CN220846242U - Mask frame and mask device - Google Patents

Abstract

The utility model provides a mask frame and a mask device, and relates to the technical field of metal masks. The mask frame comprises a plurality of metal strips and pin blocks, wherein grooves are formed in two ends of each metal strip; the metal strips are sequentially abutted end to form a rectangular frame, and grooves formed at the abutting ends of any two abutted metal strips are combined to form a pin groove; the pin block is provided with a shape and a size which are matched with those of the pin groove, and is arranged in the pin groove; the pin block and the metal strip are welded with each other at the joint of the metal strip and the metal strip, so as to obtain the mask frame. According to the utility model, after the metal strips forming the mask frame are abutted against each other, the metal strips are locked together by the pin blocks, and during subsequent welding, the metal strips do not need to be additionally fixed, and the metal strips do not generate relative movement, so that the welding seams are uniform and consistent, and the quality of the mask frame is improved.

Description

Mask frame and mask device

Technical Field

The utility model relates to the technical field of metal masks, in particular to a mask frame and a mask device.

Background

The Mask Frame (Frame) is used as a carrier of the metal Mask (METAL MASK, abbreviated as Mask) and is a main component for forming the metal Mask jig.

The mask frame is usually integrally formed from a single sheet of material, and this production method produces a large amount of excess material, which is generally not reused, but is recovered as scrap metal, which results in a high production cost for the single mask frame. In order to solve the problem of high production cost, a method for preparing a mask frame by splicing is newly adopted in the industry, wherein the method is to cut a raw material plate into metal strips, and a plurality of metal strips are connected end to end and welded together to form a rectangular mask frame. This way the generation of waste material can be substantially reduced.

However, when the mask frame is welded, relative movement is likely to occur between the metal bars that are not fixed to each other, resulting in separation or displacement of the metal bars from each other, enlargement or displacement of the joints from proper positions, affecting the progress of welding, and resulting in degradation of product quality. There is thus a need for a new solution.

Disclosure of utility model

In order to solve the problem that the welding mask frame is easy to cause relative movement of metal strips in the prior art and provide a mask frame with high quality, the utility model provides a mask frame and a mask device.

The mask frame of the present utility model includes:

The metal strips are sequentially abutted end to form a rectangular frame, grooves are formed in two ends of each metal strip, and grooves formed in the abutting ends of any two abutted metal strips are combined to form a pin groove;

the groove is provided with a narrow part and a wide part, the narrow part of the wide part of any groove is far away from the other groove combined with the narrow part, and a pin groove formed by combining the two grooves is in a shape of narrow middle and wide at two ends;

And

The pin blocks are provided with shapes and sizes matched with the pin grooves and are accommodated in the pin grooves;

the pin block and the metal strip are welded to each other at the junctions of the metal strip and the metal strip.

As a further scheme, the pin grooves are positioned on the upper side surface or the lower side surface of the rectangular frame, and the depth direction of the pin grooves is consistent with the thickness direction of the metal strip;

The two opposite surfaces of the two grooves combined into the pin groove are communicated with each other.

As a further proposal, the groove penetrates through the metal strip in the thickness direction of the metal strip; or alternatively

The depth of the groove in the thickness direction of the metal strip is a part of the thickness of the metal strip.

As a further scheme, the depth of the groove along the thickness direction of the metal strip is half of the thickness of the metal strip.

As a further scheme, two symmetrical sides of one group of the pin block are respectively provided with two convex parts protruding outwards, and a concave part recessed inwards is arranged between the two convex parts;

the two concave parts of the pin block are matched with the narrow parts of the two grooves forming the pin groove;

The four protrusions of the pin block are adapted to the wide portions of the two recesses constituting the pin slot.

As a further scheme, the concave part is rectangular, semicircular or semi-elliptic.

As a further aspect, the maximum depth of the concave portion is not less than 1mm.

As a further scheme, the metal strip comprises 2-4 metal strips;

The shape of the metal strip comprises one or two of a straight line shape, a right angle shape and a '匚' shape.

The mask device of the present utility model includes:

Masking plate; and

The mask frame;

The mask plate is jointed on the mask frame.

The beneficial effects of the utility model are as follows:

1) After the metal strips forming the mask frame are abutted against each other, the metal strips are locked together through the pin blocks, and during subsequent welding, the metal strips do not need to be additionally fixed, and the metal strips do not generate relative movement, so that welding seams are uniform and consistent, and the quality of the mask frame is improved;

2) The two metal strips are connected by adopting independent pin block designs, and when the metal strips are combined, the heavier metal strips are not required to be moved to realize the clamping, so that the assembly difficulty can be greatly reduced, and the production efficiency is improved.

Still other additional aspects and advantages of the utility model will be set forth in part in the description which follows and, in part, will be obvious from the description, or may be learned by practice of the utility model.

Drawings

FIG. 1 is a schematic view of a mask frame according to the present utility model;

FIG. 2 is an exploded view of a portion of the structural members of the mask frame of FIG. 1, shown disassembled;

FIG. 3 is a schematic view of a structure of a connection end of a metal strip; wherein fig. 3 (a) shows a first connection end on one of the metal strips, fig. 3 (b) shows a second connection end on the other metal strip, and fig. 3 (c) shows the first connection end of fig. 3 (a) combined with the second connection end of fig. 3 (b) to form a pin slot;

FIG. 4 is a schematic view of another construction of the connecting end of the metal strip; wherein fig. 4 (a) shows a first connection end on one of the metal strips, and fig. 4 (b) shows a second connection end on the other metal strip that mates with the first connection end in fig. 4 (a);

FIG. 5 is a schematic view of a pin block for connecting two metal strips;

FIG. 6 is a schematic illustration of a recess of a pin block implemented in a different manner; wherein, the shape of the concave part on the pin block shown in fig. 6 (a) is rectangular, the shape of the concave part on the pin block shown in fig. 6 (b) is semicircular, and the shape of the concave part on the pin block shown in fig. 6 (c) is semi-elliptical;

FIG. 7 is a schematic diagram of a different embodiment of a mask frame structure; wherein, fig. 7 (a) shows a mask frame composed of one straight metal bar 1a and one "匚" shaped metal bar 1b, fig. 7 (b) shows a mask frame composed of two straight-angle shaped metal bars 1c and 1d, fig. 7 (c) shows a mask frame composed of two straight-angle shaped metal bars 1e, 1f and 1g, fig. 7 (d) shows a mask frame composed of four straight-line shaped metal bars 1h, 1i, 1j and 1k, fig. 7 (e) shows a mask frame composed of four metal bars 1m, 1n, 1p, 1q abutted with 45 ° inclined surfaces of the ends;

In the figure: 1. a metal strip; 10. a pin slot; 11. a first connection end; 12. a second connection end; 100. a groove; 101. a narrow portion; 102. a wide portion;

2. A pin block; 21. a convex portion; 22. a recess.

Detailed Description

In order to make the objects, technical solutions and advantages of the present utility model more apparent, the present utility model will be described in further detail below with reference to the accompanying drawings, and it should be apparent that the embodiments described below are only some embodiments of the present utility model, but not all embodiments. For reference, the following description and drawings are merely illustrative examples for aiding in understanding the present utility model, and are not intended to limit the technical scope of the present utility model. In other words, the embodiments described below may have various modifications, which fall within the technical spirit of the present utility model, and those skilled in the art to which the present utility model pertains can easily understand the technical spirit of the present utility model through the following description. The utility model will be further described with reference to the drawings and examples.

The present utility model provides a mask frame, one structure of which is shown in fig. 1, and the mask frame of the present utility model will be described with reference to fig. 1.

According to the present utility model, the mask frame includes a plurality of metal bars 1, and the metal bars 1 are bar-shaped members cut from SUS420 stainless steel, SUS304 stainless steel, or Invar36 alloy. In the mask frame, a plurality of metal strips 1 are sequentially abutted end to form a rectangular frame. Grooves 100 are formed at two ends of the metal strip 1, and in the enclosed rectangular frame, the grooves 100 at the abutting ends of any two abutting metal strips 1 are combined to form a pin groove 10.

By way of example, fig. 3 shows the structural arrangement of the grooves 100 of two abutting metal strips 1 at their abutting ends. Wherein the first connection end 11 shown in fig. 3 (a) belongs to one metal strip 1 in the rectangular frame, the second connection end 12 shown in fig. 3 (b) belongs to the other metal strip 1 in the rectangular frame, which is abutted against the first connection end 11 in fig. 3 (a), the side surface in the width direction of the first connection end 11 is abutted against the end surface of the second connection end 12 in the extending direction of the metal strip 1, and the grooves 100 at the two connection ends are combined to form the pin groove 10 shown in fig. 3 (c).

Referring to fig. 3 (a) and 3 (b), the groove 100 has a narrow portion 101 and a wide portion 102. The narrow portion 101 corresponds to a portion of the groove 100 where the space is narrow, and the wide portion 102 corresponds to a portion of the groove 100 where the space is wide. The narrower space and the wider space referred to herein refer to the dimension of the space in the extending direction of the metal strip 1 or in the width direction of the metal strip 1, rather than the depth of the groove 100 in the thickness direction of the metal strip 1. The wide portion 102 of any groove 100 is farther from another groove 100 to which it is joined than the narrow portion 101 thereof, taking the example in fig. 3 (a) and 3 (b), where the narrow portion 101 is closer to the junction surface of the connecting end to which it belongs and the other connecting end, and the wide portion 102 is farther from the junction surface than the narrow portion 101, so that the groove 100 is formed to change in size from small to large from the junction surface to the inside of the connecting end. Referring to fig. 3 (c), the pin slot 10 formed by combining the two grooves 100 is shown as being narrow at the center and wide at both ends.

An exploded view of a portion of the structural components of the mask frame of fig. 1 is shown disassembled in fig. 2. Referring to fig. 2, the mask frame further includes a plurality of pin blocks 2, and the pin blocks 2 have a shape and size adapted to the pin grooves 10 and are accommodated in the pin grooves 10. One configuration of the pin block 2 is shown in fig. 5. Referring to fig. 5, two symmetrical sides of the pin block 2 are respectively provided with two convex parts 21 protruding outwards, a concave part 22 recessed inwards is arranged between the two convex parts 21, the two concave parts 22 of the pin block 2 are matched with the narrow parts 101 of the two grooves 100 forming the pin groove 10, and the four convex parts 21 of the pin block 2 are respectively matched with the wide parts 102 of the two grooves 100 forming the pin groove 10. In this way, the two metal strips 1 can be locked together after the pin blocks 2 are fitted into the pin grooves 10.

In addition, the pin blocks 2 and the metal strips 1 and 1 are welded at the joint parts so as to enhance the reliability of connection of each part on the mask frame and reduce the deformation caused by welding the mask plate by the subsequent screen. The welding may be performed in a variety of welding modes, such as laser welding, electron beam welding, friction stir welding, ultrasonic welding, and the like, to name a few.

In the conventional method for manufacturing the mask frame by using the welding mode, when the rectangular frame consisting of the metal strips is welded, the metal strips are not mutually locked, so that the metal strips which are abutted against each other are easily separated or deflected due to the fact that the external force is applied, the smooth welding is affected, the rectangular shape of the frame is distorted, and the product precision of the mask frame is affected. Therefore, when welding the mask frame, it is often necessary to use a positioning tool to assist in fixing each metal strip forming the rectangular frame, and especially, different positioning tools are also required to be prepared for different mask frames with different specifications to be suitable for use. In addition, the metal strip is relatively heavy, so that the metal strip is clamped in the positioning tool with certain difficulty.

By means of the design that the pin grooves 10 are matched with the pin blocks 2, the metal strips 1 forming the mask frame can be locked together through the pin blocks 2 after the metal strips 1 are abutted against each other, and in the subsequent welding process, the metal strips 1 do not need to be additionally fixed, the metal strips 1 do not generate relative movement, welding seams are uniform and consistent, and the quality of the mask frame is improved.

Furthermore, the provision of the separate pin blocks 2 is also a consideration based on the difficulty of assembly. Supposing that the pin block 2 is not independent but is a snap-in structure provided on one of the strips 1, which is integral with one of the strips 1, it is necessary to lift the entire strip 1 and snap-in the snap-in of the strip 1 into the recess 100 in the other strip 1 when assembling the rectangular frame. Because the metal strip 1 is of a pure metal solid structure, the weight is large, and the fit clearance between the two metal strips 1 is small, the structure greatly increases the assembly difficulty, slows down the efficiency and is quite unfavorable for mass production. In order to solve the problem, the mask frame of the utility model adopts the independent pin block 2 design to connect the two metal strips 1, and when the two metal strips 1 are assembled, the pin block 2 is only required to be taken to be put into the pin groove 10 formed by combining the grooves 100 on the two metal strips 1, and the whole metal strips 1 are not required to be moved to clamp the end parts of the two metal strips 1, so that the assembly difficulty can be greatly reduced, and the production efficiency is improved.

Further, referring to the example of fig. 3, the pin groove 10 on the metal bar 1 should be located at the upper side or the lower side of the rectangular frame composed of the metal bar 1, and the depth direction of the pin groove 10 coincides with the thickness direction of the metal bar 1. In the assembly process, the rectangular frame formed by the metal strips 1 is generally horizontally placed on the workbench, and the pin grooves 10 face upwards, so that the pin blocks 2 can be smoothly clamped in. More importantly, in the design, the joint to be welded generated after the pin block 2 is installed in the pin groove 10 is deep along the thickness direction of the metal strips 1, the depth of the joint corresponds to the depth of subsequent welding, and under the condition that the pin block 2 provides reliable locking for the two metal strips 1, the maximum depth of the joint is only the thickness of the metal strips 1, so that the welding can be performed in various welding modes such as laser welding, electron beam welding, friction stir welding, ultrasonic welding and the like, and the reliability of the welding is ensured.

In the rectangular frame surrounded by the metal strips 1, two opposite surfaces of the grooves 100 combined into the pin grooves 10 are mutually communicated. Referring to fig. 3 (c), the narrow portion in the middle of the corresponding pin groove 10 is the interpenetration portion. The mutually penetrating design makes the pin groove 10 into a whole, and provides a containing space in the middle part of the pin block 2. Here, the depth of the narrow portion in the middle of the pin groove 10 in the thickness direction of the metal strip 1 does not necessarily coincide with the depth of the wide portion 102 of the two grooves 100 constituting the pin groove 10, i.e., may be smaller or larger than the depth of the wide portion 102 of the groove 100, and accordingly, the portion of the pin block 2 corresponding to the narrow portion in the middle of the pin groove 10 is formed with a recess or a protrusion adapted thereto.

Referring to fig. 4, in some embodiments, the grooves 100 on the metal strip 1 penetrate the metal strip 1 in the thickness direction of the metal strip 1. After the first connection end 11 of the metal strip 1 shown in fig. 4 (a) and the second connection end 12 of the metal strip 1 shown in fig. 4 (b) are abutted against each other, the grooves 100 at the two connection ends are combined to form pin grooves 10 penetrating the upper and lower surfaces of the rectangular frame. Correspondingly, the pin block 2 has the same thickness as the metal strip 1. After the pin block 2 is installed in the pin groove 10, the same joint is formed on the upper surface and the lower surface of the rectangular frame, and under the condition that the thickness of the metal strip 1 is smaller, the joint can be welded from only one surface of the rectangular frame, and the welding depth is equal to the thickness of the metal strip, so that the production efficiency is improved.

Referring to fig. 3, in other embodiments, the depth of the groove 100 in the thickness direction of the metal strip 1 is only a part of the thickness of the metal strip 1, i.e., the groove 100 does not penetrate the metal strip 1 in the depth direction thereof. Preferably, the depth of the groove 100 in the thickness direction of the metal strip 1 is half the thickness of the metal strip 1. Accordingly, the thickness of the pin block 2 should also be a fraction of the thickness of the metal strip 1, consistent with the depth of the groove 100. After the pin block 2 is installed in the pin slot 10, different joints are formed on the upper surface and the lower surface of the rectangular frame, wherein the joint of one surface comprises the joint of the pin block 2 and the edge of the groove 100 and the joint formed by butt joint of two metal strips 1 on two sides of the joint, and the joint of the other surface is completely formed by butt joint of two metal strips 1. When welding, the joints on the two sides need to be respectively welded by overturning. It should be noted that, in the example shown in fig. 3, since the pin grooves 10 do not penetrate through the upper and lower surfaces of the rectangular frame, after the pin blocks 2 are installed in the pin grooves 10, the mask frame can be optionally moved without turning over, so that the pin blocks 2 do not fall out of the pin grooves 10, which provides convenience for the situation that the pin blocks need to be transported in the production process. In addition, because the welding seams at two sides of the same joint of the mask frame are different, the influence of the welding seams on the mechanical property of the mask frame can be reduced, and the welding reliability is improved.

A schematic of the structure of the pin block 2 in the different embodiments is shown in fig. 6. Referring to fig. 6 (a), 6 (b) and 6 (c), the shape of the recess 22 on the pin block 2 may be rectangular, semicircular or semi-elliptical, and may be selected according to the need, the ease of processing, etc. in actual production. Correspondingly, the shape of the narrow part in the middle of the pin groove 10 formed by the combination of the grooves 100 on the two metal strips 1 should be consistent with the shape of the concave part 22 on the pin block 2. The maximum depth of the recess 22 is not less than 1mm, preferably 3mm to 5mm, in view of the connection reliability of the two metal strips 1 by the pin block 2. Illustratively, the maximum depth of the recess 22 may be 1mm, 2mm, 3mm, 4mm, 5mm, and above.

It should be noted that the fit clearance between the pin block 2 and the pin groove 10 is set to be small before the mask frame is welded, and the single-side fit clearance should be controlled to be less than 0.5 mm. In order to ensure that the relative movement between the two metal strips 1 is smaller after the pin blocks 2 are placed in the pin grooves 10, the single-side fit clearance should be controlled to be smaller, preferably below 0.1 mm. Illustratively, the single-sided fit clearance of the pin block 2 with the pin slot 10 is 0.05mm, 0.06mm, 0.07mm, 0.08mm, 0.09mm, etc. The maximum depth of the recess 22 in the pin block 2 and the dimension of the narrow middle of the pin slot 10 should be chosen with reference to the fit clearance of the pin block 2 with the pin slot 10. When the fit clearance between the pin block 2 and the pin slot 10 is larger, the maximum depth of the concave part 22 on the pin block 2 should also be selected to be larger, and the narrow part in the middle of the corresponding pin slot 10 should also be narrower; however, if the fit clearance between the pin block 2 and the pin slot 10 is small, it is not necessary to select a recess 22 having a small depth and a narrow portion of the pin slot 10 adapted thereto.

Referring to fig. 7, the mask frame includes 2 to 4 metal strips 1, and the metal strips 1 in the mask frame have various combinations of shapes, such as a straight metal strip 1, a right angle metal strip 1, and a '匚' shaped metal strip 1. The mask frame contains one to two of the above-mentioned metal strips 1 of different shapes.

By way of example, fig. 7 (a) shows a mask frame made of one linear metal bar 1a and one "匚" shaped metal bar 1 b; fig. 7 (b) shows a mask frame made of two rectangular metal strips 1c and 1 d; fig. 7 (c) shows a mask frame made of two straight metal strips 1e, 1f and one rectangular metal strip 1 g; fig. 7 (d) shows a mask frame made of four linear metal strips 1h, 1i, 1j and 1 k.

The surface on which the two metal strips 1 are abutted does not necessarily have to be the end surface in the extending direction of one metal strip 1 and the end surface in the width direction of the other metal strip 1, and may be the end surfaces on both ends of the two metal strips 1. By way of example, in a mask frame shown in fig. 7 (e), the end surfaces of four metal strips 1m, 1n, 1p, 1q are all 45 ° inclined surfaces, and the metal strips 1 are abutted with each other by the end surfaces.

Furthermore, according to the present utility model, the number of metal strips 1 included in the mask frame is not limited to the various cases shown in fig. 7, and more metal strips 1 may be made into the mask frame. For example, the metal strips 1 forming any one of the rims of the mask frame may consist of a plurality of shorter metal strips 1, which shorter metal strips 1 are also joined by pin blocks 2.

The mask frame of the present utility model has been described in detail as much as possible, but the present utility model is not limited thereto, and includes a method of manufacturing such a mask frame. The manufacturing method of the mask frame comprises the following steps:

1. Manufacturing metal strip

The material for manufacturing the metal strip 1 is selected from purchased raw material plates, or selected from rest materials remained after the mask frame integrally formed by processing the plates, wherein the raw material plates are preferably stainless steel of SUS420 and SUS304, invar36 and the like.

The raw material plate is manufactured into a metal strip 1 with a straight line-shaped or right-angle-shaped or 匚 -shaped structure by cutting, milling and the like, and grooves 100 are formed at two ends of the metal strip 1. When the groove 100 is formed, the two metal strips 1 are abutted against each other in a manner of forming a mask frame, and a predetermined pin groove 10 is formed at the abutting position of the two metal strips 1 at one time. Compared with the processing of the grooves 100 on the single metal strip 1, the method can ensure that the precision of the pin grooves 10 formed by combining the processed grooves 100 is higher, so that the pin blocks 2 can still be smoothly installed in the pin grooves 10 under the condition that the unilateral fit clearance between the pin blocks 2 and the pin grooves 10 is smaller.

The metal strip 1 and its groove 100 structure are described in detail above and will not be described here again.

2. Manufacturing pin block

When the pin block 2 is manufactured, small pieces of excess material which are not enough to be processed into the metal strip 1 are preferably used for processing, so that the material waste can be reduced, and the material cost can be reduced. According to the pin grooves 10 formed by the joint of the grooves 100 on the preset two metal strips 1, the pin blocks 2 matched with the grooves are processed by cutting, milling and the like.

The unilateral fit clearance between the control pin block 2 and the pin groove 10 is below 0.5mm, preferably 0.05 mm-0.1 mm. The assembly difficulty is not increased, and the relative movement between the two metal strips 1 after the pin block 2 is arranged in the pin groove 10 can be ensured to be smaller.

3. Assembly

A plurality of metal strips 1 are connected end to form a rectangular frame, and grooves 100 at the end parts of the metal strips 1 are combined with grooves 100 at the end parts of the other metal strips 1 connected with the grooves to form pin grooves 10.

The manufactured pin blocks 2 are fitted into the corresponding pin grooves 10, and the metal strips 1 separated from each other are connected into a unitary rectangular frame by means of the pin blocks 2.

4. Welding

The assembled rectangular frame is placed on a workbench of a welding device, and the pin grooves 10 and the metal strips 1 and 1 are welded. Welding is performed along the joints between the pin grooves 10 and the metal strips 1, 1 and 1.

For the different groove 100 structures shown in fig. 3 and 4, and the pin block 2 structure matched with the pin groove 10 formed by combining the groove 100, the welding modes of double-sided welding and single-sided welding can be adopted for welding respectively.

For example, in the embodiment shown in fig. 3, after the pin block 2 is fitted into the pin groove 10, different joints are formed on the upper and lower surfaces of the rectangular frame, and welding is performed by double-sided welding. When welding is carried out, the welding depth is controlled to be half of the thickness of the metal strip 1, all joints on the upward face of the rectangular frame are welded, then the rectangular frame is turned over, and the joints on the other face of the turned over are welded by controlling the same welding depth.

For another example, in the embodiment shown in fig. 4, after the pin block 2 is installed in the pin groove 10, the same joints are formed on the upper surface and the lower surface of the rectangular frame, and the welding is performed by adopting a single-sided welding mode, the welding depth is controlled to be at least the thickness of the rectangular frame, and the welding of each joint is completed at one time without turning over the rectangular frame.

The mask frame prepared by the method can realize the secondary utilization of the production residual materials with smaller size, improve the utilization rate of the residual materials and reduce the production cost. In addition, the damage of welding to the metal characteristics has little influence on the mechanical properties of the mask frame, and the mechanical properties of the manufactured mask frame are good.

In addition, the utility model also comprises a mask device manufactured by the mask frame, the mask frame is used as a carrier frame, and the mask plate is stretched and welded on the mask frame to form the mask device. The mask plate comprises a common metal mask plate (CMM), a precise metal mask plate (FMM) and the like.

Finally, it should be emphasized that the foregoing embodiments are merely illustrative of and not limiting on the technical solutions of the embodiments of the present utility model, and although the embodiments of the present utility model have been described in detail with reference to the preferred embodiments, it should be understood by those skilled in the art that modifications and equivalents may be made to the technical solutions of the embodiments of the present utility model, and such modifications and equivalents do not depart from the scope of the technical solutions of the embodiments of the present utility model.

Claims (9)

1. A mask frame, comprising:

The metal strips (1) are sequentially abutted end to form a rectangular frame, grooves (100) are formed in two ends of each metal strip (1), and the grooves (100) formed in the abutting ends of any two abutted metal strips (1) are combined to form a pin groove (10);

The grooves (100) are provided with narrow parts (101) and wide parts (102), the narrow part (101) of the wide part (102) of any groove (100) is far away from the other groove (100) combined with the narrow part, and the pin groove (10) formed by combining the two grooves (100) is in a middle narrow and wide at two ends;

And

The pin blocks (2) are provided with shapes and sizes matched with the pin grooves (10), and are accommodated in the pin grooves (10);

The pin block (2) and the metal strip (1) are welded with each other at the joint of the metal strip (1) and the metal strip (1).

2. Mask frame according to claim 1, characterized in that the pin grooves (10) are located on the upper side or the lower side of the rectangular frame, the depth direction of the pin grooves (10) being consistent with the thickness direction of the metal strips (1);

the two grooves (100) combined into the pin slot (10) are mutually communicated on the opposite surfaces.

3. Mask frame according to claim 1, characterized in that the grooves (100) penetrate the metal strip (1) in the thickness direction of the metal strip (1); or alternatively

The depth of the groove (100) in the thickness direction of the metal strip (1) is a part of the thickness of the metal strip (1).

4. A mask frame according to claim 3, characterized in that the depth of the groove (100) in the thickness direction of the metal strip (1) is half the thickness of the metal strip (1).

5. Mask frame according to claim 1, characterized in that two convex outwards protruding parts (21) are provided on each of two symmetrical sides of one set of pin blocks (2), and a concave inwards concave part (22) is provided between the two convex parts (21);

The two recesses (22) of the pin block (2) are adapted to the narrow portions (101) of the two recesses (100) constituting the pin slot (10);

Four projections (21) of the pin block (2) are adapted to the wide portions (102) of the two recesses (100) constituting the pin slot (10).

6. Mask frame according to claim 5, characterized in that the recess (22) is rectangular or semi-circular or semi-elliptical.

7. Mask frame according to claim 5, characterized in that the maximum depth of the recess (22) is not less than 1mm.

8. Mask frame according to claim 1, characterized in that it comprises 2-4 of said metal strips (1);

The shape of the metal strip (1) comprises one or two of a straight line shape, a right angle shape and a '匚' shape.

9. A masking apparatus, comprising:

Masking plate; and

A mask frame as claimed in any one of claims 1 to 8;

The mask plate is jointed on the mask frame.