JP5734891B2 - Blasting equipment - Google Patents

Description

  The present invention relates to a blasting apparatus for blasting an object by causing a blast material ejected from a blast nozzle to collide with the object.

  Blasting is known as a surface treatment for rust removal of metal products, surface processing of glass products, and the like. The blast treatment is a method in which a sand-like blast material is sprayed at high speed toward the object with compressed air or the like, and the object is surface-treated. For example, Patent Document 1 below describes that a guardrail as a target is blasted and then re-made by thermal spraying and painting. Since rust and the like firmly adhered to the surface of the guardrail can be removed by the blasting process, the subsequent thermal spraying process and coating can be performed satisfactorily.

JP 2009-27597A

  In the blasting process of Patent Document 1, the blast material is projected from a blast nozzle. There is a limit to the projection range of the blast material from the blast nozzle, and the number of necessary blast nozzles increases as the vertical width of the guard rail increases. FIG. 3 of Patent Document 1 shows an example in which four blast nozzles are used. When the number of blast nozzles increases, the apparatus becomes complicated and it takes time to adjust the angle of each blast nozzle.

  The present invention solves the conventional problems as described above, and provides a blasting device that widens the blasting range while suppressing the number of blast nozzles by extending the projection range of the blasting material to be elongated. The purpose is to do.

  In order to achieve the above object, a blasting apparatus according to the present invention is a blasting apparatus for causing a blasting material to collide with an object, the blasting nozzle for ejecting the blasting material, and the blasting material ejected from the blasting nozzle The projection unit is formed between a pair of wall surfaces and narrows the projection width of the blast material, and the projection range of the blast material is enlarged with a narrow formation range. A projection port is formed.

  According to this configuration, the blast material ejected from the blast nozzle collides with the object through the projection unit. Since the projection unit is formed with a projection space for narrowing the projection width of the blast material and a projection port for enlarging the projection length of the blast material, the projection range of the blast material is elongated. As a result, the length of the blast process per blast nozzle is increased, and the range of the blast process is widened while suppressing the number of blast nozzles.

  Further, even when the blast material from the blast nozzle is directly projected onto the object, a certain space is required in front of the blast nozzle in order to ensure the projection range. When a plurality of blast nozzles are arranged in the vertical direction, a certain space is required in the vertical direction. The projection unit can be arranged in a portion corresponding to this fixed space, and it is not necessary to provide a special space for arranging the projection unit. Furthermore, since the formation range of the projection opening of the projection unit is elongated, the width of the projection unit can be kept small. That is, even if a projection unit is provided, an increase in the size of the blasting device can be suppressed.

  The blasting apparatus of the present invention may have various configurations listed below. It is preferable that the formation range of the jet port of the blast nozzle is elongated, and the length of the formation range of the projection port is longer than the length of the formation range of the jet port. According to this structure, since the ejection range of the blast material from the blast nozzle is elongated, and this ejection range is further elongated by the projection unit, it is more advantageous to expand the projection range of the blast material to be elongated. Become.

  The projection unit is preferably formed with the plate-like members facing each other. According to this configuration, since the projection space and the projection opening of the projection unit can be formed by combining the plate-like members, the creation of the projection unit is facilitated.

  It is preferable that there are a plurality of the blast nozzles and the projection ports, and each of the blast nozzles is disposed so as to correspond to a separate projection port. According to this configuration, the projection range can be shared by the plurality of blast nozzles, and the projection range of the blast material can be expanded more slenderly.

  A plurality of blast nozzles having different ejection directions of the blast material may cause an overlapping range to be projected onto the object. According to this configuration, in the ejection direction for one blast nozzle, even when a part of the projection object is substantially parallel to the ejection direction, by including the substantially parallel part in the overlapping range, Blasting can be performed well over the entire projection object.

  It is preferable that the opening width of the projection port is adjustable. According to this structure, it becomes possible to adjust the projection width of a blast material according to a target object.

  It is preferable that the arrangement of the blast nozzle can be adjusted as a single unit. According to this configuration, the projection range can be adjusted by adjusting the arrangement of the blast nozzle while maintaining the fixed state of the projection unit, and the projection range can be easily adjusted.

  It is preferable that the formation range of the ejection port of the blast nozzle is elongated, and the width of the ejection port is changed so that the central portion is narrowed. According to this configuration, the density of the blast material in the longitudinal direction of the jet port can be made uniform. As a result, the degree of collision of the blast material on the object can be made uniform.

  In the projection unit, it is preferable that the projection space is partitioned by a partition member so that a projection range of the blast material from the projection port is limited. According to this structure, it can prevent that a blast material collides with an unnecessary part, and can also raise the concentration degree of the blast material on a target object collectively. Furthermore, the projection range can be adjusted by adjusting the position of the partition member.

  It is preferable that the object is a guard rail, and the object side of the projection unit is uneven so as to match the uneven shape of the guard rail. According to this structure, it becomes easy to move a blasting apparatus along the longitudinal direction of a guardrail, and the blasting process in the longitudinal direction of a guardrail becomes easy.

  According to the present invention, since the projection unit is provided, the projection range of the blast material is elongated. As a result, the length of the blast process per blast nozzle is increased, and the range of the blast process is widened while suppressing the number of blast nozzles.

  Moreover, it is not necessary to provide a special space for arranging the projection units. Furthermore, since the formation range of the projection opening of the projection unit is elongated, the width of the projection unit can be kept small. Thereby, even if it has a projection unit, the enlargement of a blasting device can be suppressed.

The perspective view which shows the state which is carrying out the blasting process using the blasting apparatus which concerns on one Embodiment of this invention. The perspective view which shows the principal part of the front side of the blasting apparatus which concerns on one Embodiment of this invention. The perspective view which shows the principal part of the back side of the blasting apparatus which concerns on one Embodiment of this invention. Sectional drawing in the AA line of FIG. (A) A figure is a perspective view of a blast nozzle concerning one embodiment of the present invention, and (b) figure is a perspective view showing another example of a spout. The side view which shows the state which attached the blasting apparatus which concerns on one Embodiment of this invention to the guardrail. The longitudinal cross-sectional view in the position of the lower blast nozzle in the blasting apparatus shown in FIG. The longitudinal cross-sectional view in the position of the upper blast nozzle in the blasting apparatus shown in FIG. The comparison figure which showed typically the projection range of the blast material on a target object. Sectional drawing which shows the example which added the partition member to the projection unit in one Embodiment of this invention. Sectional drawing explaining adjustment of the projection width | variety of a projection unit in one Embodiment of this invention.

  Hereinafter, an embodiment of the present invention will be described with reference to the drawings. FIG. 1 is a perspective view showing a state in which blasting is performed using a blasting apparatus according to an embodiment of the present invention. In this figure, the blasting process 1 is used to blast the guardrail 2 as an object. The blast device 1 is attached to a guard rail 2. The blasting process is performed while moving the blasting device 1 along the longitudinal direction of the guard rail 2. Although details will be described later, the blast material projected from the blasting device 1 collides with the surface of the guard rail 2, and rust, dirt, and paint adhered to the surface of the guard rail 2 are removed. An abrasive such as sand is used for the blast material.

  The vehicle 3 is equipped with a dust collecting device 4 and a blasting device 5. A blast material is supplied from the blast device 5 to the blast device 1 through the blast supply hose 6 and the blast supply hose 7. The blast material projected on the guard rail 2 is recovered by the blast device 5 via the blast recovery hose 8. Rust, dirt, and paint removed from the guardrail 2 by the blasting process are collected by the dust collecting device 4 through the dust collecting hose 9.

  FIG. 2 is a perspective view showing a main part on the front side of the blasting apparatus 1. FIG. 3 is a perspective view showing a main part on the back side of the blasting apparatus 1. FIG. 2 shows the side on which the blast material is projected, and shows the side facing the guard rail 2 of FIG. FIG. 3 shows the side on which the blast material is supplied. In FIG. 3, the back cover is not shown to show the internal state. As shown in FIGS. 2 and 3, the projection unit 11 is accommodated in the case 10. The projection unit 11 includes three projection plates 12 to 14. The dust collection hose 9 shown in FIG. 1 is connected to the connection port 19.

  In FIG. 2, guide plates 20 and guide plates 21 are arranged on both sides of the projection unit 11. Side plates 22 and 23 are disposed on both side surfaces of the case 10. During the blasting process, the blasting device 1 is moved along the guard rail 2. In this moving state, the front end sides of the projection unit 11, the guide plate 20, the guide plate 21, the side plate 22, and the side plate 23 face the guard rail 2.

  As shown in FIG. 2, unevenness is formed on the tip side of each plate-like member such as the projection plates 12 to 14 facing the guard rail 2. These irregularities are formed in accordance with the irregular shape of the guard rail 2. According to this structure, it becomes easy to move the blasting device 1 along the longitudinal direction of the guard rail 2, and the blasting process in the longitudinal direction of the guard rail 2 is facilitated.

  A soft sealing material 25 is attached to the side plate 22 and the side plate 23. As shown in FIG. 1, the sealing material 25 contacts the guard rail 2. This prevents the removal material and the blast material from the guard rail 2 from flowing out of the case 10 during the blasting process.

  In FIG. 3, a blast nozzle 30 is attached to the upper part of the projection unit 11, and a blast nozzle 31 is attached to the lower part of the projection unit 11. The tip side of the blast nozzle 30 is sandwiched between the projection plate 13 and the projection plate 14. The tip end side of the blast nozzle 31 is sandwiched between the projection plate 12 and the projection plate 13. A blast material is ejected from the blast nozzle 30 and the blast nozzle 31, and the blast material is projected onto the guard rail 2 through the projection unit 11.

  4 is a cross-sectional view taken along line AA in FIG. In this section, the blast nozzle 30 does not appear, but the blast nozzle 30 is shown for convenience of explanation. As shown in FIG. 4, a projection space 15 is formed between the projection plate 12 and the projection plate 13. A projection space 16 is formed between the projection plate 13 and the projection plate 14. A blast nozzle 31 is disposed at one end of the projection space 15, and a projection port 17 is formed at the other end. A blast nozzle 30 is disposed at one end of the projection space 16, and a projection port 18 is formed at the other end.

  An arrow “a” in FIG. 4 indicates the projection direction of the blast material 40 from the projection unit 11. The blast material 40 ejected from the blast nozzle 30 is projected from the projection port 18 through the projection space 16. Similarly, the blast material 40 ejected from the blast nozzle 31 is projected from the projection port 17 through the projection space 15.

  FIG. 5A shows a perspective view of the blast nozzle 30 shown in FIG. The blast nozzle 31 has the same configuration. The blast nozzle 30 includes a main body portion 32 and an attachment portion 33. The main body 32 is connected to the blast supply hose 7. A mounting hole 34 is formed in the mounting portion 33. The main body portion 32 is hollow, and the blast material supplied from the blast supply hose 7 is ejected from an ejection port 35 formed at the tip of the main body portion 32.

  FIG. 5B is a perspective view showing another example of the ejection port 35. The spout 35 changes the width of the spout 35 so that the center part becomes narrow. When the spout 35 is elongated, the density of the blast material at the spout 35 is greater at the center than at the end. The density of the blasting material in the longitudinal direction of the jet port 35 can be made uniform by changing the width of the jet port 35 so that the center part becomes narrow like the jet port 35 of FIG. As a result, the degree of collision of the blast material on the object can be made uniform.

  FIG. 6 is a side view showing a state in which the blast device 1 is attached to the guard rail 2. For convenience of illustration, the guard rail 2 is shown in a cross-sectional state. The guard rail 2 is attached to the support column 16 via a bracket 17. The blast device 1 is supported by the guard rail 2 by, for example, engaging a wheel (not shown) provided in the blast device 1 with the upper end portion of the guard rail 2. In this configuration, the blast device 1 can be moved along the guard rail 2 while rotating the wheel.

  7 and 8 show longitudinal sectional views of the blasting apparatus 1 shown in FIG. FIG. 7 is a longitudinal sectional view of the blast nozzle 30 disposed at the upper part of the projection unit 11. FIG. 8 is a vertical cross-sectional view at the position where the blast nozzle 31 is disposed below the projection unit 11. 7 and 8, the upper part of the blasting device 1 is a cross section of the attachment part of the dust recovery hose 9, and the lower part of the blasting apparatus 1 is a cross section of the attachment part of the blast recovery hose 8.

  As shown in FIG. 7, the projection unit 11 is disposed in the case 10. A blast nozzle 30 is disposed on the projection unit 11. In the example of the figure, the blast nozzle 30 is fixed in the case 10 by tightening a bolt (not shown) inserted through the mounting hole 34 to a support member (not shown) provided in the case 10. .

  A blast material 40 is ejected from the blast nozzle 30. The blast material 40 collides with the guard rail 2 through the projection unit 11. In this collision portion, the guard rail 2 is blasted. The blast nozzle 30 is disposed so that the blast material 40 is ejected obliquely downward. Accordingly, the blast material 40 collides with the range from the upper end of the guard rail 2 to the inclined surface 2b.

  Rust, dirt and paint are removed from the guardrail 2 by blasting. These removing materials are collected through the dust collecting hose 9. On the other hand, the blast material 40 after colliding with the guard rail 2 falls to the lower part of the case 10 and is collected through the blast collecting hose 8.

  FIG. 8 has the same configuration as that of FIG. 7 except that the blast nozzle 31 is disposed below the projection unit 11. The blast material 40 ejected from the blast nozzle 31 collides with the guard rail 2 through the projection unit 11. In this collision portion, the guard rail 2 is blasted. The blast nozzle 31 is arranged so that the blast material 40 is ejected obliquely upward. Thereby, the blast material 40 collides with the range from the lower end of the guardrail 2 to the inclined surface 2a.

  Therefore, in this embodiment, the entire blast nozzle 30 of FIG. 7 and the blast nozzle 31 of FIG. By moving the blasting device 1 along the longitudinal direction of the guard rail 2, the entire guard rail 2 within the moving range is blasted.

  Here, in FIG. 7, the ejection direction of the blast material 40 by the blast nozzle 30 is substantially parallel to the inclined surface 2 a of the guard rail 2. In this case, the effect of the blasting process on the inclined surface 2a is disadvantageous compared to other surfaces. On the other hand, as shown in FIG. 8, the blast material 40 from the blast nozzle 31 collides with the inclined surface 2a in a direction substantially perpendicular to the inclined surface 2a. In this case, the effect of the blasting process is improved, and the blasting process effect on the inclined surface 2a is prevented from being disadvantageous compared to other surfaces. Although the example of the inclined surface 2a has been described, the same applies to the inclined surface 2b.

  In the present embodiment, the blast nozzle 30 and the blast nozzle 31 are arranged so that the respective ejection directions are different and an overlapping range is generated in the projection range onto the object. And the inclined surface 2a and the inclined surface 2b are included in this overlapping range. According to this configuration, in the ejection direction of one blast nozzle, even when a part of the projection object (the inclined surface 2a and the inclined surface 2b in the present embodiment) is substantially parallel to the ejection direction, this substantially parallel. By including the part to be in the overlapping range, the blasting process is improved over the entire projection target.

  Since the blast device 1 includes the projection unit 11, the projection range of the blast material is elongated. This will be described with reference to FIG. FIG. 9 is a comparison diagram schematically showing the projection range of the blast material on the object. The projection range 41 and the projection range 42 in FIG. 9 show the blast material on the vertical flat plate when the blast material ejected from the injection port 35 (FIG. 5) of the blast nozzle 30 (31) collides with the vertical flat plate. The projection range is shown.

  The projection range 41 indicates a projection range when the blast material from the injection port 35 is directly projected onto the vertical flat plate without going through the projection unit 11. The projection range 42 indicates a projection range when the blast material from the ejection port 35 is projected onto the vertical flat plate via the projection unit 11. The projection range 42 is elongated compared to the projection range 41. More specifically, while the projection range 41 is substantially elliptical, the projection range 42 is substantially rectangular. The projection range 42 is narrower than the projection range 41, narrows in the horizontal direction, and expands in the vertical direction.

  As shown in FIG. 4, the projection range 42 is enlarged in an elongated manner, as shown in FIG. 2, the spread of the blasting material 40 that is ejected is limited to the width of the projection space 15 (projection space 16). This is because the formation range of the projection port 17 (projection port 18) when viewed from the object side is longer than the formation range of the injection port 35. As the projection range is elongated, the projection length becomes longer. Thereby, the range of the blast process per one of the blast nozzle 30 and the blast nozzle 31 becomes long.

  As shown in FIGS. 5A and 5B, when the formation range of the injection port 35 is elongated, the ejection range of the blast material from the ejection port 35 is elongated, and this ejection range is the projection unit 11. As a result, the image is further elongated. Therefore, by making the formation range of the injection port 35 elongated, it becomes more advantageous to enlarge the projection range of the blast material to be elongated.

  As described above, in this embodiment, the entire vertical width of the guard rail 2 is blasted by the two blast nozzles 30 and the blast nozzle 31. 7 and 8, when the projection unit 11 is not used, the projection length becomes short as shown by the projection range 41 in FIG. As a result, if there is a portion where the blast material does not collide in the vertical direction of the guard rail 2, three or more blast nozzles are required for blasting the entire vertical width of the guard rail 2. That is, the number of necessary blast nozzles can be reduced by blasting using the projection unit 11.

  Moreover, the projection unit 11 can be added, without enlarging the blast apparatus 1 specially as follows. 7 and 8, even when the projection unit 11 is not provided, a certain space is required in front of the blast nozzles 30 and 31 in order to ensure the projection range. Similarly, in order to share the projection range between the blast nozzle 30 and the blast nozzle 31, a certain space is required between the upper blast nozzle 30 and the lower blast nozzle 31.

  That is, even when the projection unit 11 is not provided, a certain space is required in front of the blast nozzles 30 and 31 and between the blast nozzle 30 and the blast nozzle 31. As shown in FIGS. 7 and 8, the projection unit 11 is arranged in a portion corresponding to this fixed space, and it is not necessary to provide a special space for the arrangement of the projection unit 11. Furthermore, since the formation range of the projection opening of the projection unit 11 is elongated, the width of the projection unit 11 can be kept small. For this reason, the projection unit 11 can be added without enlarging the blasting apparatus 1 specially.

  Furthermore, in this embodiment, the projection plates 12-14 which comprise the projection unit 11 are plate-shaped members. Therefore, as shown in FIGS. 2 to 4, if the projection plate 12 and the projection plate 13 are opposed to each other and the projection plate 13 and the projection plate 14 are opposed to each other, the projection spaces 15 and 16 and the projection port 17 are arranged. , 18 will be formed. For connection between the opposing projection plates, for example, a connecting means such as a bolt and a nut may be used. That is, the creation of the projection unit 11 does not require special processing or molding, and is easy to create.

  FIG. 10 is a cross-sectional view showing an example in which a partition member is added to the projection unit 11 in the present embodiment. This figure corresponds to an enlarged view of the inside of the blasting apparatus 1 of FIG. The configuration of FIG. 10 is different from the configuration of FIG. 8 in that a partition member 36 and a partition member 37 are provided in the projection unit 11. The expansion of the projection range below the blast material 40 is limited by the partition member 37. Thereby, it is possible to prevent the blast material 40 from colliding with a portion (for example, a part of the case 10) other than the guard rail 2 that is an object of the blasting process.

  The expansion of the upward projection range is limited by the partition member 36. Further, since the projection range in the longitudinal direction is reduced by the partition member 36 and the partition member 37, the concentration of projection on the guard rail 2 can be increased. Further, the projection range can be adjusted by adjusting the positions of the partition member 36 and the partition member 37.

  The projection range can also be adjusted by adjusting the mounting angle of the blast nozzles 30 and 31 and the arrangement of the mounting positions. In the present embodiment, the blast nozzles 30 and 31 and the projection unit 11 are independent from each other. For this reason, the arrangement of the blast nozzles 30 and 31 can be adjusted while maintaining the fixed state of the projection unit 11. That is, by adjusting the arrangement of the blast nozzles 30 and 31 alone, the projection range can be adjusted, and the adjustment of the projection range is facilitated.

  FIG. 11 is a cross-sectional view illustrating adjustment of the opening widths of the projection port 17 and the projection port 18 of the projection unit 11. In the present embodiment, the projection unit 11 is composed of three independent projection plates 12 to 14. According to this configuration, the opening width of the projection port 17 can be adjusted by adjusting the distance between the projection plate 12 and the projection plate 13. Similarly, the opening width of the projection port 18 can be adjusted by adjusting the distance between the projection plate 13 and the projection plate 14.

  The two-dot chain line in FIG. 11 shows an example in which the projection plate 12 and the projection plate 14 are moved away from the projection plate 13 to increase the opening widths of the projection port 17 and the projection port 18. The projection plate 12 and the projection plate 14 may be moved so as to approach the projection plate 13 to narrow the opening widths of the projection port 17 and the projection port 18.

  For adjusting the distance between the projection plate 12 and the projection plate 13, for example, the thickness of the spacer interposed between the projection plate 12 and the projection plate 13 may be changed, and the projection plate 12 and the projection plate 13 are connected. The degree of tightening of connecting means such as bolts and nuts may be adjusted. These spacing adjustments are the same for the spacing adjustment between the projection plate 13 and the projection plate 14. In this embodiment, since the projection unit 11 is composed of three independent projection plates 12 to 14, the opening widths of the projection ports 17 and 18 can be easily adjusted by adjusting the distance between the opposing projection plates. Can do.

  As mentioned above, although the blasting process of the guard rail 2 was demonstrated in this embodiment, the guard rail 2 can be reproduced | regenerated by spraying the guard rail 2 which carried out the blasting process, and performing coating subsequently. The coating is formed on the guard rail 2 by the thermal spraying process, and the guard rail 2 can be prevented from being corroded. The appearance of the guardrail 2 can be improved by painting.

  In the present embodiment, the projection unit 11 is configured by the three projection plates 12 to 14 and the two blast nozzles 30 and 31 are used. However, the present invention is not limited to this example. The projection unit 11 may be composed of two projection plates, the projection unit 11 may have one projection port, the projection unit 11 may be composed of four or more projection plates, and the projection unit 11 may have three or more projection ports. It is good. Further, the number of blast nozzles corresponding to each projection port may be one or plural.

  In FIG. 2, each of the projection port 17 and the projection port 18 is one continuous opening. On the other hand, if the formation range of the projection port 17 and the projection port 18 is elongated, the effect that the projection range is elongated can be obtained. For this reason, the projection port 17 and the projection port 18 may be ones in which a plurality of openings are intermittently arranged and the formation range is elongated. Similarly, as for the soot outlet 35 of the blast nozzle shown in FIG. 5, the blast nozzle 35 may be a continuous opening or a plurality of openings arranged intermittently as long as the forming range is narrow. The effect of narrowing the ejection range of the material is obtained.

  Moreover, although the target object of the blast process demonstrated in the example of the guard rail in this embodiment, another structure may be sufficient. Since the blasting apparatus according to the present invention can expand the projection range per blast nozzle, it is suitable, for example, for blasting a long member having a large width.

1 Blasting device 2 Guardrail (object)
DESCRIPTION OF SYMBOLS 11 Projection unit 12,13,14 Projection board 15,16 Projection space 17,18 Projection port 30,31 Blast nozzle 35 Spout 36,37 Partition member 40 Blast material

Claims (8)

A blasting device for causing a blasting material to collide with an object,
A blast nozzle for jetting blast material;
A projection unit that projects the blast material ejected from the blast nozzle onto an object;
The projection unit is formed between a pair of wall surfaces, a projection space that narrows the projection width of the blast material, and a projection port that extends the projection length of the blast material with a narrow formation range .
The blast nozzle and the projection port are plural, and each blast nozzle is arranged to correspond to a separate projection port,
The blasting apparatus is characterized in that an overlapping range is generated in a projection range onto an object by the plurality of blast nozzles having different ejection directions of the blast material .   The blasting device according to claim 1, wherein a formation range of the ejection port of the blast nozzle is elongated, and a length of the formation range of the projection port is longer than a length of the formation range of the ejection port.   The blasting device according to claim 1, wherein the projection unit is formed with plate members facing each other. The blasting device according to any one of claims 1 to 3 , wherein an opening width of the projection port is adjustable. The blasting apparatus according to any one of claims 1 to 4 , wherein the blast nozzle can be arranged and adjusted as a single unit . The blasting device according to any one of claims 1 to 5 , wherein a formation range of the jet port of the blast nozzle is elongated, and a width of the jet port is changed so that a central portion is narrowed. The blasting device according to any one of claims 1 to 6 , wherein in the projection unit, the projection space is partitioned by a partition member so that a projection range of the blast material from the projection port is limited. The blasting device according to any one of claims 1 to 7 , wherein the object is a guard rail, and the object side of the projection unit forms unevenness according to the uneven shape of the guard rail.

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