JP5507976B2 - Dust separator - Google Patents

Description

  The present invention relates to a dust separation processing apparatus that separates dust such as polishing powder and cutting dust generated mainly when a relatively small workpiece is ground or cut, and removes a dust having a high density.

  For example, a dental technician grinds or cuts a workpiece such as a denture with a tool such as an air grinder (handpiece). During this work, polishing powder, cutting waste, etc. (hereinafter referred to as dust) are generated. As an apparatus for processing such dust, the applicant of the present application firstly uses a dust collector that sucks dust generated by work and can effectively trap the sucked dust inside the bag-shaped filter unit. It has been proposed (see, for example, Patent Document 1).

JP 2005-40939 A

  However, if the processing target is fine dust containing gypsum etc. and the amount of processing in the dust collector becomes large, it becomes necessary to periodically clean and replace the filter in order to eliminate clogging in the filter in the dust collector As a result, the dust processing efficiency may be reduced.

  On the other hand, conventionally, a separation device that separates dust using a cyclone is known, but in the conventional cyclone separation device, a hopper and a lid of a dust collection container include a plurality of connecting members such as screws and hook hangers. When the dust in the collection container is discarded, the connection member is removed and the collection container with the lid is detached from the hopper, and then the dust is discarded from the container. After that, it was necessary to return the collection container, to attach the lid to the hopper with a connecting member and to reset it, and the disposal process was troublesome.

  The present invention has been made in view of the above-described conventional problems, and an object of the present invention is to provide a dust separation processing apparatus that improves the efficiency of dust processing with a simple structure and facilitates the disposal of dust. Is.

  In order to achieve the above object, a dust separation processing apparatus according to the present invention is a cyclone type dust separation processing apparatus that is connected to a suction machine and separates and removes dust from intake air. It has a suction port, an air exhaust port from which dust has been removed, and a dust exhaust port from which dust has been removed. The air that flows in from the suction port is swirled to separate and remove dust, and the upper exhaust port. A cyclone hopper for discharging air from the lower end and discharging dust from the discharge port at the lower end, a recovery container connected to the discharge port of the cyclone hopper and collecting the removed dust, and the cyclone hopper can be moved up and down freely And a stand that is detached from the recovery container when moved upward, and the recovery container closes the container main body for storing the dust and the upper opening of the container main body so as to be freely opened and closed. And a body, the lower end of the cyclone hopper is connected insertable or disengagement on the lid.

  According to this configuration, after separating and removing the dust from the intake air, the cyclone hopper can be detached from the recovery container simply by moving the cyclone hopper upward, and the lower end of the cyclone hopper is attached to the lid provided on the recovery container. Because it is connected so that it can be inserted and removed, the cyclone hopper reduces the burden on the downstream dust collector and improves the efficiency of dust treatment, and the collection container can be easily attached to and removed from the cyclone hopper. This makes it easy to dispose of the dust inside.

  Preferably, the stand includes a columnar stand main body extending in the vertical direction, a slider coupled to the stand main body so as to be slidable in the vertical direction, and a support plate attached to the slider and supporting the cyclone hopper. Have. Therefore, since the vertical movement of the cyclone hopper is facilitated by the slider, it is easier to attach and detach the collection container from the cyclone hopper.

  Preferably, the cyclone hopper is supported on the front side of the stand main body by the support plate, an engaging body is provided on one of the stand main body and the slider, and the slider is moved up and down by guiding the engaging body to the other. Guide groove means is provided for tilting the slider moved in the direction and moved to the upper limit position so that the lower portion of the slider advances forward from the upper portion. Therefore, when the slider moves to the upper limit position, the lower part of the slider is tilted so as to advance forward from the upper part. Therefore, the cyclone hopper can be moved backward by simply moving the cyclone hopper upward. Therefore, the cyclone hopper does not get in the way when the collection container is attached and detached, and the collection container can be attached and detached more easily.

  Preferably, the engagement body includes a first engagement element and a second engagement element that are spaced apart from each other in the vertical direction, and the guide groove means is disposed to be spaced apart from each other in the vertical direction, and the first engagement element and the second engagement element. The first guide groove has a linear shape extending in the vertical direction, and the second guide groove extends rearward from the vertical groove extending in the vertical direction and the lower end of the vertical groove. It is L-shaped with front and rear grooves. Accordingly, the one-touch operation of only moving the cyclone hopper upward guides both the engagement elements by the both guide grooves, and the cyclone hopper automatically tilts backward, so that the collection container can be attached and detached more easily.

  Preferably, an intermediate stop portion that engages with the second engagement element to determine the rest position of the slider is formed in the front and rear grooves of the second guide groove. Therefore, during the return operation for returning the cyclone hopper to the set position, the second engaging element prevents the front and rear grooves of the second guide groove from continuously moving to the vertical groove at the intermediate stop portion, so that the slider and the cyclone hopper Sudden downward movement can be suppressed.

  Preferably, a straight portion having a uniform outer diameter to be inserted into the insertion hole of the lid is formed at the lower end portion of the cyclone hopper. Therefore, the inclination of the cyclone hopper with respect to the collection container can be prevented.

  Preferably, a sealing member that seals between the cyclone hopper and the lid body is attached to the lower part of the cyclone hopper in contact with the upper surface of the lid body in a state where the cyclone hopper is moved downward. Therefore, it is possible to prevent the dust collected from the cyclone hopper from being collected into the collection container from being scattered outside.

  Preferably, the stand has a stand base that supports the stand main body and on which the collection container is placed. Therefore, the collection container can be stably supported by the stand base.

  According to the present invention, using a cyclone hopper utilizing the suction force of a suction machine, it becomes easy to separate and remove dust such as abrasive powder and cutting waste and to dispose of dust with a simple structure.

It is a perspective view which shows one example of the dust processing system in which the dust separation processing apparatus 1 of this invention is used. It is a perspective view which shows the dust separation processing apparatus which concerns on one Embodiment of this invention. It is a perspective view which shows the dust separation processing apparatus. (A) is the state at the time of a dust treatment set, (B) is the state which lifted the cyclone hopper, (C) is a perspective view of the principal part which shows the resting state of the lifted cyclone hopper, respectively. It is a longitudinal cross-sectional view which shows the detached state of a cyclone hopper and a collection container.

  Hereinafter, preferred embodiments of the present invention will be described with reference to the drawings.

  FIG. 1 shows an example of a dust processing system in which a dust separation processing apparatus 1 of the present invention is used. The dust separation processing apparatus 1 discharges dust by polishing or cutting a workpiece such as a denture, for example. The dust box 7 is disposed between the working box 6 and the dust collector 7 having the filter unit FU and the suction pump P. The dust discharged from the work box 6 is collected by the dust collector 7 via the dust separation processing device 1. Is done. That is, in this system, the dust separation processing device 1 serves as a prefilter for the dust collector 7.

  FIG. 2 is a perspective view showing a dust separation processing apparatus 1 according to an embodiment of the present invention. This dust separation processing apparatus 1 is connected to a suction device such as a suction pump P in a dust collector 7 and is a cyclone type device that separates and removes dust from intake air. The cyclone hopper 2, a recovery container 3 and a stand 5 is provided. The dust separation processing apparatus 1 of FIG. 2 shows the state at the time of dust processing set.

  A stand 5 of the dust separation processing apparatus 1 in FIG. 2 is fixed to a columnar stand main body 20 extending in the vertical direction, a slider 21 slidably connected to the stand main body 20 in the vertical direction, and a lower portion of the slider 21. And a substantially annular support plate 22 for supporting the cyclone hopper 2. The upper surface of the slider 21 is covered with a bonded lid 210. The stand 5 has a flat plate-like stand base 23 that is placed on an installation table such as a floor or a table and supports the stand body 20. The collection container 3 is placed on the upper surface of the stand base 23. The collection container 3 has a bottomed cylindrical shape, and the outer peripheral surface thereof can be positioned by hitting the lower front surface of the stand main body 20. Instead, in this embodiment, positioning is performed by a plurality of positioning posts 24 that are implanted on the stand base 23.

  The cyclone hopper 2 has a cylindrical shape in which the upper part 16 is cylindrical and the lower part 17 is tapered downward. The upper part 16 is covered with a hopper lid 18. The cyclone hopper 2 is horizontally oriented on the side wall of the upper part 16. An intake port 10 for intake air is provided at a position deviated from the center line of 2. An exhaust port 11 for discharging air from which dust has been separated and removed by a cyclone is formed by a pipe bonded to the center of the hopper lid 18, and the removed dust is formed at the lower end of the lower portion 17. The discharge port 12 is open. The cyclone hopper 2 swirls the air flowing in from the suction port 10 to separate and remove the dust, and drops the air from the exhaust port 11 in the upper part 16 and drops the dust from the exhaust port 12 in the lower end part and discharges it. To do. The suction port 10 and the box discharge port 61 of the work box 6 in FIG. 1 are connected by a dust collection pipe 60, and the exhaust port 11 and the dust collection suction part 71 of the dust collector 7 are connected by a dust collection pipe 70.

  The cyclone hopper 2 shown in FIG. 2 is supported on the front side of the stand body 20 by the support plate 22 and the slider 21, and an engagement body 30 is provided on one of the stand body 20 and the slider 21, and the engagement body is provided on the other side. Guide groove means 33 for guiding the united body 30 to move the slider 21 in the vertical direction and tilting the slider 21 moved to the upper limit position so that the lower part of the slider 21 moves forward from the upper part is provided. Yes. Here, the direction in which the cyclone hopper 2 and the columnar stand body 20 are arranged is referred to as the front-rear direction.

  FIG. 3 is a perspective view showing a state in which the dust separation processing device 1 is detached from the collection container 3. In order to attach / detach the collection container 3 to / from the stand 5, the cyclone hopper 2 is lifted obliquely upward.

  As shown in FIG. 4A, the stand main body 20 and the slider 21 have a U-shaped cross section opened forward, and the lid 210 is provided on the upper end of the slider 21. The engagement body 30 includes a first engagement element 31 and a second engagement element 32 that are spaced apart from each other in the vertical direction. In this example, each of the engagement elements 31 and 32 is formed of a cylindrical pin, and is provided on a pair of left and right, for example, the side wall 20a of the stand body 20 and protrudes inward of the stand body 20. The guide groove means 33 includes a first guide groove 34 and a second guide groove 35 which are spaced apart from each other in the vertical direction. The upper first guide groove 34 has a linear shape extending in the vertical direction, and the second guide guide below. The groove 35 has an L shape having a linear vertical groove 36 extending in the vertical direction and a linear front / rear groove 37 extending rearward from the lower end of the vertical groove 36. A pair of left and right guide grooves 34 and 35 are provided on the side walls 21 a and 21 a of the slider 21. A groove 38 that is recessed upward is formed at the upper edge of the front portion of the front and rear groove 37 of the second guide groove 35, and this recessed groove 38 engages with the second engagement element 32 to slide the slider 21. An intermediate stop portion 38 for determining a midway rest position is formed. The upper edge of the rear end of the front and rear groove 37 of the second guide groove 35 is a groove recessed upward, and an inclination stop portion 39 that engages with the second engagement element 32 and determines the inclination stop position of the slider 21. Is formed.

  Each of the engagement elements 31 and 32 is composed of, for example, a screw body screwed into the side wall 20a of the stand main body 20 and a plastic tube such as polyurethane covering the protruding portion. The impact when 31 and 32 hit the ends of the guide grooves 34 and 35 can be alleviated, and the impact sound is also reduced. The first engaging element 31 and the second engaging element 32 may be provided in the slider 21, and the first guiding groove 34 and the second guiding groove 35 may be provided in the stand main body 20.

  As shown in FIG. 2, the cyclone hopper 2 is formed by joining the left and right halves, and the combined portion of both halves extending vertically forms a projecting portion 15 projecting outward. The protrusion 15 is fitted into a through hole 29 provided in the inner peripheral edge of the support plate 22 having a substantially annular shape, and the cyclone hopper 2 can be detached upward by the through hole 29 of the support plate 22. It is supported so as not to rotate around the axis.

  The collection container 3 is connected to the discharge port 12 of the cyclone hopper 2 and collects the removed dust. The stand 5 supports the cyclone hopper 2 so as to be movable up and down via a slider 21, and is detached from the collection container 3 when moved upward. The collection container 3 has a container main body 51 for storing the dust and a lid body 52 that closes an upper opening of the container main body 51 so as to be openable and closable. The lower end of the cyclone hopper 2 is disposed on the lid body 52. The parts are connected so that they can be inserted and removed.

  As shown in FIG. 5, a straight portion 27 having a uniform outer diameter that is inserted into the insertion hole 53 of the lid 52 is formed at the lower end portion of the lower portion 17 of the cyclone hopper 2. The insertion hole 53 through which the lid 52 passes is also formed with a straight hole portion 53b correspondingly. The straight portion 27 can prevent the cyclone hopper from tilting with respect to the collection container 3.

  In addition, a seal member 25 is provided at the lower portion 17 of the cyclone hopper 2 so as to contact the upper surface 54 of the lid body 52 in a state where the cyclone hopper 2 is moved downward and to seal between the cyclone hopper 2 and the lid body 52. ing. The seal member 25 is provided with a seal member 25b made of a rubber O-ring or an annular cushioning packing on the lower surface 25a of the annular main body 25a. As a result, when the lower end portion of the lower portion 17 of the cyclone hopper 2 is inserted into the insertion hole 53 of the lid body 52, the seal member 25 comes into contact with the upper surface 54 of the peripheral edge portion of the insertion hole 53 in the lid body 52. Thus, the insertion hole 53 of the lid body 52 is sealed without a gap, so that dust collected from the cyclone hopper 2 to the collection container 3 can be prevented from scattering to the outside. Further, the impact when the cyclone hopper 2 comes into contact with the lid 52 of the collection container 3 can be reduced, and the impact sound is also reduced.

Next, the handling and operation of the dust separation processing apparatus 1 will be described.
The suction force of the suction pump P built in the dust collector 7 of FIG. 1 acts on the cyclone hopper 2, and the intake air containing dust is sucked into the cyclone hopper 2 from the suction port 10 of the upper part 16 of the cyclone hopper 2 of FIG. Is done. The intake air becomes a vortex in the cyclone hopper 2, and high-density heavy particles move downward along the inner surface of the conical lower portion 17 while swirling by centrifugal force, and fall from the discharge port 12 to the lower collection container 3. To do. Fine particles such as dust having a low density rise on a rising swirl vortex formed in the center of the cyclone hopper 2 and are discharged to the outside from the exhaust port 11 at the upper end of the cylindrical portion. Thus, since air from which heavy particles have been separated and removed is introduced into the dust collector 7 of FIG. 1, the filtering burden of the dust collector 7 is reduced, and therefore the occurrence of clogging of the filter unit FU of the dust collector 7 is delayed. The dust processing efficiency is improved by that amount.

  After the dust processing by the dust separation processing apparatus 1, the collection container 3 is detached from the dust separation processing apparatus 1 by the following operation, and the dust in the collection container 3 is discarded.

  FIG. 4A shows the same dust treatment set state as FIG. 2, the cyclone hopper 2 is in a vertical posture, and the engagement elements 31, 32 of the stand body 20 are respectively guided grooves 34 of the slider 21, The upper end of 35 is engaged.

  FIG. 4B shows a state where the cyclone hopper 2 is lifted in order to disengage the cyclone hopper 2 from the collection container 3. When the front portion 22a of the support plate 22 is lifted with the finger F in the R1 direction, the slider 21 rises, and the first engagement element 31 and the second engagement element 32 are longitudinal grooves of the first guide groove 34 and the second guide groove 35. As shown in FIG. 5, the first guide groove 34 and the second guide groove 35 move to the lower end portions while being guided by the guide 36. Further, since the front portion 22a on which the operating force of the finger F acts on the first engagement element 31 is displaced forward, the lifting force acting on the front portion 22a of the support plate 22 is applied to the slider 21 on the first engagement element. Since the tilting moment about 31, that is, the moment at which the lower part of the slider 21 tries to advance forward from the upper part is given, the second engagement element 32 naturally occurs when it reaches the lower end of the vertical groove 36 of the second guide groove 35. It advances into the front-rear groove 37, stops by being fitted into the tilt stop 39 at the rear end of the front-rear groove 37, and assumes the posture shown in FIG. Here, the ascending stroke of the cyclone hopper 2, that is, the vertical lengths of the first guide groove 34 and the vertical groove 36, is such that the straight portion 27 at the lower end of the cyclone hopper 2 comes out from the lid 52 of the collection container 3 upward. It is set to a sufficient length.

  In this way, since the cyclone hopper 2 smoothly inclines backward, the cyclone hopper 2 is fitted into the tilt stop portion 39 of the front and rear grooves 37 of the second guide groove 35 and stopped. The lower end portion of the lower portion 17 of FIG. 2 and the collection container 3 are further separated by the inclination, so that the cyclone hopper 2 does not get in the way when the collection container 3 is taken out, and the collection container 3 can be taken out easily. In this way, the cyclone hopper 2 can be brought into the detached position by a simple one-touch operation. Note that the tilt stop portion 39 may be omitted, and even in that case, the upper edge of the front and rear groove 37 of the second guide groove 35 is formed by the weight of the cyclone hopper 2 as shown in FIG. The rearward tilt posture of the cyclone hopper 2 is maintained by being pressed against the top.

  In the posture of FIG. 3 in which the cyclone hopper 2 is tilted backward, the cyclone hopper 2 may return to the original vertical posture by receiving an impact force from the outside. In this case, as shown in FIG. 4C, the slider 21 rotates around the first engagement element 31 and fits in the intermediate stop portion 38 in the front and rear groove 37 of the second guide groove 35 to tilt backward. The posture becomes a little closer to the vertical posture than the posture and rests. Thus, the second engaging element 32 is prevented from suddenly entering the longitudinal groove 36 and the cyclone hopper 2 together with the slider 21 being prevented from descending.

  Unlike after the dust treatment described above, when the dust container is discarded, the collection container 3 is returned to the stand base 23 and the cyclone hopper 2 is set to start the dust treatment. 4 Operation is performed in the procedure of (B), (C), (A). In FIG. 4B, since the cyclone hopper 2 is inclined rearward, the collection container 3 can be easily placed on the stand base 23. Next, when the support plate 22 is pushed backward R <b> 2 by the force of the light finger F, the second engagement element 32 is detached from the tilt stop portion 39, and the front and rear grooves 37 of the second guide groove 35 with respect to the second engagement element 32. Moves rearward, and the second engagement element 32 is fitted into the intermediate stop portion 38 of the front-rear groove 37 and rests. Accordingly, it is possible to prevent the second engagement element 32 from entering the vertical groove 36 of the second guide groove 35 at a stretch with a small pushing force and the cyclone hopper 2 from dropping suddenly. When the support plate 22 is further pushed in the R2 direction from this resting state, the second engagement element 32 is detached from the intermediate stop portion 38, naturally enters the longitudinal groove 36 from the front and rear grooves 37, and reaches the upper end of the longitudinal groove 36. To lock automatically. Thereby, the cyclone hopper 2 is set in a vertical posture, and its lower end is inserted into the collection container 3.

  The insertion hole 53 of the lid body 52 is formed with a guide surface 53 a that is widened upward at the top, whereby when the straight portion 27 at the lower end of the cyclone hopper 2 is inserted into the insertion hole 53. Even when the collection container 3 is not concentric with the cyclone hopper 2, the straight container 27 enters the straight hole 53 b below the insertion hole 53 while being guided by the guide surface 53 a, so that the collection container on the stand base 23. 3 moves, and the collection container 3 is positioned.

  Thus, after separating and removing the dust from the intake air, the cyclone hopper 2 can be detached from the collection container 3 simply by moving the cyclone hopper 2 upward, and the lid 52 provided toward the collection container 3 is attached to the cyclone hopper 2. Since the lower end portion is connected so as to be able to be inserted / removed, it is not necessary to attach / remove the connecting member when attaching / detaching the cyclone hopper and the collection container as in the prior art. It becomes easy and the operation | work which discards the dust in the collection container 3 becomes easy.

  In the above-described embodiment, the case where the work box 6 and the dust collector 7 are installed to perform the work has been described as an example. However, the present invention is not limited to this. It can be applied to any system that is connected to a suction machine and separates and removes dust from the intake air.

DESCRIPTION OF SYMBOLS 1 Dust separation processing apparatus 2 Cyclone hopper 3 Collection container 5 Stand 10 Intake port 11 Exhaust port 12 Discharge port 20 Stand main body 21 Slider 22 Support plate 23 Stand base 25 Seal member 30 Engagement body 31 1st engagement element 32 2nd engagement element 33 Guide groove means 34 First guide groove 35 Second guide groove 36 Vertical groove 37 Front / rear groove 38 Intermediate stop portion 39 Inclined stop portion 51 Container body 52 Lid

Claims (6)

A cyclone type dust separation processing device connected to a suction machine and separating and removing dust from intake air,
It has an intake port for the intake air, an exhaust port for air from which dust has been removed, and a discharge port for dust that has been removed, and the air flowing in from the intake port is swirled to separate and remove dust. A cyclone hopper that discharges air from the exhaust port and discharges dust from the discharge port at the lower end,
A collection container connected to the cyclone hopper outlet for collecting the removed dust;
The cyclone hopper is supported in a vertically movable manner, and includes a stand that is detached from the collection container when moved upward.
The collection container has a container main body for storing the dust and a lid body that closes an upper opening of the container main body so that the upper opening can be opened and closed, and a lower end portion of the cyclone hopper is connected to the lid body so as to be inserted and removed. Has been
The stand has a columnar stand body extending in the vertical direction, a slider connected to the stand body so as to be slidable in the vertical direction, and a support plate attached to the slider and supporting the cyclone hopper,
The cyclone hopper is supported on the front side of the stand body by the support plate,
An engaging body is provided on one of the stand body and the slider, and a guide groove for guiding the engaging body is provided on the other, and the engaging body is guided by a lifting force acting on the support plate to move the slider in the vertical direction. A dust separation processing apparatus provided with guide groove means for tilting the slider that has been moved and moved to the upper limit position so that the lower part of the slider advances forward from the upper part . A cyclone type dust separation processing device connected to a suction machine and separating and removing dust from intake air,
It has an intake port for the intake air, an exhaust port for air from which dust has been removed, and a discharge port for dust that has been removed, and the air flowing in from the intake port is swirled to separate and remove dust. A cyclone hopper that discharges air from the exhaust port and discharges dust from the discharge port at the lower end,
A collection container connected to the cyclone hopper outlet for collecting the removed dust;
The cyclone hopper is supported in a vertically movable manner, and includes a stand that is detached from the collection container when moved upward.
The collection container has a container main body for storing the dust and a lid body that closes an upper opening of the container main body so that the upper opening can be opened and closed, and a lower end portion of the cyclone hopper is connected to the lid body so as to be inserted and removed. Has been
The stand has a columnar stand body extending in the vertical direction, a slider connected to the stand body so as to be slidable in the vertical direction, and a support plate attached to the slider and supporting the cyclone hopper,
The cyclone hopper is supported on the front side of the stand body by the support plate,
An engaging body is provided on one of the stand main body and the slider, and the engaging body is guided to the other to move the slider in the vertical direction, and the slider moved to the upper limit position, the lower part of the slider is placed forward of the upper part. Guide groove means for tilting to advance is provided,
The engagement body includes a first engagement element and a second engagement element that are spaced apart from each other in the vertical direction, and the guide groove means is disposed to be spaced apart from each other in the vertical direction to guide the first engagement element and the second engagement element, respectively. Comprising a first guide groove and a second guide groove,
The first guide groove has a linear shape extending in the vertical direction, and the second guide groove has an L shape having a vertical groove extending in the vertical direction and front and rear grooves extending rearward from the lower end of the vertical groove. The dust separation processing device according to claim 2 , wherein an intermediate stop portion is formed in the front and rear grooves of the second guide groove to engage with the second engagement element to determine the rest position of the slider. The dust separation processing apparatus according to any one of claims 1 to 3 , wherein a straight portion having a uniform outer diameter is formed at a lower end portion of the cyclone hopper and inserted into an insertion hole of the lid. In any one of claims 1 to 4, the lower part of the cyclone hopper, the sealing member cyclone hopper in contact with the upper surface of the lid in a state of being moved downward to seal between the cyclone hopper and the lid Is a dust separation treatment device. In any one of claims 1 to 5, wherein the stand, dust separating apparatus having a stand base that supports the stand body, and the collection container is placed.

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