the cursor 2063 to slide outside the scale 2062, so that the push plate 205 reaches the proper position.

Step five: the filter weight 5 is placed above the material plate 4, the side end face of the filter weight 5 abuts against the outer end face of the positioning plate 3011, and the rear end face of the filter weight 5 abuts against the front end face of the stop lever 2071.

Step six: pushing the pushing handle 303, the pushing handle 303 drives the connecting plate 302 to move backward, the connecting plate 302 drives the second rotating seat 3015 to move backward, the second rotating seat 3015 drives the rotating rod 3014 to rotate, the rotating rod 3014 reduces the distance between the positioning plates 3011, and the positioning plate 3011 is separated from the optical filter weight body 5.

Step seven: after the push plate 205 is pushed to move the push plate 205 backward to a proper position and the push handle 303 is released, the positioning plate 3011 is reset under the action of the second spring 30101.

Step eight: and continuing to place the filter weight 5 according to the fifth step.

Step nine: after a proper number of optical filter stacks 5 are placed on the material plate 4 according to the steps, the material plate 4 is placed into a slicing machine.

The foregoing illustrates and describes the principles, general features, and advantages of the present invention. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, which are described in the specification and illustrated only to illustrate the principle of the present invention, but that various changes and modifications may be made therein without departing from the spirit and scope of the present invention, which fall within the scope of the invention as claimed. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims (10)

1. The utility model provides a diagonal angle ware of light filter production, includes first diagonal angle mechanism (2), flitch (4), light filter mound body (5), its characterized in that: the novel multifunctional storage box is characterized by further comprising a storage box (1) and a second diagonal mechanism (3) for positioning the transverse position, wherein the first diagonal mechanism (2) is arranged inside the storage box (1), the first diagonal mechanism (2) comprises a bottom plate (201), support legs (202), a handle (203), a sliding rail (204), a push plate (205), a scale mark (206) and an angle adjusting unit (207), the support legs (202) are arranged at four corners of the bottom plate (201), the handle (203) and the sliding rail (204) are connected to two sides above the bottom plate (201) through bolts, the handle (203) is located on the outer side of the sliding rail (204), the push plate (205) is connected to the upper portion of the sliding rail (204) in a sliding manner, the scale mark (206) is arranged on one side of the push plate (205), and the angle adjusting unit (207) is rotationally connected to the front portion of the push plate (, the second diagonal mechanism (3) is arranged in front of the angle adjusting unit (207), a groove is formed above the bottom plate (201), the material plate (4) is connected in the groove in a clamping mode, and the optical filter weight body (5) is arranged above the material plate (4).

2. A diagonal for optical filter production according to claim 1, wherein: the storage box (1) comprises a lower box body (101), a lifting handle (102) and an upper cover (103), the front of the lower box body (101) is connected with the lifting handle (102) through a bolt, the rear side of the upper portion of the lower box body (101) is connected with the upper cover (103) through a hinge, the front end of the upper cover (103) is connected with the lower box body (101) through a buckle, and a foam board is bonded on the inner side of the lower box body (101) and the inner side of the upper cover (103).

3. A diagonal for optical filter production according to claim 1, wherein: the supporting legs (202) comprise screw rods (2021), butterfly handles (2022) and pad feet (2023), the screw rods (2021) are in threaded connection with four corners of the bottom plate (201), the butterfly handles (2022) are welded above the screw rods (2021), the pad feet (2023) are rotatably connected below the screw rods (2021), and rubber layers are bonded below the pad feet (2023).

4. A diagonal for optical filter production according to claim 1, wherein: the length scale (206) includes fixed block (2061), scale (2062), vernier (2063), fixed block (2061) pass through bolted connection in bottom plate (201) top, there is the scale through bolted connection between fixed block (2061) scale (2062), scale (2062) outside sliding connection has vernier (2063), vernier (2063) pass through bolted connection in push pedal (205) one side.

5. A diagonal for optical filter production according to claim 1, wherein: angle adjusting unit (207) includes shelves pole (2071), angle scale (2072), shelves pole (2071) one end is rotated and is connected push pedal (205) the place ahead, there is angle scale (2072) shelves pole (2071) other end rear through the screw connection, angle scale (2072) pass push pedal (205), and with push pedal (205) sliding connection, shelves pole (2071) the place ahead is provided with second diagonal mechanism (3).

6. A diagonal filter production according to claim 5, wherein: a plurality of sliding grooves are arranged in front of the stop lever (2071), and the inner sides of the sliding grooves are connected with the second diagonal mechanism (3) in a sliding manner.

7. A diagonal filter production according to claim 6, wherein: the second diagonal mechanism (3) comprises a positioning unit (301), a connecting plate (302) and a push handle (303), wherein the plurality of positioning units (301) are arranged below the connecting plate (302), the positioning units (301) are connected to the inner sides of sliding grooves in the gear rods (2071) in a sliding mode, and the push handle (303) is welded to the center above the connecting plate (302).

8. A diagonal filter production according to claim 7, wherein: the positioning unit (301) comprises a positioning plate (3011), a guide post (3012), a first rotating seat (3013), a rotating rod (3014), a second rotating seat (3015) and a first spring (3016), the guide post (3012) is welded at the inner side of the sliding groove on the stop lever (2071), the positioning plate (3011) is connected at the outer side of the guide post (3012) in a sliding way, the rear end of the positioning plate (3011) is also connected to the inner side of the sliding groove on the stop lever (2071) in a sliding way, the first rotating seat (3013) is connected between the positioning plates (3011) through bolts, one side of the first rotating seat (3013) is rotatably connected with the rotating rod (3014), the other end of the rotating rod (3014) is rotatably connected with the front part of the second rotating seat (3015), the first spring (3016) is welded at the rear part of the second rotary seat (3015), the rear end of the first spring (3016) is welded at the center of the inner side of the sliding groove on the stop lever (2071).

9. A diagonal filter production according to claim 7, wherein: the positioning unit (301) comprises a positioning plate (3011), a guide post (3012), a first rotating seat (3013), a rotating rod (3014), a second rotating seat (3015) and a second spring (30101), the guide post (3012) is welded at the inner side of the sliding groove on the stop lever (2071), the positioning plate (3011) is connected at the outer side of the guide post (3012) in a sliding way, the rear end of the positioning plate (3011) is also connected to the inner side of the sliding groove on the stop lever (2071) in a sliding way, the first rotating seat (3013) is connected between the positioning plates (3011) through bolts, one side of the first rotating seat (3013) is rotatably connected with the rotating rod (3014), the other end of the rotating rod (3014) is rotatably connected with the front part of the second rotating seat (3015), the second spring (30101) is sleeved on the outer side of the guide posts (3012) and is located between the positioning plates (3011).

10. A method for using diagonal device for producing optical filter is characterized in that: the method comprises the following steps: the method comprises the following steps: the buckle on the lower box body (101) is opened, then the upper cover (103) is opened to take the first diagonal mechanism (2) out of the lower box body (101) and place the first diagonal mechanism at a proper position;

step two: the butterfly rotating hand (2022) is rotated, the butterfly rotating hand (2022) drives the screw rod (2021) to rotate, and then the bottom plate (201) is driven to ascend, so that the bottom plate (201) is in a horizontal state;

step three: placing the material plate (4) in the groove on the bottom plate (201), and attaching the rear end face of the material plate (4) to the inner wall of the groove;

step three: after the gear lever (2071) is rotated to enable the gear lever (2071) to be at a proper angle, the position of the angle scale (2072) is fixed through a screw, and then the position of the gear lever (2071) is fixed;

step four: the push plate (205) is moved, the push plate (205) slides on the outer side of the sliding rail (204), and meanwhile the push plate (205) drives the cursor (2063) to slide on the outer side of the ruler (2062), so that the push plate (205) reaches a proper position;

step five: placing the optical filter weight body (5) above the material plate (4), enabling the side end face of the optical filter weight body (5) to abut against the outer end face of the positioning plate (3011), and enabling the rear end face of the optical filter weight body (5) to abut against the front end face of the stop rod (2071);

step six: pushing a push handle (303), wherein the push handle (303) drives a connecting plate (302) to move backwards, the connecting plate (302) drives a second rotating seat (3015) to move backwards, the second rotating seat (3015) drives a rotating rod (3014) to rotate, and the rotating rod (3014) enables the distance between the positioning plates (3011) to be reduced and enables the positioning plates (3011) to be separated from the optical filter weight body (5);

step seven: pushing the push plate (205) to enable the push plate (205) to move backwards to a proper position, releasing the push handle (303), and enabling the positioning plate (3011) to reset under the action of the first spring (3016) or the second spring (30101);

step eight: continuously placing the optical filter weight body (5) according to the fifth step;

step nine: and (3) placing a proper number of optical filter weight bodies (5) on the material plate (4) according to the steps, and then placing the material plate (4) into a slicing machine.

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