CN218196138U - Suction device of mortar type slicing machine - Google Patents

Abstract

The embodiment of the utility model provides a mortar type slicer suction device belongs to the relevant technical field of slicer, acts on the water collector, and suction device includes: the gas source assembly is used for providing gas required by the suction device; the vacuum generating device is communicated with the air source assembly and the water receiving tray, and is used for providing negative pressure required by the suction device; the water outlet pipe is communicated with the vacuum generating device, so that under the action of the air source assembly, the vacuum generating device can suck accumulated liquid contained in the water tray and send the sucked accumulated liquid into the water outlet pipe; the technical effect that stable work of the spool is influenced by the fact that sand slurry is not prone to stacking and leaking is achieved.

Description

Suction device of mortar type slicing machine

Technical Field

The utility model relates to a slicer technical field especially relates to a mortar type slicer suction device.

Background

A mortar type slicer for cutting silicon rod, the form of cutting that adopts is through drenching the sand slurry on the line net of cutting, relies on the line net to carry the sand slurry to cutting region and cuts the silicon rod. When the mortar type slicing machine is used, the mortar liquid is a main consumable material in the silicon wafer cutting process.

Among the prior art, receive and release the line subassembly in the slicer because diamond wire drives the mortar liquid and gets into and receive and release the line room to the mortar liquid is taken out by the diamond wire and is got rid of in the water collector of spattering and drip in tension arm subassembly and receive and release the line room in the water collector, thereby leads to the unable recovery of the mortar liquid of taking out. And long-term accumulation of sand thick liquid appears the seepage easily in cutting process, influences cleanliness and follow-up maintenance, and the weeping probably overflows to receive and release indoor back in addition, produces the influence to the steady work of I-shaped wheel.

Therefore, the technical problems of the prior art are as follows: the stable work of the I-shaped wheel is influenced to the easy accumulation of sand thick liquid and reveal.

SUMMERY OF THE UTILITY MODEL

The embodiment of the application provides a suction device of a mortar type slicing machine, which solves the technical problem that mortar liquid is easy to accumulate and leak to influence the stable work of a spool in the prior art; the technical effect that stable work of the spool is influenced by the fact that sand slurry is not prone to stacking and leaking is achieved.

The embodiment of the application provides a mortar type slicer suction device acts on the water collector, and suction device includes: the gas source assembly is used for providing gas required by the suction device; the vacuum generating device is communicated with the air source assembly and the water receiving tray, and is used for providing negative pressure required by the suction device; and the water outlet pipe is communicated with the vacuum generating device, so that under the action of the air source assembly, the vacuum generating device can suck accumulated liquid contained in the water tray and send the sucked accumulated liquid into the water outlet pipe.

Preferably, the water collector includes: the first water receiving tray is used for receiving accumulated liquid dropping in the external wire collecting and releasing chamber; and the second water receiving disc is used for receiving the accumulated liquid dropping below the external tension arm.

Preferably, the vacuum generating device includes: the vacuum generator is communicated with the air source assembly, and the vacuum generator is communicated with the water receiving tray and the water outlet pipe, so that the vacuum generator can suck the dropsy in the water receiving tray.

Preferably, the flow guide device further includes: a connector, the connector comprising: the first end of the first connecting piece is communicated with the air source assembly, and the second end of the first connecting piece is communicated with the vacuum generating device; the first end of the second connecting piece is communicated with the vacuum generating device, and the second end of the second connecting piece is communicated with the water outlet pipe; a third connecting piece, wherein the first end of the third connecting piece is communicated with the vacuum generating device; and the fourth connecting piece is communicated with the second end of the third connecting piece, and the fourth connecting piece is communicated with the water receiving tray.

Preferably, the first connecting piece is provided with a first joint, and the first joint is fixedly connected with an external metal plate.

Preferably, the fourth connecting member includes: the first end of the three-way joint is communicated with the third connecting piece; the first end of the first water pumping pipe is communicated with the second end of the three-way joint, the second end of the first water pumping pipe is connected with the water receiving tray, and the first water pumping pipe is used for pumping accumulated liquid dropping in the first water receiving tray; and the second drinking-water pipe, the first end of second drinking-water pipe with three way connection's third end intercommunication, the second of second drinking-water pipe end with the water collector is connected, the second drinking-water pipe is used for pumping the hydrops that drip in the second water collector.

Preferably, the vacuum generator and the three-way joint are both connected with a second joint, and the second joints are respectively communicated with two ends of the third connecting piece.

Preferably, the water pan is connected with a third joint, the third joint is communicated with the fourth connecting piece, the bottom end of the water pan is connected with a guide pipe, and the guide pipe is communicated with the third joint.

Preferably, the vacuum generating device is located below the air source assembly, and the vacuum generating device is located above the water pan.

Preferably, the water outlet pipe is located below the vacuum generating device, and the water outlet pipe is located below a cutting chamber of an external slicing machine.

One or more technical solutions in the embodiments of the present application have at least one or more of the following technical effects:

1. in the embodiment of the application, the vacuum generating device is communicated with the air source component and the water receiving tray, under the action of the air source component, the vacuum generating device can suck accumulated liquid contained in the water receiving tray and send the sucked accumulated liquid into the water outlet pipe, so that the phenomenon that sand slurry is easy to accumulate and leak to influence the stable work of the spool is avoided, and the technical problem that the sand slurry is easy to accumulate and leak to influence the stable work of the spool in the prior art is solved; the technical effect that stable work of the spool is influenced by the fact that sand slurry is not prone to stacking and leaking is achieved.

2. In the embodiment of the application, vacuum generator and air supply subassembly intercommunication, and vacuum generator and water collector intercommunication, through the hydrops that holds in the vacuum generator butt joint water collector suction, the hydrops after the suction is sent into in the outlet pipe to be favorable to the reuse of hydrops, improve the sand slurry rate of recovery, prevent that the hydrops from piling up, effectively prevent the seepage, the spare part in the protection line receiving and releasing room.

Drawings

FIG. 1 is a schematic diagram of a suction device of a mortar slicer in an embodiment of the present application;

FIG. 2 is a schematic view of the fluid withdrawal orientation of FIG. 1;

FIG. 3 is a front view of FIG. 1;

fig. 4 is an enlarged view of a portion a in fig. 1.

Reference numerals are as follows:

100. a gas source assembly; 200. a water pan; 210. a first water pan; 220. a second water pan; 221. a third joint; 222. a conduit; 300. a vacuum generating device; 310. a vacuum generator; 400. a connecting member; 410. a first connecting member; 411. a first joint; 420. a second connecting member; 430. a third connecting member; 431. a second joint; 440. a fourth connecting member; 441. a first pumping pipe; 442. a second pumping pipe; 443. a three-way joint; 500. and (5) discharging a water pipe.

Detailed Description

The ordinal numbers used herein for the components, such as "first," "second," etc., are used merely to distinguish between the objects described, and do not have any sequential or technical meaning. The term "connected" and "coupled" when used in this application, unless otherwise indicated, includes both direct and indirect connections (couplings). In the description of the present application, it is to be understood that the terms "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", and the like, indicate orientations or positional relationships based on those shown in the drawings, and are used only for convenience in describing the present application and for simplicity in description, and do not indicate or imply that the devices or elements referred to must have a particular orientation, be constructed in a particular orientation, and be operated, and thus, are not to be considered as limiting the present application.

In this application, unless expressly stated or limited otherwise, the first feature "on" or "under" the second feature may be directly contacting the first and second features or indirectly contacting the first and second features through intervening media. Also, a first feature "on," "over," and "above" a second feature may be directly or diagonally above the second feature, or may simply indicate that the first feature is at a higher level than the second feature. A first feature being "under," "below," and "beneath" a second feature may be directly under or obliquely under the first feature, or may simply mean that the first feature is at a lesser elevation than the second feature.

In order to better understand the technical solution, the technical solution will be described in detail with reference to the drawings and the specific embodiments.

In the working process of the slicing machine, the wire collecting and releasing assembly in the slicing machine drives the sand slurry to enter the wire collecting and releasing chamber due to the diamond wires, and the sand slurry is accumulated in the water receiving tray of the tension arm assembly and the water receiving tray of the wire collecting and releasing chamber. Sand slurry and other impurity form the hydrops, and the hydrops influences operational environment's cleanliness easily and is unfavorable for follow-up maintenance to and the sand slurry in the hydrops easily piles up reveals the stable work that influences the I-shaped wheel. The embodiment of the application provides a mortar type slicer suction device can avoid the mortar to pile up and reveal the steady operation that influences the I-shaped wheel to and influence operational environment's cleanliness and be favorable to follow-up maintenance.

As shown in fig. 1 to 4, a suction device of a mortar slicer, which acts on a water pan 200, comprises an air source assembly 100, a vacuum generating device 300, a connecting member 400 and a water outlet pipe 500. The gas source assembly 100 is used to provide the gas required by the pumping device. The vacuum generating device 300 is used to provide the negative pressure required by the suction device. The water outlet pipe 500 is used for carrying the effusion pumped by the vacuum generation device 300. The vacuum generating device 300 is communicated with the air source assembly 100, the vacuum generating device 300 is communicated with the water receiving tray 200, and the water outlet pipe 500 is communicated with the vacuum generating device 300, so that under the action of the air source assembly 100, the vacuum generating device 300 can suck accumulated liquid contained in the water receiving tray 200 and send the sucked accumulated liquid into the water outlet pipe 500. It should be noted that the vacuum generating device 300 is located below the air source assembly 100, and the vacuum generating device 300 is located above the water-receiving tray 200. The water outlet pipe 500 is located below the vacuum generating device 300, and the water outlet pipe 500 is located below a cutting chamber of the external slicing machine. In addition, to facilitate servicing of the cutting machine, the gas supply assembly 100 and other gas supply components are preferably centrally located. Outlet pipe 500 is located the cutting chamber below of external slicer to and outlet pipe 500 is located vacuum generator 300's below, is favorable to vacuum generator 300 to the hydrops suction back, makes the hydrops can flow in the cutting fluid dolly under the effect of gravity through outlet pipe 500, thereby is favorable to improving the rate of recovery of the sand slurry in the hydrops, avoids the hydrops to influence operational environment's cleanliness. The vacuum generating device 300 is located below the air source assembly 100, and the vacuum generating device 300 is located above the water-receiving tray 200. Preferred vacuum generator 300 is close to water collector 200, be favorable to making the suction range of the hydrops of vacuum generator 300 butt joint in the water collector 200 short, thereby be favorable to the better suction of the hydrops of vacuum generator 300 butt joint in the water collector 200, avoid the hydrops to pile up and reveal the steady operation that influences the I-shaped wheel, and influence operational environment's cleanliness, be favorable to improving the rate of recovery of the mortar liquid in the hydrops, can effectively prevent the hydrops seepage, the spare part in the protection line receiving and releasing room. Thereby in the slicer working process, provide the gas that needs in the suction device through air supply subassembly 100, gas among the suction device is the malleation gas, thereby vacuum generator 300 can produce the negative pressure under air supply subassembly 100's gaseous effect, make vacuum generator 300 suck the hydrops that hold in to water collector 200, and send the hydrops after the suction into outlet pipe 500, avoid the hydrops to pile up in water collector 200, be favorable to hydrops reuse, improve the recycle ratio of sand thick liquid.

The gas supply assembly 100, as shown in fig. 1-3, the gas supply assembly 100 provides the gas required in the pumping device. The air supply assembly 100 is commercially available. And the gas that air supply subassembly 100 provided is the positive pressure air supply to the existence of positive pressure air supply is favorable to vacuum generating device 300 to produce the negative pressure, thereby is favorable to vacuum generating device 300 to carry out the suction to the hydrops in the water tray 200.

A water pan 200, as shown in fig. 1-3, the water pan 200 is used for receiving the effusion dropped when the cutting fluid is driven by the diamond wire to enter the wire receiving and releasing chamber. In one embodiment, the drip tray 200 includes a first drip tray 210 and a second drip tray 220. The first water pan 210 is used for receiving the accumulated liquid dripped into the external wire collecting and releasing chamber. The second water pan 220 is used for receiving the accumulated liquid dropping below the external tension arm. Thereby through the setting of first water collector 210 and second water collector 220, vacuum generating device 300 can suck the hydrops that holds in first water collector 210, the second water collector 220 under the effect of air supply subassembly 100 to avoid the unable recovery of mortar liquid to cause the waste, be favorable to avoiding the hydrops to pile up the normal work who reveals the tension arm subassembly that influences in the slicer, receive and release line subassembly and I-shaped wheel simultaneously.

Vacuum generator 300, as shown in fig. 1-4, vacuum generator 300 can produce the negative pressure under the effect of air supply assembly 100 to be favorable to vacuum generator 300 to pump the hydrops in water tray 200, be favorable to avoiding the hydrops to pile up, influence operational environment's cleanliness, prevent that the sand thick liquid in the hydrops can't be retrieved and cause the waste, and can avoid the sand thick liquid seepage to receive and release the indoor, influence the normal work of I-shaped wheel. In one embodiment, the vacuum generator 300 includes a vacuum generator 310, the vacuum generator 310 is in communication with the gas source assembly 100, and the vacuum generator 310 is in communication with both the water pan 200 and the water outlet pipe 500, so that the vacuum generator 310 can suck the liquid loading dropped from the water pan 200. It should be noted that, in another embodiment, the vacuum generating device 300 includes a vacuum pump, and the vacuum pump can suck the accumulated liquid contained in the water tray 200. The direct hydrops that holds in to water tray 200 through the vacuum pump suction, then carry the hydrops through outlet pipe 500, accomplish the recovery that the hydrops is favorable to improving the rate of recovery of mortar liquid, be favorable to operational environment's cleanliness, avoid the hydrops to pile up simultaneously and reveal the tension arm subassembly that influences in the slicer, receive and release line subassembly and the normal use of I-shaped wheel. Therefore, the vacuum generating device 300 may be in the form of a vacuum generator 310 for pumping the accumulated liquid in the water tray 200, or in the form of a vacuum pump for pumping the accumulated liquid in the water tray 200. The vacuum generator 300 used in the embodiment of the present application is a vacuum generator 310.

A connector 400, as shown in fig. 1 to 4, the connector 400 is used to enable the water-receiving tray 200, the vacuum generating device 300 and the water outlet pipe 500 to communicate with each other. In one embodiment, the connector 400 includes a first connector 410, a second connector 420, a third connector 430, and a fourth connector 440. A first end of the first connector 410 is in communication with the gas source assembly 100, and a second end of the first connector 410 is in communication with the vacuum generating device 300. A first end of the second connector 420 is communicated with the vacuum generating device 300, and a second end of the second connector 420 is communicated with the water outlet pipe 500. The first end of the third connector 430 is in communication with the vacuum generating device 300. The fourth connection member 440 is in communication with the second end of the third connection member 430, and the fourth connection member 440 is in communication with the drip tray 200. Through the arrangement of the first connecting piece 410, the second connecting piece 420, the third connecting piece 430 and the fourth connecting piece 440, the gas in the gas source assembly 100 enters the vacuum generator 310 through the first connecting piece 410, and the gas provided in the gas source assembly 100 forms a negative pressure region in the vacuum generator 310 after passing through the vacuum generator 310, then under the action of the third connecting piece 430 and the fourth connecting piece 440, the vacuum generator 310 can suck the accumulated liquid in the water tray 200, and the sucked accumulated liquid and the gas in the gas source assembly 100 are discharged outwards from the second connecting piece 420 and the water outlet pipe 500 together, so that the accumulated liquid is prevented from being accumulated and leaked to affect the stable operation of the spool, and the cleanliness of the working environment is affected.

Further, as shown in fig. 3, the first connector 410 is provided with a first connector 411, and the first connector 411 is fixedly connected to an external connecting plate. It should be noted that the external connecting plate may be a metal plate, or a plate made of other materials. In one embodiment, the first joint 411 is a panel mount elbow joint. In addition, the second connector 420 and the outlet pipe 500 are connected by the first connector 411.

Further, as shown in fig. 3, the fourth connection member 440 includes a first pumping pipe 441, a second pumping pipe 442, and a three-way joint 443. The first end of the three-way joint 443 communicates with the third link 430. The first end of the first pumping pipe 441 is communicated with the second end of the three-way joint 443, the second end of the first pumping pipe 441 is connected with the water receiving tray 200, and the first pumping pipe 441 is used for pumping accumulated liquid dropping in the first water receiving tray 210. The first end of the second pumping pipe 442 is communicated with the third end of the three-way joint 443, the second end of the second pumping pipe 442 is connected with the water-receiving tray 200, and the second pumping pipe 442 is used for pumping the accumulated liquid dropping in the second water-receiving tray 220. It should be noted that, the arrangement of the three-way joint 443, the first water pumping pipe 441 and the second water pumping pipe 442 in the fourth connection member 440 is beneficial to enable the dripped accumulated water carried in the first water receiving tray 210 and the second water receiving tray 220 to enter the vacuum generator 310 through the three-way joint 443 and then enter the water outlet pipe 500 through the first water pumping pipe 441 and the second water pumping pipe 442, so that the accumulated water is prevented from accumulating and leaking to affect the normal operation of the spool and the cleanliness of the working environment.

It is worth explaining that, in order to facilitate the connection between the three-way joint 443 and the third connecting member 430, it is convenient and quick. As shown in fig. 1, 3 and 4, in one embodiment, a second joint 431 is connected to each of the vacuum generator 310 and the three-way joint 443, and the second joints 431 are respectively communicated with both ends of the third connecting member 430. In one embodiment, the second connector 431 is a 90 degree quick-connect elbow. The second joint 431 is threadedly coupled to the three-way joint 443, and the second joint 431 is threadedly coupled to the vacuum generator 310. It should be noted that the connection between the second joint 431 and the third connecting member 430, and the connection between the second joint 431 and the vacuum generator 310 may be in other forms. Therefore, the second joint 431 enables the third connection 430 to be in quick communication with the three-way joint 443 and the vacuum generator 310, which is beneficial to the accumulated liquid in the first and second water-receiving trays 210 and 220 to enter the vacuum generator 310 through the three-way joint 443 and the third connection 430. Then the effusion in first water collector 210, the second water collector 220 and the gas in the air source subassembly 100 are passed through vacuum generator 310 together and are followed in outlet pipe 500 and flow out to, avoid the sand thick liquid in the effusion to pile up unable recovery and cause the waste, and avoid the stable work of sand thick liquid infiltration influence I-shaped wheel to and influence operational environment's cleanliness.

Further, in the process of pumping the effusion in the water pan 200 by the fourth connection piece 440, the water pan 200 is connected with the third joint 221, and the third joint 221 is communicated with the fourth connection piece 440. In one embodiment, the third joint 221 is also a 90 degree quick-insertion elbow. In addition, a conduit 222 is connected to the bottom end of the drip tray 200, and the conduit 222 is communicated with the third joint 221. Thereby through the effect of third joint 221 and pipe 222, be favorable to the hydrops in the water collector 200 to be sucked by vacuum generator 310 fast for the gas in hydrops and the gas source module 100 outwards flows out through second connecting piece 420, outlet pipe 500 together, is favorable to the recycle of the sand thick liquid in the hydrops, can avoid the sand thick liquid to pile up the stable work that influences the I-shaped wheel and influence operational environment's cleanliness simultaneously.

Working principle/steps:

as shown in fig. 1-3, the gas is provided by the gas source assembly 100, the gas enters the vacuum generating device 300, and under the action of the connecting member 400 and the water outlet pipe 500, after the gas in the gas source assembly 100 passes through the vacuum generating device 300, a negative pressure is formed in the vacuum generating device 300, so that the vacuum generating device 300 can suck the effusion dripping in the water tray 200, and the effusion and the gas in the gas source assembly 100 flow out from the water outlet pipe 500;

it should be noted that, by arranging a plurality of joints, the air source assembly 100, the vacuum generating device 300, the connecting member 400 and the water outlet pipe 500 can be quickly communicated, so that time is saved and working efficiency is improved.

The technical effects are as follows:

1. in the embodiment of the application, the vacuum generating device 300 is communicated with the air source assembly 100, and the vacuum generating device 300 is communicated with the water receiving tray 200, so that under the action of the air source assembly 100, the vacuum generating device 300 can suck the accumulated liquid contained in the water receiving tray 200 and send the sucked accumulated liquid into the water outlet pipe 500, thereby preventing the accumulation and leakage of mortar liquid from affecting the stable operation of the spool, and solving the technical problem that the stable operation of the spool is affected by the easy accumulation and leakage of mortar liquid in the prior art; the technical effect that stable work of the spool is influenced by the fact that sand slurry is not prone to stacking and leaking is achieved.

2. In the embodiment of the application, vacuum generator 300 and air supply subassembly 100 communicate, and vacuum generator 300 and water collector 200 communicate, through vacuum generator 300 to the hydrops that holds in the water collector 200 suction, the hydrops after the suction is sent into in outlet pipe 500 to be favorable to the reuse of hydrops, improve the sand slurry rate of recovery, prevent that the hydrops from piling up, effectively prevent the seepage, the spare part in the protection line receiving and releasing room.

While the preferred embodiments of the present invention have been described, additional variations and modifications in those embodiments may occur to those skilled in the art once they learn of the basic inventive concepts. It is therefore intended that the appended claims be interpreted as including the preferred embodiment and all such alterations and modifications as fall within the scope of the invention.

It will be apparent to those skilled in the art that various changes and modifications may be made without departing from the spirit and scope of the invention. Thus, if such modifications and variations of the present invention fall within the scope of the claims and their equivalents, the present invention is also intended to include such modifications and variations.

Claims (10)

1. The utility model provides a mortar type slicer suction device acts on the water collector, its characterized in that, suction device includes:

the gas source assembly is used for providing gas required by the suction device;

the vacuum generating device is communicated with the air source assembly and the water receiving tray, and is used for providing negative pressure required by the suction device; and

the outlet pipe with vacuum generating device intercommunication to make under the air supply subassembly effect, vacuum generating device can suck the hydrops that holds in the butt joint water tray, and send the hydrops after the suction into in the outlet pipe.

2. The suction device of a mortar-type slicer as claimed in claim 1, wherein said water receiving tray includes:

the first water receiving tray is used for receiving accumulated liquid dropping in the external wire collecting and releasing chamber;

and the second water pan is used for receiving accumulated liquid dropping below the external tension arm.

3. The mortar-type slicer suction apparatus of claim 2, wherein said vacuum generating means includes:

the vacuum generator is communicated with the air source assembly, and the vacuum generator is communicated with the water receiving tray and the water outlet pipe, so that the vacuum generator can suck the dropsy in the water receiving tray.

4. The mortar-type slicer suction apparatus of claim 3, further comprising:

a connector, the connector comprising:

the first end of the first connecting piece is communicated with the air source assembly, and the second end of the first connecting piece is communicated with the vacuum generating device;

the first end of the second connecting piece is communicated with the vacuum generating device, and the second end of the second connecting piece is communicated with the water outlet pipe;

a third connecting member, a first end of which is communicated with the vacuum generating device; and

and the fourth connecting piece is communicated with the second end of the third connecting piece, and the fourth connecting piece is communicated with the water receiving tray.

5. The suction device of a mortar type slicer according to claim 4 wherein the first connector is provided with a first joint, and the first joint is fixedly connected with an external sheet metal.

6. The mortar-type slicer suction apparatus of claim 4 wherein the fourth link includes:

the first end of the three-way joint is communicated with the third connecting piece;

the first end of the first water pumping pipe is communicated with the second end of the three-way joint, the second end of the first water pumping pipe is connected with the water receiving tray, and the first water pumping pipe is used for pumping accumulated liquid dropping in the first water receiving tray; and

the second drinking-water pipe, the first end of second drinking-water pipe with three way connection's third end intercommunication, the second of second drinking-water pipe end with the water collector is connected, the second drinking-water pipe is used for the suction to drip the hydrops in the second water collector.

7. The apparatus of claim 6, wherein a second connector is connected to each of said vacuum generator and said tee connector, said second connectors being in communication with respective ends of said third connector.

8. The suction device of mortar type slicer as claimed in claim 4, wherein said water-receiving tray is connected with a third connector, said third connector is communicated with said fourth connector, and a bottom end of said water-receiving tray is connected with a conduit, said conduit is communicated with said third connector.

9. The mortar-type slicer suction apparatus of claim 1 wherein the vacuum generating means is located below the air supply assembly and the vacuum generating means is located above the drip tray.

10. The aspiration device of claim 1 or 9, wherein the water outlet tube is located below the vacuum generator and the water outlet tube is located below the cutting chamber of an external slicer.

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