CN211136823U - Double-sided sand planting structure for grid cloth sand planting and double-sided sand planting equipment thereof - Google Patents

Abstract

The utility model discloses a two-sided sand planting structure and two-sided sand planting equipment for net cloth plants sand belongs to the two-sided sand planting equipment technical field that plants sand of disposable realization net cloth. The utility model relates to a double-sided sand planting structure for grid cloth sand planting, which comprises a conveyer belt, a sand discharging device, an upper polar plate and a lower polar plate; wherein the upper polar plate is arranged above the lower polar plate; the grid cloth walking path is positioned between the upper polar plate and the lower polar plate; the sand discharging device is arranged above the grid cloth walking path and beside the upper polar plate, and the abrasive falling path penetrates through the grid cloth walking path; the conveyer belt is arranged between the grid cloth walking path and the lower polar plate. Adopt the utility model discloses the time, can once only make the both sides of net cloth all implant the abrasive material, make simultaneously also implant the abrasive material in the mesh of net cloth, it is higher to plant sand efficiency, and the cost is lower, and the product quality who makes is higher to have wear-resisting and sharp dual advantage.

Description

Double-sided sand planting structure for grid cloth sand planting and double-sided sand planting equipment thereof

Technical Field

The utility model relates to a two-sided sand planting structure and two-sided sand planting equipment for net cloth plants sand belongs to the two-sided sand planting equipment technical field that plants sand that can once only realize net cloth.

Background

The sand planting operation of the coated abrasive tool mainly adopts the modes of electrostatic sand planting and gravity sand planting at present.

The structural principle of electrostatic sand planting is shown in fig. 1 and fig. 2, an upper polar plate 3 is opposite to a lower polar plate 4, a conveying belt 1 moves between the upper polar plate 3 and the lower polar plate 4, a base material 9 runs between the upper polar plate 3 and the lower polar plate 4 through a guide roller 5, the base material 9 is positioned above the conveying belt 1, and a sand discharging device 2 is arranged above the conveying belt 1 and beside the base material 9; when the lower sand device 2 (a lower sand hopper) enables the abrasive 7 to fall onto the conveyer belt 1, and the conveyer belt 1 conveys the abrasive 7 between the upper pole plate 3 and the lower pole plate 4, the abrasive 7 moves upwards under the action of an electric field (the electric field is generated between the upper pole plate 3 and the lower pole plate 4), and the abrasive 7 rises to be attached to a base material 9 (glue is pre-attached to the base material 9) walking below the upper pole plate 3 to realize sand planting; the whole action process continuously and continuously runs to realize continuous sand planting on the base material. Fig. 1 shows reverse sand planting: the conveying direction of the grinding materials on the conveying belt is opposite to the traveling direction of the base material, and the reverse sand planting mode is widely adopted in the coated abrasive industry at present. FIG. 2 shows the same direction sand planting: the conveying direction of the grinding materials on the conveying belt is the same as the walking direction of the base material, and the same-direction sand planting mode is also partially adopted.

The structural principle of gravity sand planting is shown in figure 3: the base material 9 is formed with a certain inclination by the guide roller 5, the sand discharging device 2 is arranged above the base material 9 which runs obliquely, the grinding material 7 falls down by the sand discharging device 2, and the sand is planted by falling and attaching to the running base material 9 under the action of the self weight of the grinding material 7.

The product obtained by the gravity sand planting mode has the advantage of wear resistance, and the product obtained by the electrostatic sand planting mode has the advantage of sharpness. It can be seen that, no matter the sand planting mode of electrostatic sand planting or gravity sand planting, the sand planting operation can be performed on one surface of the base material only at one time, and the sand planting operation cannot be performed on the other surface of the base material, namely, the sand planting operation is performed on one surface, as shown in fig. 4; the prior art commonly used abrasive cloth, abrasive paper and the like are all made by planting sand on a single surface. Double-sided sand planting means that sand planting is performed on both sides of the base material. When sand planting is needed on two sides, the adopted method is also to plant sand on one side (primary sand planting) and then plant sand on the other side (secondary sand planting), the process is complicated and low in efficiency, and the sand planting effect of the primary sand planting is easy to destroy during the secondary sand planting.

Disclosure of Invention

The invention of the utility model aims to: to the problem that above-mentioned exists, a two-sided sand planting structure and two-sided sand planting equipment for net cloth plants sand is provided, the utility model discloses can once only realize the two-sided sand planting of net cloth.

The utility model adopts the technical scheme as follows:

a double-sided sand planting structure for grid cloth sand planting comprises a conveying belt, a sand discharging device, an upper polar plate and a lower polar plate; wherein the upper polar plate is arranged above the lower polar plate and used for generating an electric field which enables the grinding materials to move upwards; the grid cloth walking path is positioned between the upper polar plate and the lower polar plate and is a path for the grid cloth to walk when sand is planted; the abrasive falling path passes through the grid cloth walking path, and is a path through which the abrasive falls from the abrasive falling device; the conveying belt is arranged between the grid cloth walking path and the lower polar plate and used for conveying the grinding materials falling from the sand falling device and passing through the grid cloth walking path to the position between the upper polar plate and the lower polar plate.

The utility model discloses a two-sided sand planting structure possesses static simultaneously and plants the characteristics of sand and gravity planting sand, has gravity when planting sand and plants sand action and static and plant sand action, when adopting the two-sided sand planting structure of utility model to plant sand operation to net cloth, its principle is: the grid cloth attached with the glue water walks between the upper polar plate and the conveyer belt along the grid cloth walking path, the grinding materials fall down from the sand falling device and then move downwards along the grinding material falling path, and under the action of the self weight of the grinding materials, a part of the grinding materials fall down and are attached to the upper side surface of the walking grid cloth, so that the sand planting action (gravity sand planting action) of the upper side surface of the grid cloth is realized; because the grid cloth is provided with the meshes, the other part of the grinding materials continuously fall onto the conveying belt through the meshes of the grid cloth, and when the conveying belt conveys the grinding materials to a position between the upper polar plate and the lower polar plate, the grinding materials move upwards under the action of an electric field and rise to be attached to the lower side surface of the walking grid cloth, so that the sand planting action (electrostatic sand planting action) of the lower side surface of the grid cloth is realized; in the whole sand planting process, when the grinding materials pass through the meshes of the grid cloth or move upwards under the action of an electric field, the grinding materials can be attached to the meshes of the grid cloth. And the redundant abrasive materials which are not implanted into the grid cloth are transported away by the conveyer belt and recycled. Namely, the double-sided sand planting structure of the utility model can implant abrasive materials on both sides of the grid cloth at one time, and implant abrasive materials in the meshes of the grid cloth, thereby having higher sand planting efficiency and lower cost; the utility model discloses possess the static simultaneously and plant the characteristics of sand and gravity planting sand, consequently the product that makes has wear-resisting and sharp dual advantage.

Further, the conveying surface of the conveying belt is positioned between the upper polar plate and the lower polar plate. The conveying surface of the conveyor belt is used for conveying the abrasive.

Optionally, the sand discharging device is positioned on the left side or the right side of the upper polar plate.

A two-sided sand planting equipment for net cloth sand planting comprises the two-sided sand planting structure.

A double-sided sand planting structure for grid cloth sand planting comprises a sand discharging device, an upper polar plate and a lower polar plate; wherein: the upper polar plate is arranged above the lower polar plate and used for generating an electric field which enables the grinding materials to move upwards; the grid cloth walking path is positioned between the upper polar plate and the lower polar plate and is a path for the grid cloth to walk when sand is planted; the upper polar plate is provided with an abrasive passage through which the abrasive can pass; the sand discharging device is arranged above the upper polar plate, the abrasive material falling path sequentially passes through the abrasive material passage and the grid cloth walking path, and the abrasive material falling path is a path through which the abrasive material falls from the sand discharging device.

The utility model discloses a two-sided sand planting structure possesses static simultaneously and plants the characteristics of sand and gravity planting sand, has gravity when planting sand and plants sand action and static and plant sand action, when adopting the two-sided sand planting structure of utility model to plant sand operation to net cloth, its principle is: the grid cloth attached with the glue water walks between the upper polar plate and the conveyer belt along the grid cloth walking path, the grinding materials fall down from the sand falling device and move downwards along the grinding material falling path, and under the action of the self weight of the grinding materials, the grinding materials pass through a grinding material passageway of the upper polar plate, and then a part of the grinding materials fall down and are attached to the upper side surface of the walking grid cloth, so that the sand planting action (gravity sand planting action) of the upper side surface of the grid cloth is realized; because the grid cloth is provided with the meshes, the other part of the grinding material passes through the meshes of the grid cloth and falls between the upper polar plate and the lower polar plate, and meanwhile, the grinding material moves upwards under the action of the electric field and rises to be attached to the lower side surface of the walking grid cloth, so that the sand planting action (electrostatic sand planting action) of the lower side surface of the grid cloth is realized; in the whole sand planting process, when the grinding materials pass through the meshes of the grid cloth or move upwards under the action of an electric field, the grinding materials can be attached to the meshes of the grid cloth. Namely, the double-sided sand planting structure of the utility model can implant abrasive materials on both sides of the grid cloth at one time, and implant abrasive materials in the meshes of the grid cloth, thereby having higher sand planting efficiency and lower cost; the utility model discloses possess the static simultaneously and plant the characteristics of sand and gravity planting sand, consequently the product that makes has wear-resisting and sharp dual advantage.

Optionally, the upper polar plate is a grid plate, and grid holes of the grid plate are the abrasive passage; or the upper polar plate is a lattice plate, and lattice holes of the lattice plate are the grinding material passages; or the upper polar plate is provided with a through hole, and the through hole of the upper polar plate is the grinding material passageway.

Optionally, a base plate is laid on the top surface of the lower polar plate. The abrasive can be prevented from contacting the lower plate.

Optionally, the grid cloth conveying device further comprises a conveying belt, and the conveying belt is arranged between the grid cloth traveling path and the lower polar plate. The abrasive can be prevented from contacting the lower polar plate, and meanwhile, the redundant abrasive which is not implanted into the grid cloth can be transported away and recycled.

Further, the conveying surface of the conveying belt is positioned between the upper polar plate and the lower polar plate. The conveying surface of the conveyor belt is used for conveying the abrasive.

A two-sided sand planting equipment for net cloth sand planting comprises the two-sided sand planting structure.

To sum up, owing to adopted above-mentioned technical scheme, the beneficial effects of the utility model are that:

the utility model discloses a two-sided sand planting structure and two-sided sand planting equipment for net cloth plants sand possesses static simultaneously and plants sand and gravity and plant the characteristics of sand, can once only make the both sides of net cloth all implant the abrasive material, make simultaneously also implant the abrasive material in the mesh of net cloth, plant sand efficiency higher, the cost is lower, and the product quality of making is higher to have wear-resisting and sharp dual advantage.

Drawings

FIG. 1 is a structural schematic diagram of electrostatic sand-planting of reverse sand-planting in the background art;

FIG. 2 is a structural schematic diagram of electrostatic sand-planting of the same-direction sand-planting of the background art;

FIG. 3 is a structural schematic diagram of a gravity sand-planting in the background art;

FIG. 4 is a side view of a single-sided sand-planted product formed by electrostatic sand-planting or gravity sand-planting in the background art;

FIG. 5 is a schematic view of a double-sided sand-planting structure according to the first embodiment; the sand discharging device is positioned on the left side of the upper polar plate and used for reversely planting sand;

FIG. 6 is a schematic view of a double-sided sand-planting structure according to the first embodiment; the sand discharging device is positioned on the right side of the upper polar plate and is used for planting sand in the same direction;

FIG. 7 is a schematic view of a double-sided sand-planting structure according to a third embodiment; wherein, the double-sided sand planting structure does not comprise a backing plate and a conveying belt;

FIG. 8 is a schematic view of a double-sided sand-planting structure according to a third embodiment; wherein, the double-sided sand planting structure comprises a backing plate;

FIG. 9 is a schematic view of a double-sided sand-planting structure according to a third embodiment; wherein, the double-sided sand planting structure comprises a conveying belt;

FIG. 10 is a schematic structural diagram of 3 upper plates; wherein, fig. 10a shows that the upper polar plate is a grid plate, fig. 10b shows that the upper polar plate is a bar grid plate, and fig. 10c shows that the upper polar plate is provided with through holes.

Fig. 11 is a side view of a formed product incorporating the present invention;

fig. 12 is a top view of a formed product incorporating the present invention.

The labels in the figure are: 1-conveying belt, 2-sand discharging device, 3-upper polar plate, 4-lower polar plate, 5-guide roller, 6-grid cloth, 6 '-grid cloth traveling path, 7-grinding material, 7' -grinding material falling path, 8-backing plate and 9-base material.

Detailed Description

The present invention will be described in detail with reference to the accompanying drawings.

In order to make the objects, technical solutions and advantages of the present invention more clearly understood, the present invention is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

In the present invention, as shown in fig. 5 to 9, the mesh cloth traveling path 6' refers to a path along which the mesh cloth 6 travels when the sand planting work is performed; the grid cloth 6 can run between the upper and lower polar plates along the grid cloth running path 6' by the guiding action of the 2 guide rollers 5, and the lower sand device 2 (such as a lower sand hopper) is positioned between the two guide rollers 5, so that the lower sand device 2 is positioned above the grid cloth 6. In the conventional electrostatic sand planting apparatus, as shown in fig. 1 and 2, the mesh cloth 6 can travel between the upper plate and the lower plate, and the guide roller 5 of the conventional electrostatic sand planting apparatus mainly plays a role of guiding. Therefore, the utility model discloses in, how make net cloth 6 walk path 6 'along net cloth and walk between last polar plate and bottom plate to do not have a technical problem, refer to prior art means can, the technical problem of solution be how once only realize the two-sided sand planting of net cloth, consequently, net cloth 6's walking adopt prior art means can, the utility model discloses just no longer give unnecessary details.

Example one

As shown in fig. 5 and 6, the double-sided sand-planting structure for grid cloth sand-planting according to the embodiment includes a conveyer belt 1, a sand-planting device 2, an upper polar plate 3, and a lower polar plate 4; wherein the upper polar plate 3 is arranged above the lower polar plate 4 and used for generating an electric field which enables the grinding materials to move upwards; the grid cloth walking path 6 'is positioned between the upper polar plate 3 and the lower polar plate 4, and the grid cloth walking path 6' is a path where the grid cloth 6 walks during sand planting; the sand discharging device 2 is arranged above the grid cloth walking path 6 'and beside the upper polar plate 3, and the abrasive falling path 7' passes through the grid cloth walking path 6', and the abrasive falling path 7' is a path through which the abrasive falls from the sand discharging device 2; the conveyor belt 1 is disposed between the mesh cloth traveling path 6 'and the lower plate 4, for conveying the abrasive dropped from the lower sand device 2 and passing through the mesh cloth traveling path 6' to between the upper plate 3 and the lower plate 4.

The utility model discloses a two-sided sand planting structure possesses static simultaneously and plants the characteristics of sand and gravity planting sand, has gravity when planting sand and plants sand action and static and plant sand action, when adopting the two-sided sand planting structure of utility model to plant sand operation to net cloth, its principle is: the gridding cloth 6 adhered with the glue water is made to walk between the upper polar plate 3 and the conveyer belt 1 along a gridding cloth walking path 6', the grinding material 7 moves downwards along a grinding material falling path 7' after falling from the sand falling device 2, under the action of the self weight of the grinding material 7, a part of the grinding material falls and is adhered to the upper side surface of the walking gridding cloth 6, and the sand planting action (gravity sand planting action) of the upper side surface of the gridding cloth 6 is realized; because the grid cloth 6 has the meshes 61, the other part of the abrasive 7 passes through the meshes of the grid cloth 6 and continuously falls onto the conveyer belt 1, when the conveyer belt 1 conveys the abrasive 7 between the upper polar plate 3 and the lower polar plate 4, the abrasive 7 moves upwards under the action of the electric field and rises to be attached to the lower side surface of the traveling grid cloth 6, and the sand planting action (electrostatic sand planting action) of the lower side surface of the grid cloth 6 is realized; during the whole sand planting action, when the grinding material passes through the meshes of the mesh cloth 6 or the grinding material 7 moves upwards under the action of an electric field, the grinding material 7 can be attached in the meshes 61 of the mesh cloth. And the redundant abrasive which is not implanted into the mesh cloth 6 is transported away by the conveyer belt 1 and recycled. Namely, with the double-sided sand planting structure of the present invention, as shown in fig. 11 and 12, the abrasive material can be implanted into both sides of the mesh cloth 6 at one time, and simultaneously, the abrasive material is also implanted into the meshes 61 of the mesh cloth 6, so that the sand planting efficiency is higher, and the cost is lower; the utility model discloses possess the static simultaneously and plant the characteristics of sand and gravity planting sand, consequently the product that makes has wear-resisting and sharp dual advantage.

Further, as shown in fig. 5 and 6, the conveying surface of the conveying belt 1 is located between the upper plate 3 and the lower plate 4. The conveying surface of the conveyor belt 1 is used for conveying abrasive. Preferably, the lower polar plate 4 is close to the back of the conveying surface of the conveying belt 1.

Alternatively, as shown in fig. 5, the sand discharging device 2 is positioned at the left side of the upper polar plate 3. At this time, the sand discharging device 2 is positioned between the guide roller 5 on the left side and the upper polar plate 3, so that the conveyer belt 1 conveys the grinding materials to the right, and the guide roller 5 guides the mesh cloth 6 which travels to the left, thereby realizing the reverse sand planting action. Of course, the abrasive may be conveyed to the right by the conveyor belt 1, and the guide roller 5 may guide the mesh cloth 6 traveling to the right, thereby realizing the equidirectional sand planting operation.

Alternatively, as shown in fig. 6, the sand discharging device 2 is positioned at the right side of the upper polar plate 3. At this time, the sand discharging device 2 is positioned between the guide roller 5 on the right side and the upper polar plate 3, so that the conveyer belt 1 conveys the grinding materials to the left, and the guide roller 5 guides the grid cloth 6 which travels to the left, thereby realizing the equidirectional sand planting action. Of course, the abrasive may be conveyed to the left by the conveyor belt 1, and the grid cloth 6 traveling to the right may be guided by the guide roller 5, thereby realizing the reverse sand-planting operation.

Example two

The second double-sided sand planting device for grid cloth sand planting comprises the first double-sided sand planting structure.

EXAMPLE III

The double-sided sand planting structure for grid cloth sand planting of the third embodiment comprises a sand discharging device 2, an upper polar plate 3 and a lower polar plate 4; wherein: an upper polar plate 3 is arranged above the lower polar plate 4 and used for generating an electric field which enables the grinding materials to move upwards; the grid cloth walking path 6 'is positioned between the upper polar plate 3 and the lower polar plate 4, and the grid cloth walking path 6' is a path where the grid cloth 6 walks during sand planting; the upper plate 3 has an abrasive passage through which an abrasive can pass; the sand discharging device 2 is arranged above the upper pole plate 3, the abrasive falling path 7' sequentially passes through the abrasive passage and the gridding cloth walking path 6', and the abrasive falling path 7' is a path through which the abrasive falls from the sand discharging device 2.

The utility model discloses a two-sided sand planting structure possesses static simultaneously and plants the characteristics of sand and gravity planting sand, has gravity when planting sand and plants sand action and static and plant sand action, when adopting the two-sided sand planting structure of utility model to plant sand operation to net cloth, its principle is: enabling the gridding cloth 6 attached with the glue to travel along a gridding cloth traveling path 6'; walking between the upper polar plate 3 and the conveyer belt 1, the grinding material 7 moves downwards along the grinding material falling path 7' after falling from the sand falling device 2, under the action of the self weight of the grinding material 7, after the grinding material 7 passes through a grinding material passageway of the upper polar plate 3, a part of the grinding material falls and is attached to the upper side surface of the walking grid cloth 6, and the sand planting action (gravity sand planting action) of the upper side surface of the grid cloth 6 is realized; because the grid cloth 6 is provided with the meshes 61, the other part of the abrasive 7 passes through the meshes of the grid cloth 6 and falls between the upper polar plate 3 and the lower polar plate 4, and meanwhile, the abrasive 7 moves upwards under the action of the electric field and rises to be attached to the lower side surface of the walking grid cloth 6, so that the sand planting action (electrostatic sand planting action) of the lower side surface of the grid cloth 6 is realized; during the whole sand planting action, when the grinding material passes through the meshes of the mesh cloth 6 or the grinding material 7 moves upwards under the action of an electric field, the grinding material 7 can be attached in the meshes 61 of the mesh cloth. Namely, with the double-sided sand planting structure of the present invention, as shown in fig. 11 and 12, the abrasive material can be planted on both sides of the mesh cloth 6 at one time, and simultaneously, the abrasive material is also planted in the mesh holes of the mesh cloth 6, so that the sand planting efficiency is higher, and the cost is lower; the utility model discloses possess the static simultaneously and plant the characteristics of sand and gravity planting sand, consequently the product that makes has wear-resisting and sharp dual advantage.

Alternatively, as shown in fig. 10a, the upper plate 3 is a grid plate, and the grid holes 31 of the grid plate are the abrasive passages. The lattice holes 31 may be in the shape of a circle, an ellipse, a square, a rectangle, a parallelogram, or the like, as long as they pass through the abrasive 7.

Alternatively, as shown in fig. 10b, the upper plate 3 is a lattice plate, and the lattice holes 32 of the lattice plate are the abrasive passage. The lattice holes 32 may be in the shape of a kidney-shaped hole, an oval, a rectangle, or the like, as long as they pass through the abrasive 7.

Optionally, as shown in fig. 10c, a through hole 33 is formed on the upper plate 3, and the through hole 33 of the upper plate 3 is the abrasive passage. The through-hole 33 may be circular, oval, square, rectangular, or parallelogram, etc., as long as it can pass through the abrasive 7.

The present embodiment discloses the structural forms of the above-mentioned 3 kinds of upper electrode plates 3, which can achieve the purpose that the grinding material 7 passes through the upper electrode plates 3. Of course, the upper plate 3 may have other structures, as long as the grinding material passage of the upper plate 3 can pass through the grinding material 7, which is within the protection scope of the present invention.

Alternatively, as shown in fig. 8, a backing plate 8 is laid on the top surface of the lower plate 4. In order to implant the abrasive 7 on the grid cloth 6, glue is pre-attached to the grid cloth 6, after the abrasive 7 passes through the meshes of the grid cloth 6, the adhesive is possibly attached to the abrasive 7, and after the abrasive 7 contacts the lower pole plate 4, the abrasive 7 is possibly adhered to the lower pole plate 4, so that the upper abrasive is gradually accumulated on the lower pole plate 4. Therefore, the utility model provides a lay the design of backing plate 8 at the top surface of lower polar plate 4, after piling up the abrasive material of certain quantity on the backing plate, can take off backing plate 8 and change or the sanitization.

Alternatively, as shown in fig. 9, a conveyer belt 1 is further included, and the conveyer belt 1 is arranged between the grid cloth walking path 6' and the lower polar plate 4. The abrasive 7 can be prevented from contacting the lower pole plate 4, and meanwhile, the redundant abrasive which is not implanted into the grid cloth 6 can be transported away and recycled.

Further, as shown in fig. 9, the conveying surface of the conveying belt 1 is located between the upper plate 3 and the lower plate 4. The conveying surface of the conveyor belt 1 is used for conveying abrasive. Preferably, the lower polar plate 4 is close to the back of the conveying surface of the conveying belt 1.

Example four

The sand planting equipment for the grid cloth comprises a sand planting structure for the third embodiment.

EXAMPLE five

In the double-sided sand planting method for grid cloth sand planting according to the fifth embodiment, the grid cloth 6 attached with the glue is made to travel through the electric field, and the grinding material 7 is made to fall onto the traveling grid cloth 6; at this time, a part of the abrasive falls down to be attached to the upper side of the mesh cloth 6, and the other part of the abrasive continues to fall after passing through the meshes 61 of the mesh cloth 6; the abrasive 7 falling through the mesh cloth enters the electric field, and under the action of the electric field, the abrasive 7 rises to be attached to the lower side surface of the mesh cloth 6, so that the abrasive 7 is implanted into both surfaces of the mesh cloth 6 at one time.

Adopt the utility model discloses a two-sided sand planting method is when planting the sand operation to net cloth, and is obvious, and the electric power field is the electric power field that can make the abrasive material upward movement. When the grinding materials fall and are attached to the upper side surface of the grid cloth 6, the gravity sand planting is performed on the upper side surface of the grid cloth 6; when abrasive 7 rises and attaches to the downside of net cloth 6, carried out static planting sand to the downside of net cloth 6 in other words in the two-sided sand planting method of the utility model, when the abrasive passed the mesh of net cloth 6, perhaps when abrasive 7 upwards moved under the effect in electric power field, can also make abrasive 7 attach to in the mesh 61 of net cloth. Namely, the double-sided sand planting method of the utility model can implant abrasive materials into both sides of the grid cloth 6 at one time, and implant abrasive materials into the meshes 61 of the grid cloth 6, so that the sand planting efficiency is higher and the cost is lower; the utility model discloses possess the static simultaneously and plant the characteristics of sand and gravity planting sand, consequently the product that makes has wear-resisting and sharp dual advantage. The double-sided sand planting method of the fifth embodiment can be realized by adopting the double-sided sand planting device of the second or fourth embodiment.

EXAMPLE six

Based on the design of the fifth embodiment, in the double-sided sand-planting method of the sixth embodiment, the abrasive 7 falling through the mesh cloth is conveyed to the electric power field by a conveying device (e.g., the conveyor belt 1). The double-sided sand planting method of the sixth embodiment can be realized by adopting the double-sided sand planting device of the second embodiment.

EXAMPLE seven

Based on the design of the fifth embodiment, in the double-sided sand planting method of the seventh embodiment, the abrasive 7 falling through the mesh cloth falls directly into the electric field. The double-sided sand planting method of the seventh embodiment can be realized by adopting the double-sided sand planting device of the fourth embodiment.

To sum up, adopt the utility model discloses a two-sided sand planting structure and two-sided sand planting equipment for net cloth plants sand possesses static simultaneously and plants sand and gravity and plant the characteristics of sand, can once only make the both sides of net cloth all implant the abrasive material, make simultaneously also implant the abrasive material in the mesh of net cloth, plant sand efficiency higher, the cost is lower, and the product quality of making is higher to have wear-resisting and sharp dual advantage.

The above description is only exemplary of the present invention and should not be taken as limiting the scope of the present invention, as any modifications, equivalents, improvements and the like made within the spirit and principles of the present invention are intended to be included within the scope of the present invention.

Claims (10)

1. The utility model provides a two-sided sand planting structure for net cloth plants sand which characterized in that: comprises a conveyer belt (1), a sand discharging device (2), an upper polar plate (3) and a lower polar plate (4); wherein the content of the first and second substances,

the upper polar plate (3) is arranged above the lower polar plate (4) and used for generating an electric power field which enables the grinding materials to move upwards;

the grid cloth walking path (6') is positioned between the upper polar plate (3) and the lower polar plate (4), and the grid cloth walking path (6') is a path where the grid cloth (6) walks during sand planting;

the sand discharging device (2) is arranged above the grid cloth walking path (6') and beside the upper polar plate (3), the abrasive falling path (7') penetrates through the grid cloth walking path (6'), and the abrasive falling path (7') is a path through which the abrasive falls from the sand discharging device (2);

the conveying belt (1) is arranged between the grid cloth walking path (6') and the lower polar plate (4) and is used for conveying the grinding materials falling from the sand falling device (2) and passing through the grid cloth walking path (6') to the position between the upper polar plate (3) and the lower polar plate (4).

2. The double-sided sand-planting structure of claim 1, wherein: the conveying surface of the conveying belt (1) is positioned between the upper polar plate (3) and the lower polar plate (4).

3. The double-sided sand-planting structure of claim 1, wherein: the sand discharging device (2) is positioned on the left side or the right side of the upper polar plate (3).

4. The utility model provides a two-sided sand planting equipment for net cloth is planted sand which characterized in that: comprises the double-sided sand-planting structure as claimed in any one of claims 1 to 3.

5. The utility model provides a two-sided sand planting structure for net cloth plants sand which characterized in that: comprises a sand discharging device (2), an upper polar plate (3) and a lower polar plate (4); wherein:

the upper polar plate (3) is arranged above the lower polar plate (4) and used for generating an electric power field which enables the grinding materials to move upwards;

the grid cloth walking path (6') is positioned between the upper polar plate (3) and the lower polar plate (4), and the grid cloth walking path (6') is a path where the grid cloth (6) walks during sand planting;

the upper polar plate (3) is provided with an abrasive passage through which an abrasive can pass;

the sand discharging device (2) is arranged above the upper polar plate (3), the abrasive falling path (7') sequentially passes through the abrasive passage and the grid cloth walking path (6'), and the abrasive falling path (7') is a path through which the abrasive falls from the sand discharging device (2).

6. The double-sided sand-planting structure of claim 5, wherein:

the upper polar plate (3) is a grid plate, and grid holes of the grid plate are the abrasive passage; alternatively, the first and second electrodes may be,

the upper polar plate (3) is a lattice plate, and lattice holes of the lattice plate are the grinding material passage; alternatively, the first and second electrodes may be,

the upper polar plate (3) is provided with a through hole, and the through hole of the upper polar plate (3) is the grinding material passageway.

7. The double-sided sand-planting structure of claim 5, wherein: and a base plate (8) is laid on the top surface of the lower polar plate (4).

8. The double-sided sand-planting structure of claim 5, wherein: the grid cloth conveying device further comprises a conveying belt (1), and the conveying belt (1) is arranged between the grid cloth walking path (6') and the lower pole plate (4).

9. The double-sided sand-planting structure of claim 8, wherein: the conveying surface of the conveying belt (1) is positioned between the upper polar plate (3) and the lower polar plate (4).

10. The utility model provides a two-sided sand planting equipment for net cloth is planted sand which characterized in that: comprises the double-sided sand-planting structure as claimed in any one of claims 5 to 9.

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