CN209808593U - Cutting machine for manufacturing false teeth - Google Patents

Abstract

The utility model relates to a cutting machine for false tooth manufacture, which comprises a machine body with an opening at one side, wherein a closed door is rotatably connected with one side of the opening of the machine body; a clamp and a cutting tool are arranged in the machine body; the cutting tool comprises a mounting seat and a tool bit, and the mounting seat is also connected with a cooling water pipe; the end part of the cooling water pipe is connected with a cooling water tank through a pipeline, and the cooling water tank is positioned outside the machine body; the pipeline is also connected with a delivery pump; the bottom of the machine body is communicated with a transmission pipe, and a water pump is connected to the transmission pipe; one end of the transmission pipe, which is far away from the machine body, is sequentially connected with a filtering device and a heat exchange device, a connecting pipe is communicated between the filtering device and the heat exchange device, and a recovery pipe is communicated between the heat exchange device and the cooling water tank. The utility model filters and cools the waste water, and then conveys the waste water into the cooling water tank for recycling, thereby improving the utilization rate of water resources; and the water accumulation in the machine body is greatly reduced, and the influence on the processing process is reduced.

Description

Cutting machine for manufacturing false teeth

Technical Field

The utility model belongs to the technical field of the technique of artificial tooth cutting and specifically relates to a cutting machine for artificial tooth preparation is related to.

Background

A denture is an artificial tooth, also called a denture, that replaces a missing natural tooth. As modern medicine develops, dentures are slowly accepted by more consumers, and more consumers obtain dental restorations for implanting dentures. The artificial tooth is divided into metal and porcelain according to different materials, and the metal artificial tooth is manufactured in a cutting machine.

As shown in fig. 5-6, the cutting machine comprises a machine body 1 with an opening at one side, and a closing door 11 is rotatably connected to the open side of the machine body 1. The closed door 11 is provided with an observation glass window 111 for observing the condition inside the machine body 1. A clamp 12 for clamping a metal raw material is arranged in the machine body 1, and a cutting tool 2 is arranged above the clamp 12. The cutting tool 2 comprises a mounting base 21 and a cutting head 22, the cutting head 22 being arranged in alignment with the metal stock material.

Since the cutting tool 2 generates a large amount of heat energy in the process of cutting metal, the metal needs to be cooled. Usually, a cooling water pipe 211 is disposed in the body of the machine body 1, the cooling water pipe 211 is mounted on the mounting seat 21, and the nozzle of the cooling water pipe 211 is aligned with the cutter head 22. The end of the cooling water pipe 211 is connected with a pipe 3, and the pipe 3 passes through the machine body 1 and is connected with a cooling water tank 32. The pipeline 3 is a hose, so that the mounting seat 21 can move conveniently and move in the lower machine body 1; the pipe 3 is also connected with a delivery pump 31 for delivering cooling water.

The defects of the prior art are as follows: after the cooling water output from the cooling water pipe sprays the metal raw material, the waste water with metal powder can be accumulated at the bottom of the machine body, and the metal raw material is cleaned after being processed, so that the processing efficiency is reduced, and the water resource is wasted.

Disclosure of Invention

The utility model aims at providing a cutting machine for artificial tooth preparation can carry out reuse to the waste water that has metal powder, improves the utilization ratio of water resource to do not need the manual work to wash the inside waste water of organism, improved metal feedstock's machining efficiency.

The above object of the present invention is achieved by the following technical solutions:

a cutting machine for manufacturing false teeth comprises a machine body with an opening at one side, wherein a closed door is rotatably connected to one side of the opening of the machine body; a clamp and a cutting tool are arranged in the machine body; the cutting tool comprises a mounting seat and a tool bit, and the mounting seat is also connected with a cooling water pipe; the end part of the cooling water pipe is connected with a cooling water tank through a pipeline, and the cooling water tank is positioned outside the machine body; the pipeline is also connected with a delivery pump; the bottom of the machine body is communicated with a transmission pipe, and a water suction pump is connected to the transmission pipe; one end, far away from the machine body, of the transmission pipe is sequentially connected with a filtering device and a heat exchange device, a connecting pipe is communicated between the filtering device and the heat exchange device, and a recovery pipe is communicated between the heat exchange device and the cooling water tank.

By adopting the technical scheme, the waste water with the metal powder enters the filtering device through the transmission pipe under the action of the water pump. After passing through the filtering device, the wastewater still has a certain temperature and is cooled by the heat exchange device and then is recycled into the cooling water tank, so that the utilization efficiency of the cooling water is improved.

The utility model discloses further set up to: the filtering device comprises a box body; an active carbon filtering component is arranged in the box body, faces to the pipe orifice of the transmission pipe and is matched with the cross section of the box body; the active carbon limiting component comprises two clamping plates and an active carbon fiber layer arranged between the two clamping plates, and a plurality of water permeable holes are formed in the clamping plates.

By adopting the technical scheme, the activated carbon fiber has extremely large specific surface area and abundant micropores, and the volume of the micropores accounts for more than 90% of the total pore volume. The activated carbon fiber has larger adsorption capacity and faster adsorption dynamic performance than granular activated carbon, has high adsorption efficiency on particulate matters in a liquid phase, can be regenerated and recycled, has the advantages of acid and alkali resistance, high temperature resistance, strong adaptability and the like, and is an ideal environment-friendly material. Set up activated carbon fiber layer between two splint, can fix a position activated carbon fiber layer to reduced the direct impact effect of water pressure to activated carbon fiber layer, protected activated carbon fiber layer. In actual installation, can fix two splint through the screw rod, and the screw rod passes the setting of activated carbon fiber layer, then with inside the whole box that inserts of activated carbon filter component.

The utility model discloses further set up to: a gravel filtering component is also arranged in the box body and is positioned on the transmission pipe and the active carbon filtering component; the rubble filter component includes a plurality of stones and wraps up in the outside wire net of all stones.

Through adopting above-mentioned technical scheme, the stone has the effect of the particulate matter in the filtration liquid phase, and the waste water that has metal powder can detach more metal powder in the waste water after the prefilter of stone, and can detach the great metal powder of granule to reduce the burden to active carbon filter element, and then improved the filter effect.

The utility model discloses further set up to: the box body is connected with the transmission pipe and the connecting pipe through flanges.

Through adopting above-mentioned technical scheme, the installation and the dismantlement of the box of being convenient for. After the activated carbon filter assembly and the broken stone filter assembly in the box body are used for one section, the whole box body can be replaced, and therefore the filtering effect is guaranteed.

The utility model discloses further set up to: the heat exchange device comprises a heat exchange tube, and two ends of the heat exchange tube are respectively communicated between the connecting tube and the recovery tube; a heat insulation box is sleeved outside the heat exchange tube, and a water inlet tube and a water outlet tube are connected to the heat insulation box; the water inlet pipe is connected with a cold water tank, and a water pump is connected to the water inlet pipe; and the water outlet pipe is connected with a recovery box.

Through adopting above-mentioned technical scheme, the cold water tank can be connected to municipal water supply system to guarantee the sufficiency of water source. The collection in the collection box is warm water with a certain temperature, and the warm water can be used for preheating or cleaning products in other places needing water in the false tooth manufacturing process, and due to the fact that the products have a certain temperature, the temperature difference generated on the products can be reduced by using warm water cleaning, and the warm water can also be used as domestic water to be utilized, and the utilization rate of hot resources is improved.

The utility model discloses further set up to: the conveying pipe is connected to the middle position of the bottom of the machine body, a guide slope is formed between the pipe orifice of the conveying pipe and the edge of the bottom of the machine body, and the guide slope is arranged in an inclined mode upwards from the conveying pipe to the direction far away from the conveying pipe.

Through adopting above-mentioned technical scheme, be convenient for waste water enter into the transmission pipe more smoothly and fast under the guide effect on direction slope to improve the transport efficiency of waste water.

The utility model discloses further set up to: a partition board is additionally arranged above the transmission pipe, the periphery of the partition board is fixed on four side walls of the machine body, and a water storage space is formed between the partition board and the bottom of the machine body; and the clapboard is provided with a water outlet.

By adopting the technical scheme, when the water consumption in the machine body is large, the waste water can not flow into the transmission pipe quickly and completely. The setting in water storage space can give the space of a buffering to waste water, avoids the inside ponding of organism to the recovery efficiency of waste water has been improved, and the influence when having reduced the cutting to metal raw materials.

The utility model discloses further set up to: a water guide slope is formed between the lower water port and the edge of the partition plate, and the water guide slope is obliquely and upwards arranged from the lower water port to the direction far away from the lower water port.

Through adopting above-mentioned technical scheme, be convenient for have the waste water of metal powder flow under the dead weight effect in the mouth of a river to store in the water storage cavity.

To sum up, the utility model discloses a beneficial technological effect does:

1. the filtering device and the heat exchange device are arranged to filter and cool the wastewater, and then the wastewater is conveyed into the cooling water tank for recycling, so that the utilization rate of water resources is improved; the water accumulation in the machine body is greatly reduced, and the influence on the processing process is reduced;

2. the filter equipment includes rubble filtering component and active carbon filtering component for waste water has improved the filter effect through getting over of rubble filtering component and active carbon filtering component in proper order.

Drawings

Fig. 1 is a schematic view of the overall structure of the present invention.

Fig. 2 is a schematic view of the internal structure of the body of fig. 1.

Fig. 3 is a schematic view of the internal structure of the case of fig. 1.

Fig. 4 is a schematic view showing the internal structure of the insulation box of fig. 1.

Fig. 5 is a schematic view of the overall structure of the prior art.

Fig. 6 is a schematic view of the internal structure of a prior art housing.

In the figure, 1, a machine body; 11. a closing door; 111. an observation glass window; 12. a clamp; 13. a guide ramp; 2. cutting a cutter; 21. a mounting seat; 211. a cooling water pipe; 22. a cutter head; 3. a pipeline; 31. a delivery pump; 32. a cooling water tank; 321. a recovery pipe; 4. a partition plate; 41. a water outlet; 42. water guiding slope; 5. a conveying pipe; 51. a water pump; 6. a filtration device; 61. a box body; 611. an access door; 62. a crushed stone filtering assembly; 621. a stone block; 622. steel wire mesh; 63. an activated carbon filter assembly; 631. a splint; 6311. water permeable holes; 6312. a screw; 632. an activated carbon fiber layer; 7. a connecting pipe; 8. a heat exchange device; 81. a heat exchange tube; 82. a heat insulation box; 821. a water inlet pipe; 822. a water outlet pipe; 9. a cold water tank; 10. a recycling bin; 101. an electromagnetic valve.

Detailed Description

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

Referring to fig. 1-2, for the utility model discloses a cutting machine for artificial tooth preparation, including organism 1 that one side opening set up, the opening one side of organism 1 is rotated and is connected with closed door 11. The closed door 11 is provided with an observation glass window 111 for observing the condition inside the machine body 1. A clamp 12 and a cutting tool 2 are arranged in the machine body 1, and the cutting tool 2 is positioned right above the clamp 12. In use, a metal material is clamped by the clamp 12 and then cut by the cutting tool 2.

The cutting tool 2 comprises a mounting seat 21 and a tool bit 22, and a cooling water pipe 211 is further connected to the mounting seat 21. Two cooling water pipes 211 are symmetrically arranged on the mounting base 21, and the pipe openings of the two cooling water pipes 211 are arranged towards the tool bit 22. One end of the cooling water pipe 211, which is far away from the cutter head 22, is communicated with each other through a pipeline 3, the end part of the pipeline 3 penetrates through the side wall of the machine body 1 and is connected with a cooling water tank 32, and the pipeline 3 is also connected with a delivery pump 31.

The top of 1 diapire of organism has increased baffle 4, and baffle 4 is fixed in on four lateral walls of organism 1 all around, and is formed with the water storage space between baffle 4 and the organism 1 bottom. The middle part of the partition plate 4 corresponding to the position of the clamp 12 is provided with a water outlet 41, so that the wastewater on the partition plate 4 can flow into the water storage space through the water outlet 41. In order to increase the flow rate of the waste water, a water guide slope 42 is formed between the drain port 41 and the edge of the partition plate 4, and the water guide slope 42 is obliquely upward from the drain port 41 in a direction away from the drain port 41.

The bottom of the machine body 1 is communicated with a transmission pipe 5, and the transmission pipe 5 is connected to the position, corresponding to the lower water opening 41, on the machine body 1. A guide slope 13 is formed between the nozzle of the conveying pipe 5 and the edge of the bottom of the machine body 1, and the guide slope 13 is obliquely and upwards arranged from the conveying pipe 5 to the direction far away from the conveying pipe 5.

The end of the transmission pipe 5 far away from the machine body 1 is sequentially connected with a filtering device 6 and a heat exchange device 8, and the heat exchange device 8 is connected to the cooling water tank 32. The transmission pipe 5 is also connected with a water pump 51 at the positions of the machine body 1 and the filtering device 6, so that water output from the water storage space is sequentially filtered and heat exchanged and finally recovered in the cooling water tank 32 for recycling.

The filter device 6 comprises a box 61, and the transfer pipe 5 is connected to the side wall of the box 61. The box 61 is provided with flanges at both ends for facilitating connection of the transfer pipe 5 and other pipes 3. An access door 611 is rotatably connected to a side wall of the case 61 adjacent to the transfer pipe 5, and the height of the access door 611 is the same as that of the case 61.

Referring to fig. 3, a macadam filter assembly 62 and an activated carbon filter assembly 63 which are vertically arranged are installed in the box body 61, the macadam filter assembly 62 and the activated carbon filter assembly 63 are arranged corresponding to the access door 611, and the macadam filter assembly 62 and the activated carbon filter assembly 63 cover the vertical sectional area inside the box body 61.

Rubble filter assembly 62 is located between transmission pipe 5 and the active carbon filter assembly 63, and rubble filter assembly 62 includes a plurality of stones 621 and wraps up in the outside wire net 622 of all stones 621, and wire net 622 is the cuboid shape of stereotyping. Notches are formed in the other three side walls of the box body 61 except the side wall where the access door 611 is installed, and the notches are communicated with each other so that the steel wire mesh 622 can be inserted into the notches from the position of the access door 611. Such an arrangement can facilitate servicing and replacement of the debris filter assembly 62.

The activated carbon filter module 63 includes two clamp plates 631 and an activated carbon fiber layer 632 sandwiched between the two clamp plates 631, and the two clamp plates 631 have a plurality of water permeable holes 6311. The two clamp plates 631 are fixed to each other by screws 6312, and the screws 6312 are disposed through the activated carbon fiber layer 632. The activated carbon filter module 63 is fixed in the case 61 in the same manner as the crushed stone filter module 62, and other three side walls except the side wall where the access door 611 is installed in the case 61 are provided with notches, and two clamp plates 631 are inserted into the notches, and then the access door 611 is closed so that the clamp plates 631 abut against the access door 611 toward the side of the access door 611. In order to improve the sealing property between the access door 611 and the box 61, a gasket (not shown) may be interposed between the access door 611 and the box 61.

Referring to fig. 4, the heat exchanger 8 and the case 61 are communicated with each other through a connection pipe 7, and the connection pipe 7 is connected to a flange of the case 61. The heat exchanging device 8 includes a heat exchanging pipe 81 and a heat insulating box 82 sleeved outside the heat exchanging pipe 81, and both ends of the heat exchanging pipe 81 are respectively communicated with the connecting pipe 7 and the recovery pipe 321. An inlet pipe 821 and an outlet pipe 822 are connected to the heat insulating box 82. The inlet pipe 821 is connected with the cold water tank 9, the inlet pipe 821 is connected with a water pump used for conveying cold water in the cold water tank 9 to the heat insulation tank 82, and the outlet pipe 822 is connected with the recovery tank 10, so that water with temperature can be conveniently recovered and utilized.

Referring to fig. 1, a recovery pipe 321 is communicated between the cooling water tank 32 and the heat exchanger 8, an electromagnetic valve 101 is provided in the recovery pipe 321, and the electromagnetic valve 101 is controlled by temperature. When the temperature of the cooling water in the recovery pipe 321 is lower than a set value, the electromagnetic valve 101 is in an open state, and when the temperature of the cooling water in the recovery pipe 321 is higher than the set value, the cooling water cannot well cool the metal raw material, so that the electromagnetic valve 101 is closed at this time.

The implementation principle of the embodiment is as follows: the waste water with metal powder and higher temperature enters the water storage space through the drain port 41 and is then transported into the tank 61 through the transport pipe 5. The waste water is filtered by the stone 621 and the activated carbon fiber layer 632 in sequence, and is output from the connecting pipe 7 to the heat exchange pipe 81 for cooling. The cooled wastewater is input into the cooling water tank 32 through the recovery pipe 321 for recycling.

The embodiment of this specific implementation mode is the preferred embodiment of the present invention, not limit according to this the utility model discloses a protection scope, so: all equivalent changes made according to the structure, shape and principle of the utility model are covered within the protection scope of the utility model.

Claims (8)

1. A cutting machine for manufacturing false teeth comprises a machine body (1) with an opening at one side, wherein a closed door (11) is rotatably connected to one side of the opening of the machine body (1); a clamp (12) and a cutting tool (2) are arranged in the machine body (1); the cutting tool (2) comprises a mounting seat (21) and a tool bit (22), and the mounting seat (21) is also connected with a cooling water pipe (211); the end part of the cooling water pipe (211) is connected with a cooling water tank (32) through a pipeline (3), and the cooling water tank (32) is positioned outside the machine body (1); the pipeline (3) is also connected with a delivery pump (31); the method is characterized in that: the bottom of the machine body (1) is communicated with a transmission pipe (5), and the transmission pipe (5) is connected with a water suction pump (51); one end, far away from the machine body (1), of the transmission pipe (5) is sequentially connected with a filtering device (6) and a heat exchange device (8), a connecting pipe (7) is communicated between the filtering device (6) and the heat exchange device (8), and a recovery pipe (321) is communicated between the heat exchange device (8) and the cooling water tank (32).

2. A cutting machine for denture fabrication according to claim 1, wherein: the filtering device (6) comprises a box body (61); an active carbon filtering component (63) is installed in the box body (61), the active carbon filtering component (63) is arranged towards the pipe orifice of the transmission pipe (5), and the active carbon filtering component (63) is matched with the section of the box body (61); the activated carbon filtering component (63) comprises two clamping plates (631) and an activated carbon fiber layer (632) clamped between the two clamping plates (631), and a plurality of water permeable holes (6311) are formed in the clamping plates (631).

3. A cutting machine for denture fabrication according to claim 2, wherein: a gravel filtering component (62) is further arranged in the box body (61), and the gravel filtering component (62) is positioned on the transmission pipe (5) and the activated carbon filtering component (63); the gravel filtering assembly (62) comprises a plurality of stones (621) and a steel wire mesh (622) wrapping the outside of all the stones (621).

4. A cutting machine for denture fabrication according to claim 2 or 3, wherein: the box body (61) and the transmission pipe (5) and the box body (61) and the connecting pipe (7) are connected by flanges.

5. A cutting machine for denture fabrication according to claim 1, wherein: the heat exchange device (8) comprises a heat exchange tube (81), and two ends of the heat exchange tube (81) are respectively communicated between the connecting tube (7) and the recovery tube; a heat insulation box (82) is sleeved outside the heat exchange tube (81), and a water inlet tube (821) and a water outlet tube (822) are connected to the heat insulation box (82); the water inlet pipe (821) is connected with a cold water tank (9), and the water inlet pipe (821) is connected with a water pump; the water outlet pipe (822) is connected with a recovery box (10).

6. A cutting machine for denture fabrication according to claim 1, wherein: the conveying pipe (5) is connected to the middle position of the bottom of the machine body (1), a guide slope (13) is formed between the pipe orifice of the conveying pipe (5) and the edge of the bottom of the machine body (1), and the guide slope (13) is arranged in an inclined mode upwards from the conveying pipe (5) to the direction far away from the conveying pipe (5).

7. A cutting machine for denture fabrication according to claim 6, wherein: a partition plate (4) is additionally arranged above the transmission pipe (5), the periphery of the partition plate (4) is fixed on four side walls of the machine body (1), and a water storage space is formed between the partition plate (4) and the bottom of the machine body (1); and a lower water gap (41) is formed in the partition plate (4).

8. A cutting machine for denture fabrication according to claim 7, wherein: a water guide slope (42) is formed between the lower water gap (41) and the edge of the partition plate (4), and the water guide slope (42) is obliquely and upwards arranged from the lower water gap (41) to the direction far away from the lower water gap (41).