TWM413548U - Rotating ejecting apparatus - Google Patents

Description

M413548 V. New description: [New technical field] This creation is about the design of a spray blasting device, especially for a rotary spray device driven by a rotary drive mechanism. [Prior Art] Various spray guns are widely used to remove ash and dirt on the surface of objects, water spray, spray paint, and various other uses. This type of spray gun sprays a high-pressure gas to remove ash and dirt, or uses high-pressure gas mixed with water or other spray to spray and paint. In order to make the spraying effect uniform, the spray control of the spray is curved, and a rotating mechanism is combined on the spray nozzle. The nozzle is rotated by the rotating member, so that the mixed fluid of the high-pressure fluid and the spray can be uniformly ejected in all directions as the nozzle rotates. For example, the rotating mechanism may be a fan provided with a plurality of blades that rotate the rotating mechanism by pushing the blades with high pressure fluid introduced into the blasting. Alternatively, the rotating mechanism can be a motor that uses external power to drive the rotating mechanism to cause the nozzle to rotate. However, the shape of the blade is complicated and the structural strength is poor, which is difficult in manufacturing and miniaturization of the volume and is easily damaged and deformed. The motor requires additional power to be supplied, which is costly in terms of production costs and power. [New content] The technical problem to be solved by the present invention In view of the above, the conventional spray blasting uses a fan or a motor to drive the nozzle of the spray gun to rotate, which is difficult to manufacture and costly to the south. 0 3 M413548 Therefore, the purpose of this creation is to provide a rotary injection device that is structurally strong, easy to manufacture, stable in rotation, and that does not require electric drive. Technical Solution for Solving the Problem The present invention provides a rotary injection device for solving the problems of the prior art, comprising: a fluid conveying pipe body, one end of the fluid conveying pipe body is provided with a fluid inlet, and the fluid conveying pipe The other end of the body is provided with a discharge port, and a plurality of through holes are arranged in the wall of the fluid conveying pipe body; a rotary driving mechanism is coupled to the fluid conveying pipe body, and the rotating driving mechanism has a fluid output direction with the through hole a sloping fluid ejector wall, and a first-stage outlet passage formed at an end of the fluid ejector wall, the fluid ejector wall being fluidly connected to the fluid outputted by the through-hole through a fluid-conducting space; a delivery tube The body has a receiving fluid inlet at one end and a fluid receiving mechanism, and the other end is disposed in the fluid conveying pipe body and extends to the discharge port of the fluid conveying pipe body. In one embodiment of the present invention, the fluid ejector wall of the rotary drive mechanism extends in an involute direction. In one embodiment of the present invention, the rotary drive mechanism has a plurality of fixed ribs that project toward the fluid delivery tube body. In one embodiment of the present invention, the rotary drive mechanism includes a front fixed layer, a rear fixed layer, and a flow path structure layer sandwiched between the front fixed layer and the rear fixed layer. Further, the front fixing layer and the rear fixing layer are made of a hard material, and the flow path structure layer is made of a plastic material. In an embodiment of the present invention, a flow dividing member is further disposed in the fluid conveying pipe body, and the fluid flowing into the fluid conveying pipe body is divided into two parts, and one part of the fluid flows to the discharge port of the fluid conveying pipe body, and the fluid The other portion flows to the through hole of the fluid delivery tube body. In an embodiment of the present invention, a flow regulating mechanism is further disposed in the conveying pipe body, including a water blocking wall and a water stopping rod member, and the water blocking wall has a shape limiting hole 4 M413548, and the water stopping rod member A tapered portion is formed at one end, and the tapered portion of the water stop member is displaced in the restricting hole of the water blocking wall. In an embodiment of the present invention, a rotational speed adjusting mechanism includes a first adjusting member and a second adjusting member. The first adjusting member is coupled to the outflow passage of the rotary driving mechanism, and has a plurality of An output surface of the opening, the second adjusting member has an input surface, the input surface of the second adjusting member is rotatably coupled to the output surface of the first adjusting member, and the input surface is formed with a plurality of corresponding first openings The second opening. The effect of this creation against the prior art, through the technical means employed in the creation, enables the fluid delivery tube to rotate without the need for electric drive. With respect to the rotary drive mechanism, the fluid ejector wall, the outflow passage, and the flow guiding space are formed inside the rotary drive mechanism, so that the structure of the rotary drive mechanism can be made relatively strong and can be easily miniaturized. Further, the rotary drive mechanism having such a structure is stable at the time of rotation, and the rotation speed is uniform and the fluctuation is small, which is advantageous for uniformly spraying the fluid. Specific embodiments of the present invention will be further illustrated by the following examples and the accompanying drawings. [Embodiment] Please refer to FIG. 1, FIG. 2, and FIG. 3, and FIG. 1 is a perspective view of a rotary jet apparatus according to an embodiment of the present invention, and FIG. 2 is a cross-sectional view of FIG. The figure shows a partial enlarged view of Fig. 2. Rotary spray device 100 in accordance with one embodiment of the present invention includes a body 1. One end of the body 1 is provided with a control handle 11 and a fluid receiving mechanism 12 is coupled to the lower side of the body 1. A fluid conveying pipe body 2 is disposed in the body 1. The fluid delivery tube body 2 5 M413548 is coupled to the body 1 through a bearing 20 and is rotatable along the axial direction of the rotary injection device 100. One end of the fluid delivery tube 2 extends into the control handle 11, and a fluid inlet 21 is provided at one end of the fluid delivery tube 2 for a fluid F1 to be input therefrom. The other end of the fluid delivery tube 2 extends to the other side of the body 1 and is provided with a discharge port 22. The fluid F1 input from the fluid inlet 21 is output from the discharge port 22. Further, a rotary drive mechanism 3 is provided in the body 1, and the rotary drive mechanism 3 is coupled to the fluid delivery pipe body 2 for driving the fluid delivery pipe 2 to rotate for rotary injection. In addition, a conveying pipe body 4 is provided in the body 1. One end of the conveying pipe body 4 is provided with an accommodating fluid inlet 41 connected to the fluid accommodating mechanism 12. The other end of the conveying pipe body 4 is provided with an accommodating fluid outlet 42, which is bored in the fluid conveying pipe body 2 and extends to the discharge port 22 of the fluid conveying pipe body 2. When the fluid F1 is ejected from the discharge port 22 of the fluid transport tube 2, a Venturi effect is generated at the nozzle, and the accommodating fluid F2 in the fluid accommodating mechanism 12 is ejected outward through the transport tube 4. Please refer to FIG. 4 and FIG. 5 again. FIG. 4 is a perspective view showing the rotary drive mechanism, and FIG. 5 is a cross-sectional view showing the rotary drive mechanism. The rotary drive mechanism 3 in this embodiment includes a front fixing layer 3a, a rear fixing layer 3b, and a flow path structure layer 3c sandwiched between the front fixing layer 3a and the rear fixing layer 3b. The front fixing layer 3a and the rear fixing layer 3b have a simple structure, and thus can be made of a hard material such as metal or acrylic. The structure of the flow channel structure layer 3c is relatively complicated, and can be made of a plastic material such as plastic or rubber. In this way, the rotary drive mechanism 3 can be easily manufactured. However, the present creation is not limited thereto, and the flow path structure layer 3c may be made of a hard material. The rotary drive mechanism 3 is coupled to the fluid delivery tube body 2. A plurality of through holes 23 are formed in the wall of the fluid supply 6 M413548 to the pipe body 2 to communicate with the rotary drive mechanism 3. Further, a flow dividing member 24 is provided in the fluid delivery pipe body 2, and the flow dividing member 24 is a pipe body in this embodiment. The flow dividing member 24 is bored in the fluid delivery tube body 2 to isolate the fluid delivery tube body 2 into two regions. Thereby, when the fluid F1 flows through the flow dividing member 24, it is branched into two parts, and one part of the fluid F1 flows to the discharge port 22 of the fluid delivery pipe body 2 via the inner region of the flow dividing member 24, and another portion of the fluid F1 is passed through The outer side region of the flow dividing member 24 flows to the through hole 23 of the fluid transport pipe body 2. This portion of the fluid F1 flows into the rotary drive mechanism 3 via the through hole 23. The rotary drive mechanism 3 has a fluid ejector wall 31 which is inclined with respect to the fluid output direction of the through hole 23. An outflow passage 32 is formed at an end of the fluid pushing wall 31. The fluid F1 input from the through hole 23 through the rotary drive mechanism 3 flows through a flow guiding space 33 to be applied to the fluid ejector wall 31, and then flows out of the vortex driving mechanism 3 from the outflow passage 32. In this process, the fluid ejector wall 31 is biased by the fluid F1 output from the through hole 23 to rotate the rotary drive mechanism 3. Thereby, the fluid transport tube 2 is rotated together by the interlocking of the rotary drive mechanism 3. The direction of rotation of the rotary drive mechanism 3 is related to the direction of inclination of the fluid ejector wall 31. The fluid ejector wall 31 in this embodiment is formed to extend in an involute direction as shown in Fig. 5, so that the rotational direction of the rotary drive mechanism 3 is a clockwise direction. Note that although the number of fluid ejector walls 31 in this embodiment is four, the present creation is not limited thereto. The number of fluid ejector walls 31 can be one. In this case, the outflow passage 32 is formed between the front end and the rear end of the fluid ejector wall 31. In addition, the rotary drive mechanism 3 has a plurality of fixing ribs 34a, 34b protruding toward the fluid delivery tube body 2 for positioning the fluid delivery tube body 2 7 M413548 at the center of rotation of the rotary drive mechanism 3 to reduce the deviation during rotation. Pendulum error. According to the structure disclosed in the present invention, the fluid transport tube 2 can be rotated without electric drive. Since the fluid ejector wall 31, the outflow channel 32, the flow guiding space 33, and the like are all formed inside the rotary drive mechanism 3, the structure of the rotary drive mechanism 3 is relatively strong and is easily miniaturized. Further, the rotary drive mechanism 3 having such a configuration is stable at the time of rotation, and the rotation speed is uniform and the fluctuation is small. Please refer to Figure 6 again. Figure 6 shows a cross-sectional view of the flow adjustment mechanism. In order to regulate the flow rate of the accommodating fluid F2 outputted through the conveying pipe body 4, a flow regulating mechanism 5 is further provided in the conveying pipe body 4 of this embodiment. The flow regulating mechanism 5 includes a water blocking wall 51, a water stopping member 52, and an adjusting member 53. A water restricting hole 511 is formed in the water blocking wall 51 to allow the fluid F2 flowing through the conveying pipe body 4 to pass through the restricting hole 511. One end of the water stop rod member 52 is formed with a tapered portion 521, and the tapered portion 521 of the water stop rod member 52 is movably disposed in the restricting hole 511 of the water blocking wall 51. The other end of the water stop member 52 extends outside the body 1 and is coupled to the adjustment member 53 (Fig. 2). The depth of the tapered portion 521 of the water stop rod member 52 passing through the restricting hole 511 of the water blocking wall 51 can be adjusted by the adjusting member 53, whereby the gap between the limiting hole 511 and the tapered portion 521 can be changed, and The flow rate of the fluid F2 flowing through the conveying pipe body 4 is adjusted. Please refer to Fig. 7 and Fig. 8 again. Fig. 7 is a perspective view showing the rotation speed adjusting mechanism, and Fig. 8 is another perspective view showing the rotation speed adjusting mechanism. In order to adjust the rotational speed of the fluid delivery tube 2 and the rotary drive mechanism 3, the rotary injection device 100 is further provided with a rotational speed adjustment mechanism 6. The rotational speed adjusting mechanism 6 includes a first regulating member 61 and a second regulating member 62. The first regulating member 61 is coupled to the outflow passage 32 of the rotary drive mechanism 3. Furthermore, the first adjusting member 61 has an output surface 611, and a plurality of first openings 612 are formed on the output surface 611. Therefore, it is known that the fluid F1 flowing out of the rotary drive mechanism 3 flows into the first regulating member 6j' and then flows out from the first opening 612. The second regulating member 62 has an input face 621'. The input face 021 is formed with a plurality of second openings 622 corresponding to the first opening 612. The input face 621 of the second adjustment member 62 is condensably coupled to the output face "I of the first adjustment member 61. With such a configuration, with the relative rotational displacement between the first adjustment member 61 and the second adjustment member 62 The size of the communication gap between the first opening 612 and the second opening 622 can be changed. Therefore, the flow rate of the fluid F1 flowing out of the rotation driving mechanism 3 can be adjusted, and the magnitude of the flow rate determines the rotation driving mechanism 3 Rotation speed. It can be seen from the above embodiments that the rotary jetting device provided by the present invention has industrial value. Therefore, the present invention has met the requirements of the patent. However, the above description is only a description of the preferred embodiment of the present invention. Anyone who is skilled in this skill can make other improvements according to the above description, but these changes are still in the creative spirit of this creation and the patent scope defined below. [Simplified illustration] Figure 1 According to the present invention, a rotary spray perspective view of the embodiment; a second diagram showing a cross-sectional view of FIG. 1; a f3 diagram showing a partial enlarged view of FIG. 2; and a fourth diagram showing a rotary drive Fig. 5 is a cross-sectional view showing the rotary drive mechanism; Fig. 6 is a cross-sectional view showing the flow rate adjusting mechanism; Fig. 7 is a perspective view showing the rotational speed adjusting mechanism; and Fig. 8 is a perspective view showing the rotational speed adjusting mechanism. M413548

[Main component symbol description] 100 rotary injection device 1 body 11 control handle 12 fluid accommodation mechanism 2 fluid delivery pipe body 20 bearing 21 fluid inlet 22 discharge port 23 through hole 24 shunt member 3 rotary drive mechanism 3a front fixed layer 3b Fixed layer 3c flow channel structure layer 31 fluid ejector wall 32 outflow channel 33 flow guiding space 34a fixing rib 34b fixing rib 4 conveying pipe body 41 accommodating fluid inlet 42 accommodating fluid outlet 5 flow regulating mechanism 51 water blocking wall 511 limiting hole 52 Water stop rod M413548 521 Tapered portion 53 Adjustment member 6 Speed adjustment mechanism 61 First adjustment member 611 Output surface 612 First opening 62 Second adjustment member 621 Input surface 622 Second opening FI Fluid F2 Fluid

Claims (1)

M413548, the scope of patent application: 1. A rotary injection device comprising: a fluid delivery tube body, one end of the fluid delivery tube body is provided with a fluid inlet, and the other end of the fluid delivery tube body is provided with a discharge port, and the fluid is The pipe wall of the conveying pipe body is provided with a plurality of through holes; a rotary driving mechanism is coupled to the fluid conveying pipe body, and the rotating driving mechanism has a fluid ejector wall inclined to the fluid output direction of the through hole, and An outflow channel formed at an end of the fluid ejector wall, the fluid ejector wall being fluidly coupled to the fluid outputted by the through hole through a fluid connection of the flow guiding space; One end is provided with a receiving fluid inlet for connecting to a fluid receiving mechanism, and the other end is disposed in the fluid conveying pipe body and extends to the discharge port of the fluid conveying pipe body, wherein the fluid inlet port flows into the outlet a portion of a fluid of the fluid delivery tube body flows into the rotary drive mechanism through the through hole, the fluid ejector wall being biased by the fluid to drive the rotation Structure rotates and drives the rotation of the fluid delivery tube for rotation injection. 2. The rotary jet apparatus of claim 1, wherein the fluid ejector wall of the rotary drive mechanism extends in an involute direction. 3. The rotary injection device of claim 1, wherein the rotary drive mechanism has a plurality of fixing ribs projecting toward the fluid delivery tube body. 4. The rotary injection according to claim 1 The device, wherein the rotary drive mechanism comprises a front fixing layer, a rear fixing layer, and a flow channel structure layer sandwiched between the front fixing layer and the rear fixing layer. 5. The rotary spray device of claim 4, wherein the 12 M413548 front fixed layer and the rear fixed layer are made of a hard material, the flow channel structural layer being made of a plastic material. . 6. The rotary spray device of claim 1, wherein the fluid delivery body further comprises a 'flow dividing member' to split the fluid flowing into the fluid delivery pipe into two parts, wherein the fluid is A portion flows to the discharge port of the fluid delivery tube body, and another portion of the fluid flows to the through hole of the fluid delivery tube body. 7. The rotary injection device of claim 1, wherein a flow regulating mechanism is further disposed in the conveying pipe body, comprising a water blocking wall and a water stopping rod, wherein the water blocking wall defines a limit The hole, one end of the water stop rod member is formed with a tapered portion, and the tapered portion of the water stop rod member is movably disposed in the restricting hole of the water blocking wall. 8. The rotary injection device of claim 1, further comprising a rotational speed adjusting mechanism comprising a first adjusting member and a second adjusting member, the first adjusting member being coupled to the outflow passage of the rotary driving mechanism And having an output surface formed with a plurality of first openings, the second adjustment member having an input surface, the input surface of the second adjustment member being rotatably coupled to the output surface of the first adjustment member, and the A plurality of second openings corresponding to the first openings are formed on the input surface. 13